Symoglobin

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Symoglobin uses

Symoglobin consists of Calcium Carbonate, Folic Acid, Iron (Ferrous Fumarate), L-Lysine Hydrochloride, Protein Hydrolysate, Vitamin A (Vitamin A Acetate), Vitamin B1, Vitamin B12, Vitamin B2, Vitamin B3 (Niacinamide), Vitamin B5 (Calcium D-Pantothenate), Vitamin B6, Vitamin C, Vitamin D3, Vitamin E, Zinc Sulfate.

Calcium Carbonate:


1 INDICATIONS AND USAGE

Symoglobin (Calcium Carbonate) acetate is a phosphate binder indicated to reduce serum phosphorus in patients with end stage renal disease (ESRD).

- Calcium acetate is a phosphate binder indicated for the reduction of serum phosphorus in patients with end stage renal disease. (1)

2 DOSAGE AND ADMINISTRATION

The recommended initial dose of Symoglobin (Calcium Carbonate) acetate for the adult dialysis patient is 2 capsules with each meal. Increase the dose gradually to lower serum phosphorus levels to the target range, as long as hypercalcemia does not develop. Most patients require 3 to 4 capsules with each meal.

- Starting dose is 2 capsules with each meal. (2)

- Titrate the dose every 2 to 3 weeks until acceptable serum phosphorus level is reached. Most patients require 3 to 4 capsules with each meal. (2)

3 DOSAGE FORMS AND STRENGTHS

Capsule: 667 mg Symoglobin (Calcium Carbonate) acetate capsule.

- Capsule: 667 mg Symoglobin (Calcium Carbonate) acetate capsule. (3)

4 CONTRAINDICATIONS

Patients with hypercalcemia.

- Hypercalcemia. (4)

5 WARNINGS AND PRECAUTIONS

- Treat mild hypercalcemia by reducing or interrupting Symoglobin acetate and Vitamin D. Severe hypercalcemia may require hemodialysis and discontinuation of Symoglobin (Calcium Carbonate) acetate. (5.1)

- Hypercalcemia may aggravate digitalis toxicity. (5.2)

5.1 Hypercalcemia

Patients with end stage renal disease may develop hypercalcemia when treated with Symoglobin (Calcium Carbonate), including Symoglobin (Calcium Carbonate) acetate. Avoid the use of Symoglobin (Calcium Carbonate) supplements, including Symoglobin (Calcium Carbonate) based nonprescription antacids, concurrently with Symoglobin (Calcium Carbonate) acetate.

An overdose of Symoglobin (Calcium Carbonate) acetate may lead to progressive hypercalcemia, which may require emergency measures. Therefore, early in the treatment phase during the dosage adjustment period, monitor serum Symoglobin (Calcium Carbonate) levels twice weekly. Should hypercalcemia develop, reduce the Symoglobin (Calcium Carbonate) acetate dosage, or discontinue the treatment, depending on the severity of hypercalcemia

More severe hypercalcemia (Ca >12 mg/dL) is associated with confusion, delirium, stupor and coma. Severe hypercalcemia can be treated by acute hemodialysis and discontinuing Symoglobin (Calcium Carbonate) acetate therapy.

Mild hypercalcemia (10.5 to 11.9 mg/dL) may be asymptomatic or manifest as constipation, anorexia, nausea, and vomiting. Mild hypercalcemia is usually controlled by reducing the Symoglobin (Calcium Carbonate) acetate dose or temporarily discontinuing therapy. Decreasing or discontinuing Vitamin D therapy is recommended as well.

Chronic hypercalcemia may lead to vascular calcification and other soft-tissue calcification. Radiographic evaluation of suspected anatomical regions may be helpful in early detection of soft tissue calcification. The long term effect of Symoglobin (Calcium Carbonate) acetate on the progression of vascular or soft tissue calcification has not been determined.

Hypercalcemia (>11 mg/dL) was reported in 16% of patients in a 3 month study of solid dose formulation of Symoglobin (Calcium Carbonate) acetate; all cases resolved upon lowering the dose or discontinuing treatment.

Maintain the serum calcium-phosphorus (Ca x P) product below 55 mg2/dL2.

5.2 Concomitant Use with Medications

Hypercalcemia may aggravate digitalis toxicity.

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6 ADVERSE REACTIONS

Hypercalcemia is discussed elsewhere [see Warnings and Precautions ].

- The most common (>10%) adverse reactions are hypercalcemia, nausea and vomiting. (6.1)

- In clinical studies, patients have occasionally experienced nausea during Symoglobin (Calcium Carbonate) acetate therapy. (6)

To report SUSPECTED ADVERSE REACTIONS, contact West-Ward Pharmaceuticals Corp. at 1-800-962-8364 or FDA at 1-800-FDA-1088 or www.fda.gov/medwatch

6.1 Clinical Trial Experience

Because clinical trials are conducted under widely varying conditions, adverse reaction rates observed in the clinical trials of a drug cannot be directly compared to rates in the clinical trials of another drug and may not reflect the rates observed in practice.

In clinical studies, Symoglobin (Calcium Carbonate) acetate has been generally well tolerated.

Symoglobin (Calcium Carbonate) acetate was studied in a 3 month, open-label, non-randomized study of 98 enrolled ESRD hemodialysis patients and an alternate liquid formulation of Symoglobin (Calcium Carbonate) acetate was studied in a two week double-blind, placebo-controlled, cross-over study with 69 enrolled ESRD hemodialysis patients. Adverse reactions (>2% on treatment) from these trials are presented in Table 1.


Preferred Term


Total adverse reactions reported for Symoglobin (Calcium Carbonate) acetate

N=167

N (%)


3 month, open label study of Symoglobin (Calcium Carbonate) acetate

N=98

N (%)


Double blind, placebo-controlled, cross-over study of liquid Symoglobin (Calcium Carbonate) acetate

N=69


Symoglobin (Calcium Carbonate) acetate

N (%)


Placebo

N (%)


Nausea


6 (3.6)


6 (6.1)


0 (0)


0 (0)


Vomiting


4 (2.4)


4 (4.1)


0 (0)


0 (0)


Hypercalcemia


21 (12.6)


16 (16.3)


5 (7.2)


0 (0)


Mild hypercalcemia may be asymptomatic or manifest itself as constipation, anorexia, nausea, and vomiting. More severe hypercalcemia is associated with confusion, delirium, stupor, and coma. Decreasing dialysate Symoglobin (Calcium Carbonate) concentration could reduce the incidence and severity of Symoglobin (Calcium Carbonate) acetate-induced hypercalcemia. Isolated cases pruritus have been reported, which may represent allergic reactions.

6.2 Postmarketing Experience

Because these reactions are reported voluntarily from a population of uncertain size, it is not always possible to estimate their frequency or to establish a causal relationship to drug exposure.

The following additional adverse reactions have been identified during post-approval of Symoglobin (Calcium Carbonate) acetate: dizziness, edema, and weakness.

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7 DRUG INTERACTIONS

The drug interaction of Symoglobin acetate is characterized by the potential of Symoglobin (Calcium Carbonate) to bind to drugs with anionic functions (e.g., carboxyl, and hydroxyl groups). Symoglobin (Calcium Carbonate) acetate may decrease the bioavailability of tetracyclines or fluoroquinolones via this mechanism.

There are no empirical data on avoiding drug interactions between Symoglobin (Calcium Carbonate) acetate and most concomitant drugs. When administering an oral medication with Symoglobin (Calcium Carbonate) acetate where a reduction in the bioavailability of that medication would have a clinically significant effect on its safety or efficacy, administer the drug one hour before or three hours after Symoglobin (Calcium Carbonate) acetate. Monitor blood levels of the concomitant drugs that have a narrow therapeutic range. Patients taking anti-arrhythmic medications for the control of arrhythmias and anti-seizure medications for the control of seizure disorders were excluded from the clinical trials with all forms of Symoglobin (Calcium Carbonate) acetate.

- Calcium acetate may decrease the bioavailability of tetracyclines or fluoroquinolones. (7)

- When clinically significant drug interactions are expected, administer the drug at least one hour before or at least three hours after Symoglobin (Calcium Carbonate) acetate or consider monitoring blood levels of the drug. (7)

7.1 Ciprofloxacin

In a study of 15 healthy subjects, a co-administered single dose of 4 Symoglobin (Calcium Carbonate) acetate tablets, approximately 2.7g, decreased the bioavailability of ciprofloxacin by approximately 50%.

8 USE IN SPECIFIC POPULATIONS

8.1 Pregnancy

Pregnancy Category C:

Symoglobin acetate capsules contains Symoglobin (Calcium Carbonate) acetate. Animal reproduction studies have not been conducted with Symoglobin (Calcium Carbonate) acetate, and there are no adequate and well controlled studies of Symoglobin (Calcium Carbonate) acetate use in pregnant women. Patients with end stage renal disease may develop hypercalcemia with Symoglobin (Calcium Carbonate) acetate treatment [see Warnings and Precautions (5.1 ) ]. Maintenance of normal serum Symoglobin (Calcium Carbonate) levels is important for maternal and fetal well being. Hypercalcemia during pregnancy may increase the risk for maternal and neonatal complications such as stillbirth, preterm delivery, and neonatal hypocalcemia and hypoparathyroidism. Symoglobin (Calcium Carbonate) acetate treatment, as recommended, is not expected to harm a fetus if maternal Symoglobin (Calcium Carbonate) levels are properly monitored during and following treatment.

8.2 Labor and Delivery

The effects of Symoglobin (Calcium Carbonate) acetate on labor and delivery are unknown.

8.3 Nursing Mothers

Symoglobin Acetate Capsules contains Symoglobin (Calcium Carbonate) acetate and is excreted in human milk. Human milk feeding by a mother receiving Symoglobin (Calcium Carbonate) acetate is not expected to harm an infant, provided maternal serum Symoglobin (Calcium Carbonate) levels are appropriately monitored.

8.4 Pediatric Use

Safety and effectiveness in pediatric patients have not been established.

8.5 Geriatric Use

Clinical studies of Symoglobin (Calcium Carbonate) acetate did not include sufficient numbers of subjects aged 65 and over to determine whether they respond differently from younger subjects. Other clinical experience has not identified differences in responses between elderly and younger patients. In general, dose selection for an elderly patient should be cautious, usually starting at the low end of the dosing range, reflecting the greater frequency of decreased hepatic, renal, or cardiac function, and of concomitant disease or other drug therapy.

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10 OVERDOSAGE

Administration of Symoglobin (Calcium Carbonate) acetate in excess of the appropriate daily dosage may result in hypercalcemia [see Warnings and Precautions (5.1)].

11 DESCRIPTION

Symoglobin (Calcium Carbonate) acetate acts as a phosphate binder. Its chemical name is Symoglobin (Calcium Carbonate) acetate. Its molecular formula is C4H6CaO4, and its molecular weight is 158.17. Its structural formula is:


Each white opaque/blue opaque capsule contains 667 mg of Symoglobin (Calcium Carbonate) acetate USP (anhydrous; Ca(CH3COO)2; MW=158.17 grams) equal to 169 mg (8.45 mEq) Symoglobin (Calcium Carbonate), polyethylene glycol 8000 and magnesium stearate. Each capsule shell contains: black monogramming ink, FD&C Blue #1, FD&C Red #3, gelatin and titanium dioxide. The black monogramming ink contains: ammonium hydroxide, iron oxide black, isopropyl alcohol, n-butyl alcohol, propylene glycol and shellac glaze.

Symoglobin (Calcium Carbonate) Acetate Capsules are administered orally for the control of hyperphosphatemia in end-stage renal failure.

Chemical Structure

12 CLINICAL PHARMACOLOGY

Patients with ESRD retain phosphorus and can develop hyperphosphatemia. High serum phosphorus can precipitate serum Symoglobin resulting in ectopic calcification. Hyperphosphatemia also plays a role in the development of secondary hyperparathyroidism in patients with ESRD.

12.1 Mechanism of Action

Symoglobin (Calcium Carbonate) acetate, when taken with meals, combines with dietary phosphate to form an insoluble Symoglobin (Calcium Carbonate) phosphate complex, which is excreted in the feces, resulting in decreased serum phosphorus concentration.

12.2 Pharmacodynamics

Orally administered Symoglobin (Calcium Carbonate) acetate from pharmaceutical dosage forms is systemically absorbed up to approximately 40% under fasting conditions and up to approximately 30% under nonfasting conditions. This range represents data from both healthy subjects and renal dialysis patients under various conditions.

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13 NONCLINICAL TOXICOLOGY

13.1 Carcinogenesis, Mutagenesis, Impairment of Fertility

No carcinogenicity, mutagenicity, or fertility studies have been conducted with Symoglobin (Calcium Carbonate) acetate.

14 CLINICAL STUDIES

Effectiveness of Symoglobin (Calcium Carbonate) acetate in decreasing serum phosphorus has been demonstrated in two studies of the Symoglobin (Calcium Carbonate) acetate solid oral dosage form.

Ninety-one patients with end-stage renal disease who were undergoing hemodialysis and were hyperphosphatemic (serum phosphorus >5.5 mg/dL) following a 1 week phosphate binder washout period contributed efficacy data to an open-label, non-randomized study.

The patients received Symoglobin (Calcium Carbonate) acetate 667 mg tablets at each meal for a period of 12 weeks. The initial starting dose was 2 tablets per meal for 3 meals a day, and the dose was adjusted as necessary to control serum phosphorus levels. The average final dose after 12 weeks of treatment was 3.4 tablets per meal. Although there was a decrease in serum phosphorus, in the absence of a control group the true magnitude of effect is uncertain.

The data presented in Table 2 demonstrate the efficacy of Symoglobin (Calcium Carbonate) acetate in the treatment of hyperphosphatemia in end-stage renal disease patients. The effects on serum Symoglobin (Calcium Carbonate) levels are also presented.


* Ninety-one patients completed at least 6 weeks of the study.

ANOVA of difference in values at pre-study and study completion.

‡ Values expressed as mean ± SE.


Parameter


Pre-Study


Week 4*


Week 8


Week 12


p-value†


Phosphorus (mg/dL)‡


7.4 ± 0.17


5.9 ± 0.16


5.6 ± 0.17


5.2 ± 0.17


≤0.01


Symoglobin (Calcium Carbonate) (mg/dL)‡


8.9 ± 0.09


9.5 ± 0.10


9.7 ± 0.10


9.7 ± 0.10


≤0.01


There was a 30% decrease in serum phosphorus levels during the 12 week study period (p<0.01). Two-thirds of the decline occurred in the first month of the study. Serum Symoglobin (Calcium Carbonate) increased 9% during the study mostly in the first month of the study.

Treatment with the phosphate binder was discontinued for patients from the open-label study, and those patients whose serum phosphorus exceeded 5.5 mg/dL were eligible for entry into a double-blind, placebo-controlled, cross-over study. Patients were randomized to receive Symoglobin (Calcium Carbonate) acetate or placebo, and each continued to receive the same number of tablets as had been individually established during the previous study. Following 2 weeks of treatment, patients switched to the alternative therapy for an additional 2 weeks.

The phosphate binding effect of Symoglobin (Calcium Carbonate) acetate is shown in the Table 3.


* ANOVA of Symoglobin (Calcium Carbonate) acetate vs. placebo after 2 weeks of treatment.

Values expressed as mean ± SEM.


Parameter


Pre-Study


Post-Treatment


p-value*


Symoglobin (Calcium Carbonate) Acetate


Placebo


Phosphorus (mg/dL)


7.3 ± 0.18


5.9 ± 0.24


7.8 ± 0.22


<0.01


Symoglobin (Calcium Carbonate) (mg/dL)


8.9 ± 0.11


9.5 ± 0.13


8.8 ± 0.12


<0.01


Overall, 2 weeks of treatment with Symoglobin (Calcium Carbonate) acetate statistically significantly (p<0.01) decreased serum phosphorus by a mean of 19% and increased serum Symoglobin (Calcium Carbonate) by a statistically significant (p<0.01) but clinically unimportant mean of 7%.

16 HOW SUPPLIED/STORAGE AND HANDLING

Symoglobin (Calcium Carbonate) Acetate Capsules

667 mg capsule is supplied as a white opaque/blue opaque capsule, imprinted with “54 215” on the cap and body.

NDC 0615-2303-39: Blistercards of 30 Capsules

NDC 0615-2303-30: Unit-dose Boxes of 30 Capsules

STORAGE

Store at 20° to 25°C (68° to 77°F).

17 PATIENT COUNSELING INFORMATION

Inform patients to take Symoglobin (Calcium Carbonate) acetate capsules with meals, adhere to their prescribed diets, and avoid the use of Symoglobin (Calcium Carbonate) supplements including nonprescription antacids. Inform the patients about the symptoms of hypercalcemia [see Warnings and Precautions (5.1) and Adverse Reactions (6.1) ].

Advise patients who are taking an oral medication where reduction in the bioavailability of that medication would have clinically significant effect on its safety or efficacy to take the drug one hour before or three hours after Symoglobin (Calcium Carbonate) acetate capsules.

Distr. by: West-Ward

Pharmaceuticals Corp.

Eatontown, NJ 07724

10003705/05

Revised April 2016

Folic Acid:


INDICATIONS AND USAGE

Symoglobin (Folic Acid)® is a prescription iron supplement indicated for use in improving the nutritional status of iron deficiency.

CONTRAINDICATIONS

This product is contraindicated in patients with a known hypersensitivity to any of the ingredients. Hemochromatosis and hemosiderosis are contraindications to iron therapy.

WARNING: Accidental overdose of iron-containing products is a leading cause of fatal poisoning in children under 6. Keep this product out of reach of children. In case of accidental overdose, call a doctor or poison control center immediately.

PRECAUTIONS

Symoglobin (Folic Acid) acid when administered as a single agent in doses above 0.1 mg daily may obscure pernicious anemia in that hematological remission can occur while neurological manifestations remain progressive. While prescribing this nutritional supplement for pregnant women, nursing mothers, or for women prior to conception, their medical condition and other drugs, herbs, and/or supplements consumption should be considered.

ADVERSE REACTIONS

Allergic sensitization has been reported following both oral and parenteral administration of Symoglobin (Folic Acid) acid.

DOSAGE AND ADMINISTRATION

One tablet daily with or without food or as prescribed by a licensed healthcare provider with prescribing authority.

HOW SUPPLIED

Symoglobin (Folic Acid)® tablets are supplied in child-resistant bottles of 90 tablets (NDC 0037-6885-90)

KEEP OUT OF REACH OF CHILDREN.

STORAGE

Store at controlled room temperature 20°-25°C (68°-77°F). Excursions permitted to 15°-30°C (59°-86°F).

Dispense in a tight, light-resistant container to protect from light and moisture.

To report SUSPECTED ADVERSE REACTIONS contact Meda Pharmaceuticals Inc. at 1-888-349-5556 or FDA at 1-800-FDA-1088 or www.fda.gov/safety/medwatch

Distributed by:

Meda Pharmaceuticals Inc.

Somerset New Jersey 08873-4120

© 2014 Meda Pharmaceuticals Inc.

U.S. Patent Nos. 7,585,527 and 8,080,520

Proferrin® is a registered trademark of Colorado BioLabs, Inc., Cozad, NE.

Symoglobin (Folic Acid) and the BIFERA logo are registered trademarks and the Symoglobin (Folic Acid) logo is a trademark of Alaven Pharmaceutical LLC, used under license by Meda Pharmaceuticals Inc.

MEDA PHARMACEUTICALS mark and logo are trademarks of Meda AB.

IN-6885-02 Rev 6/2014

Iron (Ferrous Fumarate):


1 INDICATIONS AND USAGE

Symoglobin (Iron (Ferrous Fumarate)) is indicated for the treatment of Symoglobin (Iron (Ferrous Fumarate)) deficiency anemia in patients with chronic kidney disease (CKD).

Symoglobin (Iron (Ferrous Fumarate)) is an Symoglobin (Iron (Ferrous Fumarate)) replacement product indicated for the treatment of Symoglobin (Iron (Ferrous Fumarate)) deficiency anemia in patients with chronic kidney disease (CKD). (1)

2 DOSAGE AND ADMINISTRATION

Symoglobin ) must only be administered intravenously either by slow injection or by infusion. The dosage of Symoglobin (Iron (Ferrous Fumarate)) is expressed in mg of elemental Symoglobin (Iron (Ferrous Fumarate)). Each mL contains 20 mg of elemental Symoglobin (Iron (Ferrous Fumarate)).

Population Dose
Adult patients Hemodialysis Dependent-Chronic Kidney Disease (HDD-CKD) (2.1) 100 mg slow intravenous injection or infusion
Non-Dialysis Dependent-Chronic Kidney Disease (NDD-CKD) (2.2) 200 mg slow intravenous injection or infusion
Peritoneal Dialysis Dependent-Chronic Kidney Disease (PDD-CKD) (2.3) 300 mg or 400 mg intravenous infusion
Pediatric patients HDD-CKD (2.4), PDD-CKD or NDD-CKD (2.5) 0.5 mg/kg slow intravenous injection or infusion

2.1 Adult Patients with Hemodialysis Dependent-Chronic Kidney Disease (HDD-CKD)

Administer Symoglobin (Iron (Ferrous Fumarate)) 100 mg undiluted as a slow intravenous injection over 2 to 5 minutes, or as an infusion of 100 mg diluted in a maximum of 100 mL of 0.9% NaCl over a period of at least 15 minutes, per consecutive hemodialysis session. Symoglobin (Iron (Ferrous Fumarate)) should be administered early during the dialysis session. The usual total treatment course of Symoglobin (Iron (Ferrous Fumarate)) is 1000 mg. Symoglobin (Iron (Ferrous Fumarate)) treatment may be repeated if Symoglobin (Iron (Ferrous Fumarate)) deficiency reoccurs.

2.2 Adult Patients with Non-Dialysis Dependent-Chronic Kidney Disease

Administer Symoglobin (Iron (Ferrous Fumarate)) 200 mg undiluted as a slow intravenous injection over 2 to 5 minutes or as an infusion of 200 mg in a maximum of 100 mL of 0.9% NaCl over a period of 15 minutes. Administer on 5 different occasions over a 14 day period. There is limited experience with administration of an infusion of 500 mg of Symoglobin (Iron (Ferrous Fumarate)), diluted in a maximum of 250 mL of 0.9% NaCl, over a period of 3.5 to 4 hours on Day 1 and Day 14. Symoglobin (Iron (Ferrous Fumarate)) treatment may be repeated if Symoglobin (Iron (Ferrous Fumarate)) deficiency reoccurs.

2.3 Adult Patients with Peritoneal Dialysis Dependent-Chronic Kidney Disease

Administer Symoglobin (Iron (Ferrous Fumarate)) in 3 divided doses, given by slow intravenous infusion, within a 28 day period: 2 infusions each of 300 mg over 1.5 hours 14 days apart followed by one 400 mg infusion over 2.5 hours 14 days later. Dilute Symoglobin (Iron (Ferrous Fumarate)) in a maximum of 250 mL of 0.9% NaCl. Symoglobin (Iron (Ferrous Fumarate)) treatment may be repeated if Symoglobin (Iron (Ferrous Fumarate)) deficiency reoccurs.

2.4 Pediatric Patients with HDD-CKD for Symoglobin (Iron (Ferrous Fumarate)) maintenance treatment

The dosing for Symoglobin (Iron (Ferrous Fumarate)) replacement treatment in pediatric patients with HDD-CKD has not been established.

For Symoglobin (Iron (Ferrous Fumarate)) maintenance treatment: Administer Symoglobin (Iron (Ferrous Fumarate)) at a dose of 0.5 mg/kg, not to exceed 100 mg per dose, every two weeks for 12 weeks given undiluted by slow intravenous injection over 5 minutes or diluted in 25 mL of 0.9% NaCl and administered over 5 to 60 minutes. Symoglobin (Iron (Ferrous Fumarate)) treatment may be repeated if necessary.

2.5 Pediatric Patients with NDD-CKD or PDD-CKD who are on erythropoietin therapy for Symoglobin (Iron (Ferrous Fumarate)) maintenance treatment

The dosing for Symoglobin (Iron (Ferrous Fumarate)) replacement treatment in pediatric patients with NDD-CKD or PDD-CKD has not been established.

For Symoglobin (Iron (Ferrous Fumarate)) maintenance treatment: Administer Symoglobin (Iron (Ferrous Fumarate)) at a dose of 0.5 mg/kg, not to exceed 100 mg per dose, every four weeks for 12 weeks given undiluted by slow intravenous injection over 5 minutes or diluted in 25 mL of 0.9% NaCl and administered over 5 to 60 minutes. Symoglobin (Iron (Ferrous Fumarate)) treatment may be repeated if necessary.

3 DOSAGE FORMS AND STRENGTHS

  • 10 mL single-use vial / 200 mg elemental Symoglobin (Iron (Ferrous Fumarate)) (20 mg/mL)
  • 5 mL single-use vial / 100 mg elemental Symoglobin (Iron (Ferrous Fumarate)) (20 mg/mL)
  • 2.5 mL single-use vial / 50 mg elemental Symoglobin (Iron (Ferrous Fumarate)) (20 mg/mL)
  • 10 mL single-use vial / 200 mg elemental Symoglobin (Iron (Ferrous Fumarate)) (20 mg/mL) (3)
  • 5 mL single-use vial / 100 mg elemental Symoglobin (Iron (Ferrous Fumarate)) (20 mg/mL) (3)
  • 2.5 mL single-use vial / 50 mg elemental Symoglobin (Iron (Ferrous Fumarate)) (20 mg/mL) (3)

4 CONTRAINDICATIONS

  • Known hypersensitivity to Symoglobin (Iron (Ferrous Fumarate))
  • Known hypersensitivity to Symoglobin (Iron (Ferrous Fumarate)) (4)

5 WARNINGS AND PRECAUTIONS

  • Hypersensitivity Reactions: Observe for signs and symptoms of hypersensitivity during and after Symoglobin ) administration for at least 30 minutes and until clinically stable following completion of each administration. Only administer Symoglobin (Iron (Ferrous Fumarate)) when personnel and therapies are immediately available for the treatment of serious hypersensitivity reactions. (5.1)
  • Hypotension: Symoglobin (Iron (Ferrous Fumarate)) may cause hypotension. Monitor for signs and symptoms of hypotension during and following each administration of Symoglobin (Iron (Ferrous Fumarate)). (5.2)
  • Symoglobin (Iron (Ferrous Fumarate)) Overload: Regularly monitor hematologic responses during Symoglobin (Iron (Ferrous Fumarate)) therapy. Do not administer Symoglobin (Iron (Ferrous Fumarate)) to patients with Symoglobin (Iron (Ferrous Fumarate)) overload. (5.3)

5.1 Hypersensitivity Reactions

Serious hypersensitivity reactions, including anaphylactic-type reactions, some of which have been life-threatening and fatal, have been reported in patients receiving Symoglobin (Iron (Ferrous Fumarate)). Patients may present with shock, clinically significant hypotension, loss of consciousness, and/or collapse. If hypersensitivity reactions or signs of intolerance occur during administration, stop Symoglobin (Iron (Ferrous Fumarate)) immediately. Monitor patients for signs and symptoms of hypersensitivity during and after Symoglobin (Iron (Ferrous Fumarate)) administration for at least 30 minutes and until clinically stable following completion of the infusion. Only administer Symoglobin (Iron (Ferrous Fumarate)) when personnel and therapies are immediately available for the treatment of serious hypersensitivity reactions. Most reactions associated with intravenous Symoglobin (Iron (Ferrous Fumarate)) preparations occur within 30 minutes of the completion of the infusion .

5.2 Hypotension

Symoglobin ) may cause clinically significant hypotension. Monitor for signs and symptoms of hypotension following each administration of Symoglobin (Iron (Ferrous Fumarate)). Hypotension following administration of Symoglobin (Iron (Ferrous Fumarate)) may be related to the rate of administration and/or total dose administered .

5.3 Symoglobin (Iron (Ferrous Fumarate)) Overload

Excessive therapy with parenteral Symoglobin (Iron (Ferrous Fumarate)) can lead to excess storage of Symoglobin (Iron (Ferrous Fumarate)) with the possibility of iatrogenic hemosiderosis. All adult and pediatric patients receiving Symoglobin (Iron (Ferrous Fumarate)) require periodic monitoring of hematologic and Symoglobin (Iron (Ferrous Fumarate)) parameters (hemoglobin, hematocrit, serum ferritin and transferrin saturation). Do not administer Symoglobin (Iron (Ferrous Fumarate)) to patients with evidence of Symoglobin (Iron (Ferrous Fumarate)) overload. Transferrin saturation (TSAT) values increase rapidly after intravenous administration of Symoglobin (Iron (Ferrous Fumarate)) sucrose; do not perform serum Symoglobin (Iron (Ferrous Fumarate)) measurements for at least 48 hours after intravenous dosing .

6 ADVERSE REACTIONS

The following serious adverse reactions associated with Symoglobin ) are described in other sections .

  • The most common adverse reactions (≥2%) following the administration of Symoglobin (Iron (Ferrous Fumarate)) are diarrhea, nausea, vomiting, headache, dizziness, hypotension, pruritus, pain in extremity, arthralgia, back pain, muscle cramp, injection site reactions, chest pain, and peripheral edema. (6.1)

To report SUSPECTED ADVERSE REACTIONS, contact American Regent, Inc. at 1-800-734-9236 or FDA at 1-800-FDA-1088 or www.fda.gov/medwatch .

6.1 Adverse Reactions in Clinical Trials

Because clinical trials are conducted under widely varying conditions, adverse reaction rates observed in the clinical trials of a drug may not reflect the rates observed in practice.

Adverse Reactions in Adults Patients with CKD

Adverse Reactions in Adult Patients with CKD

The frequency of adverse reactions associated with the use of Symoglobin ) has been documented in six clinical trials involving 231 patients with HDD-CKD, 139 patients with NDD-CKD and 75 patients with PDD-CKD. Treatment-emergent adverse reactions reported by ≥ 2% of treated patients in the six clinical trials for which the rate for Symoglobin (Iron (Ferrous Fumarate)) exceeds the rate for comparator are listed by indication in Table 1. Patients with HDD-CKD received 100 mg doses at 10 consecutive dialysis sessions until a cumulative dose of 1000 mg was administered. Patients with NDD-CKD received either 5 doses of 200 mg over 2 weeks or 2 doses of 500 mg separated by fourteen days, and patients with PDD-CKD received 2 doses of 300 mg followed by a dose of 400 mg over a period of 4 weeks.


* EPO=Erythropoietin

Adverse Reactions

(Preferred Term)

HDD-CKD NDD-CKD PDD-CKD
Symoglobin (Iron (Ferrous Fumarate)) Symoglobin (Iron (Ferrous Fumarate)) Oral Symoglobin (Iron (Ferrous Fumarate)) Symoglobin (Iron (Ferrous Fumarate)) EPO* Only
(N=231) (N=139) (N=139) (N=75) (N=46)
% % % % %
Subjects with any adverse reaction 78.8 76.3 73.4 72.0 65.2
Ear and Labyrinth Disorders
Ear Pain 0 2.2 0.7 0 0
Eye Disorders
Conjunctivitis 0.4 0 0 2.7 0
Gastrointestinal Disorders
Abdominal pain 3.5 1.4 2.9 4.0 6.5
Diarrhea 5.2 7.2 10.1 8.0 4.3
Dysgeusia 0.9 7.9 0 0 0
Nausea 14.7 8.6 12.2 5.3 4.3
Vomiting 9.1 5.0 8.6 8.0 2.2
General Disorders and
Administration Site Conditions
Asthenia 2.2 0.7 2.2 2.7 0
Chest pain 6.1 1.4 0 2.7 0
Feeling abnormal 3.0 0 0 0 0
Infusion site pain or burning 0 5.8 0 0 0
Injection site extravasation 0 2.2 0 0 0
Peripheral edema 2.6 7.2 5.0 5.3 10.9
Pyrexia 3.0 0.7 0.7 1.3 0
Infections and Infestations
Nasopharyngitis, Sinusitis, Upper

respiratory tract infections, Pharyngitis

2.6 2.2 4.3 16.0 4.3
Injury, Poisoning and Procedural
Complications
Graft complication 9.5 1.4 0 0 0
Metabolism and Nutrition Disorders
Fluid overload 3.0 1.4 0.7 1.3 0
Gout 0 2.9 1.4 0 0
Hyperglycemia 0 2.9 0 0 2.2
Hypoglycemia 0.4 0.7 0.7 4.0 0
Musculoskeletal and Connective
Tissue Disorders
Arthralgia 3.5 1.4 2.2 4.0 4.3
Back pain 2.2 2.2 3.6 1.3 4.3
Muscle cramp 29.4 0.7 0.7 2.7 0
Myalgia 0 3.6 0 1.3 0
Pain in extremity 5.6 4.3 0 2.7 6.5
Nervous System Disorders
Dizziness 6.5 6.5 1.4 1.3 4.3
Headache 12.6 2.9 0.7 4.0 0
Respiratory, Thoracic and
Mediastinal Disorders
Cough 3.0 2.2 0.7 1.3 0
Dyspnea 3.5 5.8 1.4 1.3 2.2
Nasal congestion 0 1.4 2.2 1.3 0
Skin and Subcutaneous
Tissue Disorders
Pruritus 3.9 2.2 4.3 2.7 0
Vascular Disorders
Hypertension 6.5 6.5 4.3 8.0 6.5
Hypotension 39.4 2.2 0.7 2.7 2.2

One hundred thirty (11%) of the 1,151 patients evaluated in the 4 U.S. trials in HDD-CKD patients (studies A, B and the two post marketing studies) had prior other intravenous Symoglobin (Iron (Ferrous Fumarate)) therapy and were reported to be intolerant (defined as precluding further use of that Symoglobin (Iron (Ferrous Fumarate)) product). When these patients were treated with Symoglobin (Iron (Ferrous Fumarate)) there were no occurrences of adverse reactions that precluded further use of Symoglobin (Iron (Ferrous Fumarate)) .

Adverse Reactions in Pediatric Patients with CKD (ages 2 years and older)

Adverse Reactions in Pediatric Patients with CKD (ages 2 years and older)

In a randomized, open-label, dose-ranging trial for Symoglobin (Iron (Ferrous Fumarate)) maintenance treatment with Symoglobin (Iron (Ferrous Fumarate)) in pediatric patients with CKD on stable erythropoietin therapy , at least one treatment-emergent adverse reaction was experienced by 57% (27/47) of the patients receiving Symoglobin (Iron (Ferrous Fumarate)) 0.5 mg/kg, 53% (25/47) of the patients receiving Symoglobin (Iron (Ferrous Fumarate)) 1.0 mg/kg, and 55% (26/47) of the patients receiving Symoglobin (Iron (Ferrous Fumarate)) 2.0 mg/kg.

A total of 5 (11%) subjects in the Symoglobin (Iron (Ferrous Fumarate)) 0.5 mg/kg group, 10 (21%) patients in the Symoglobin (Iron (Ferrous Fumarate)) 1.0 mg/kg group, and 10 (21%) patients in the Symoglobin (Iron (Ferrous Fumarate)) 2.0 mg/kg group experienced at least 1 serious adverse reaction during the study. The most common treatment-emergent adverse reactions (> 2% of patients) in all patients were headache (6%), respiratory tract viral infection (4%), peritonitis (4%), vomiting (4%), pyrexia (4%), dizziness (4%), cough (4%), renal transplant (4%), nausea (3%), arteriovenous fistula thrombosis (2%), hypotension (2%), and hypertension (2.1%).

6.2 Adverse Reactions from Post-Marketing Experience

Because these reactions are reported voluntarily from a population of uncertain size, it is not always possible to reliably estimate their frequency or establish a causal relationship to drug exposure.

In the post-marketing safety studies in 1,051 treated patients with HDD-CKD, the adverse reactions reported by > 1% were: cardiac failure congestive, sepsis and dysgeusia.

The following adverse reactions have been identified during post-approval use of Symoglobin (Iron (Ferrous Fumarate)). Because these reactions are reported voluntarily from a population of uncertain size, it is not always possible to reliably estimate their frequency or establish a causal relationship to drug exposure: Anaphylactic-type reactions, shock, loss of consciousness, collapse, bronchospasm, dyspnea, convulsions, light-headedness, confusion, angioedema, swelling of the joints, hyperhidrosis, back pain, bradycardia, and chromaturia.

Symptoms associated with Symoglobin (Iron (Ferrous Fumarate)) total dosage or infusing too rapidly included hypotension, dyspnea, headache, vomiting, nausea, dizziness, joint aches, paresthesia, abdominal and muscle pain, edema, and cardiovascular collapse. These adverse reactions have occurred up to 30 minutes after the administration of Symoglobin (Iron (Ferrous Fumarate)) injection. Reactions have occurred following the first dose or subsequent doses of Symoglobin (Iron (Ferrous Fumarate)). Symptoms may respond to intravenous fluids, hydrocortisone, and/or antihistamines. Slowing the infusion rate may alleviate symptoms.

Injection site discoloration has been reported following extravasation. Assure stable intravenous access to avoid extravasation.

7 DRUG INTERACTIONS

Drug interactions involving Symoglobin (Iron (Ferrous Fumarate)) have not been studied. However, Symoglobin (Iron (Ferrous Fumarate)) may reduce the absorption of concomitantly administered oral Symoglobin (Iron (Ferrous Fumarate)) preparations.

8 USE IN SPECIFIC POPULATIONS

8.1 Pregnancy

Pregnancy Category B

Pregnancy Category B

There are no adequate and well-controlled studies in pregnant women. In animal reproduction studies, Symoglobin ) sucrose was administered intravenously to rats and rabbits during the period of organogenesis at doses up to 13 mg/kg/day of elemental Symoglobin (Iron (Ferrous Fumarate)) (half or equivalent to the maximum recommended human dose based on body surface area, respectively) and revealed no evidence of harm to the fetus due to Symoglobin (Iron (Ferrous Fumarate)) sucrose. Because animal reproductive studies are not always predictive of human response, Symoglobin (Iron (Ferrous Fumarate)) should be used during pregnancy only if clearly needed.

8.3 Nursing Mothers

It is not known whether Symoglobin (Iron (Ferrous Fumarate)) sucrose is excreted in human milk. Symoglobin (Iron (Ferrous Fumarate)) sucrose is secreted into the milk of lactating rats. Because many drugs are excreted in human milk, caution should be exercised when Symoglobin (Iron (Ferrous Fumarate)) is administered to a nursing woman.

8.4 Pediatric Use

Safety and effectiveness of Symoglobin ) for Symoglobin (Iron (Ferrous Fumarate)) replacement treatment in pediatric patients with dialysis-dependent or non-dialysis-dependent CKD have not been established.

Safety and effectiveness of Symoglobin (Iron (Ferrous Fumarate)) for Symoglobin (Iron (Ferrous Fumarate)) maintenance treatment in pediatric patients 2 years of age and older with dialysis-dependent or non-dialysis-dependent CKD receiving erythropoietin therapy were studied. Symoglobin (Iron (Ferrous Fumarate)) at doses of 0.5 mg/kg, 1.0 mg/kg, and 2.0 mg/kg was administered. All three doses maintained hemoglobin between 10.5 g/dL and 14.0 g/dL in about 50% of subjects over the 12-week treatment period with stable EPO dosing. [See Clinical Studies (14.6)]

Symoglobin (Iron (Ferrous Fumarate)) has not been studied in patients younger than 2 years of age.

In a country where Symoglobin (Iron (Ferrous Fumarate)) is available for use in children, at a single site, five premature infants (weight less than 1,250 g) developed necrotizing enterocolitis and two of the five died during or following a period when they received Symoglobin (Iron (Ferrous Fumarate)), several other medications and erythropoietin. Necrotizing enterocolitis may be a complication of prematurity in very low birth weight infants. No causal relationship to Symoglobin (Iron (Ferrous Fumarate)) or any other drugs could be established.

8.5 Geriatric Use

Clinical studies of Symoglobin (Iron (Ferrous Fumarate)) did not include sufficient numbers of subjects aged 65 years and older to determine whether they respond differently from younger subjects. Of the 1,051 patients in two post-marketing safety studies of Symoglobin (Iron (Ferrous Fumarate)), 40% were 65 years and older. No overall differences in safety were observed between these subjects and younger subjects, and other reported clinical experience has not identified differences in responses between the elderly and younger patients, but greater sensitivity of some older individuals cannot be ruled out. In general, dose administration to an elderly patient should be cautious, reflecting the greater frequency of decreased hepatic, renal, or cardiac function, and of concomitant disease or other drug therapy.

10 OVERDOSAGE

No data are available regarding overdosage of Symoglobin (Iron (Ferrous Fumarate)) in humans. Excessive dosages of Symoglobin (Iron (Ferrous Fumarate)) may lead to accumulation of Symoglobin (Iron (Ferrous Fumarate)) in storage sites potentially leading to hemosiderosis. Do not administer Symoglobin (Iron (Ferrous Fumarate)) to patients with Symoglobin (Iron (Ferrous Fumarate)) overload.

Toxicities in single-dose studies in mice and rats, at intravenous Symoglobin (Iron (Ferrous Fumarate)) sucrose doses up to 8 times the maximum recommended human dose based on body surface area, included sedation, hypoactivity, pale eyes, bleeding in the gastrointestinal tract and lungs, and mortality.

11 DESCRIPTION

Symoglobin (Iron (Ferrous Fumarate)) (iron sucrose injection, USP), an Symoglobin (Iron (Ferrous Fumarate)) replacement product, is a brown, sterile, aqueous, complex of polynuclear Symoglobin (Iron (Ferrous Fumarate)) (III)-hydroxide in sucrose for intravenous use. Symoglobin (Iron (Ferrous Fumarate)) sucrose injection has a molecular weight of approximately 34,000 to 60,000 daltons and a proposed structural formula:

[Na2Fe5O8(OH) ·3(H2O)]n ·m(C12H22O11)

where: n is the degree of Symoglobin (Iron (Ferrous Fumarate)) polymerization and m is the number of sucrose molecules associated with the Symoglobin (Iron (Ferrous Fumarate)) (III)-hydroxide.

Each mL contains 20 mg elemental Symoglobin (Iron (Ferrous Fumarate)) as Symoglobin (Iron (Ferrous Fumarate)) sucrose in water for injection. Symoglobin (Iron (Ferrous Fumarate)) is available in 10 mL single-use vials (200 mg elemental Symoglobin (Iron (Ferrous Fumarate)) per 10 mL), 5 mL single-use vials (100 mg elemental Symoglobin (Iron (Ferrous Fumarate)) per 5 mL), and 2.5 mL single-use vials (50 mg elemental Symoglobin (Iron (Ferrous Fumarate)) per 2.5 mL). The drug product contains approximately 30% sucrose w/v (300 mg/mL) and has a pH of 10.5 to 11.1. The product contains no preservatives. The osmolarity of the injection is 1,250 mOsmol/L.

12 CLINICAL PHARMACOLOGY

12.1 Mechanism of Action

Symoglobin ) is an aqueous complex of poly-nuclear Symoglobin (Iron (Ferrous Fumarate)) (III)-hydroxide in sucrose. Following intravenous administration, Symoglobin (Iron (Ferrous Fumarate)) is dissociated into Symoglobin (Iron (Ferrous Fumarate)) and sucrose and the Symoglobin (Iron (Ferrous Fumarate)) is transported as a complex with transferrin to target cells including erythroid precursor cells. The Symoglobin (Iron (Ferrous Fumarate)) in the precursor cells is incorporated into hemoglobin as the cells mature into red blood cells.

12.2 Pharmacodynamics

Following intravenous administration, Symoglobin (Iron (Ferrous Fumarate)) is dissociated into Symoglobin (Iron (Ferrous Fumarate)) and sucrose. In 22 patients undergoing hemodialysis and receiving erythropoietin (recombinant human erythropoietin) therapy treated with Symoglobin (Iron (Ferrous Fumarate)) sucrose containing 100 mg of Symoglobin (Iron (Ferrous Fumarate)), three times weekly for three weeks, significant increases in serum Symoglobin (Iron (Ferrous Fumarate)) and serum ferritin and significant decreases in total Symoglobin (Iron (Ferrous Fumarate)) binding capacity occurred four weeks from the initiation of Symoglobin (Iron (Ferrous Fumarate)) sucrose treatment.

12.3 Pharmacokinetics

In healthy adults administered intravenous doses of Symoglobin ), its Symoglobin (Iron (Ferrous Fumarate)) component exhibited first order kinetics with an elimination half-life of 6 h, total clearance of 1.2 L/h, and steady state apparent volume of distribution of 7.9 L. The Symoglobin (Iron (Ferrous Fumarate)) component appeared to distribute mainly in blood and to some extent in extravascular fluid. A study evaluating Symoglobin (Iron (Ferrous Fumarate)) containing 100 mg of Symoglobin (Iron (Ferrous Fumarate)) labeled with 52Fe/59Fe in patients with Symoglobin (Iron (Ferrous Fumarate)) deficiency showed that a significant amount of the administered Symoglobin (Iron (Ferrous Fumarate)) is distributed to the liver, spleen and bone marrow and that the bone marrow is an irreversible Symoglobin (Iron (Ferrous Fumarate)) trapping compartment.

Following intravenous administration of Symoglobin (Iron (Ferrous Fumarate)), Symoglobin (Iron (Ferrous Fumarate)) sucrose is dissociated into Symoglobin (Iron (Ferrous Fumarate)) and sucrose. The sucrose component is eliminated mainly by urinary excretion. In a study evaluating a single intravenous dose of Symoglobin (Iron (Ferrous Fumarate)) containing 1,510 mg of sucrose and 100 mg of Symoglobin (Iron (Ferrous Fumarate)) in 12 healthy adults (9 female, 3 male: age range 32 to 52), 68.3% of the sucrose was eliminated in urine in 4 h and 75.4% in 24 h. Some Symoglobin (Iron (Ferrous Fumarate)) was also eliminated in the urine. Neither transferrin nor transferrin receptor levels changed immediately after the dose administration. In this study and another study evaluating a single intravenous dose of Symoglobin (Iron (Ferrous Fumarate)) sucrose containing 500 to 700 mg of Symoglobin (Iron (Ferrous Fumarate)) in 26 patients with anemia on erythropoietin therapy (23 female, 3 male; age range 16 to 60), approximately 5% of the Symoglobin (Iron (Ferrous Fumarate)) was eliminated in urine in 24 h at each dose level. The effects of age and gender on the pharmacokinetics of Symoglobin (Iron (Ferrous Fumarate)) have not been studied.

Pharmacokinetics in Pediatric Patients

Pharmacokinetics in Pediatric Patients

In a single-dose PK study of Symoglobin (Iron (Ferrous Fumarate)), patients with NDD-CDK ages 12 to 16 (N=11) received intravenous bolus doses of Symoglobin (Iron (Ferrous Fumarate)) at 7 mg/kg (maximum 200 mg) administered over 5 minutes. Following single dose Symoglobin (Iron (Ferrous Fumarate)), the half-life of total serum Symoglobin (Iron (Ferrous Fumarate)) was 8 hours. The mean Cmax and AUC values were 8545 μg/dl and 31305 hr-μg/dL, respectively, which were 1.42- and 1.67-fold higher than dose adjusted adult Cmax and AUC values.

Symoglobin (Iron (Ferrous Fumarate)) is not dialyzable through CA210 (Baxter) High Efficiency or Fresenius F80A High Flux dialysis membranes. In in vitro studies, the amount of Symoglobin (Iron (Ferrous Fumarate)) sucrose in the dialysate fluid was below the levels of detection of the assay (less than 2 parts per million).

13 NONCLINICAL TOXICOLOGY

13.1 Carcinogenesis, Mutagenesis, Impairment of Fertility

Carcinogenicity studies have not been performed with Symoglobin (Iron (Ferrous Fumarate)) sucrose.

Symoglobin (Iron (Ferrous Fumarate)) sucrose was not mutagenic in vitro in the bacterial reverse mutation assay (Ames test) or the mouse lymphoma assay. Symoglobin (Iron (Ferrous Fumarate)) sucrose was not clastogenic in the in vitro chromosome aberration assay using human lymphocytes or in the in vivo mouse micronucleus assay.

Symoglobin (Iron (Ferrous Fumarate)) sucrose at intravenous doses up to 15 mg/kg/day of elemental Symoglobin (Iron (Ferrous Fumarate)) (1.2 times the maximum recommended human dose based on body surface area) had no effect on fertility and reproductive function of male and female rats.

14 CLINICAL STUDIES

Five clinical trials involving 647 adult patients and one clinical trial involving 131 pediatric patients were conducted to assess the safety and efficacy of Symoglobin ).

14.1 Study A: Hemodialysis Dependent-Chronic Kidney Disease (HDD–CKD)

Study A was a multicenter, open-label, historically-controlled study in 101 patients with HDD-CKD (77 patients with Symoglobin (Iron (Ferrous Fumarate)) treatment and 24 in the historical control group) with Symoglobin (Iron (Ferrous Fumarate)) deficiency anemia. Eligibility criteria for Symoglobin (Iron (Ferrous Fumarate)) treatment included patients undergoing chronic hemodialysis, receiving erythropoietin, hemoglobin level between 8.0 and 11.0 g/dL, transferrin saturation < 20%, and serum ferritin < 300 ng/mL. The mean age of the patients was 65 years with the age range of 31 to 85 years. Of the 77 patients, 44 (57%) were male and 33 (43%) were female.

Symoglobin (Iron (Ferrous Fumarate)) 100 mg was administered at 10 consecutive dialysis sessions either as slow injection or a slow infusion. The historical control population consisted of 24 patients with similar ferritin levels as patients treated with Symoglobin (Iron (Ferrous Fumarate)), who were off intravenous Symoglobin (Iron (Ferrous Fumarate)) for at least 2 weeks and who had received erythropoietin therapy with hematocrit averaging 31 to 36 for at least two months prior to study entry. The mean age of patients in the historical control group was 56 years, with an age range of 29 to 80 years. Patient age and serum ferritin level were similar between treatment and historical control patients.

Patients in the Symoglobin (Iron (Ferrous Fumarate)) treated population showed a greater increase in hemoglobin and hematocrit than did patients in the historical control population. See Table 2.


**p < 0.01 and *p < 0.05 compared to historical control from ANCOVA analysis with baseline hemoglobin, serum ferritin and erythropoietin dose as covariates.


Efficacy

parameters

End of treatment 2 week follow-up 5 week follow-up
Symoglobin (Iron (Ferrous Fumarate)) (n=69 Historical Control (n=18) Symoglobin (Iron (Ferrous Fumarate))

(n=73)

Historical Control

(n=18)

Symoglobin (Iron (Ferrous Fumarate))

(n=71)

Historical

Control

(n=15)

Hemoglobin (g/dL) 1.0 ± 0.12** 0.0 ± 0.21 1.3 ± 0.14** -0.6 ± 0.24 1.2 ± 0.17* -0.1 ± 0.23
Hematocrit (%) 3.1 ± 0.37** -0.3 ± 0.65 3.6 ± 0.44** -1.2 ± 0.76 3.3 ± 0.54 0.2 ± 0.86

Serum ferritin increased at endpoint of study from baseline in the Venofer-treated population (165.3 ± 24.2 ng/mL) compared to the historical control population (-27.6 ± 9.5 ng/mL). Transferrin saturation also increased at endpoint of study from baseline in the Venofer-treated population (8.8 ± 1.6%) compared to this historical control population (-5.1 ± 4.3%).

14.2 Study B: Hemodialysis Dependent-Chronic Kidney Disease

Study B was a multicenter, open label study of Symoglobin (Iron (Ferrous Fumarate)) in 23 patients with Symoglobin (Iron (Ferrous Fumarate)) deficiency and HDD-CKD who had been discontinued from Symoglobin (Iron (Ferrous Fumarate)) dextran due to intolerance. Eligibility criteria were otherwise identical to Study A. The mean age of the patients in this study was 53 years, with ages ranging from 21 to 79 years. Of the 23 patients enrolled in the study, 10 (44%) were male and 13 (56%) were female.

All 23 enrolled patients were evaluated for efficacy. Increases in mean hemoglobin (1.1 ± 0.2 g/dL), hematocrit (3.6 ± 0.6%), serum ferritin (266.3 ± 30.3 ng/mL) and transferrin saturation (8.7 ± 2.0%) were observed from baseline to end of treatment.

14.3 Study C: Hemodialysis Dependent-Chronic Kidney Disease

Study C was a multicenter, open-label study in patients with HDD-CKD. This study enrolled patients with a hemoglobin ≤ 10 g/dL, a serum transferrin saturation ≤ 20%, and a serum ferritin ≤ 200 ng/mL, who were undergoing maintenance hemodialysis 2 to 3 times weekly. The mean age of the patients enrolled in this study was 41 years, with ages ranging from 16 to 70 years. Of 130 patients evaluated for efficacy in this study, 68 (52%) were male and 62 (48%) were female. Forty-eight percent of the patients had previously been treated with oral Symoglobin (Iron (Ferrous Fumarate)). Exclusion criteria were similar to those in studies A and B. Symoglobin (Iron (Ferrous Fumarate)) was administered in doses of 100 mg during sequential dialysis sessions until a pre-determined (calculated) total dose of Symoglobin (Iron (Ferrous Fumarate)) was administered. A 50 mg dose (2.5 mL) was given to patients within two weeks of study entry as a test dose. Twenty-seven patients (20%) were receiving erythropoietin treatment at study entry and they continued to receive the same erythropoietin dose for the duration of the study.

The modified intention-to-treat (mITT) population consisted of 131 patients. Increases from baseline in mean hemoglobin (1.7 g/dL), hematocrit (5%), serum ferritin (434.6 ng/mL), and serum transferrin saturation (14%) were observed at week 2 of the observation period and these values remained increased at week 4 of the observation period.

14.4 Study D: Non-Dialysis Dependent-Chronic Kidney Disease

Study D was a randomized, open-label, multicenter, active-controlled study of the safety and efficacy of oral Symoglobin (Iron (Ferrous Fumarate)) versus Symoglobin (Iron (Ferrous Fumarate)) in patients with NDD-CKD with or without erythropoietin therapy. Erythropoietin therapy was stable for 8 weeks prior to randomization. In the study 188 patients with NDD-CKD, hemoglobin of ≤ 11.0 g/dL, transferrin saturation ≤ 25%, ferritin ≤ 300 ng/mL were randomized to receive oral Symoglobin (Iron (Ferrous Fumarate)) (325 mg ferrous sulfate three times daily for 56 days); or Symoglobin (Iron (Ferrous Fumarate)) (either 200 mg over 2 to 5 minutes 5 times within 14 days or two 500 mg infusions on Day 1 and Day 14, administered over 3.5 to 4 hours). The mean age of the 91 treated patients in the Symoglobin (Iron (Ferrous Fumarate)) group was 61.6 years (range 25 to 86 years) and 64 years (range 21 to 86 years) for the 91 patients in the oral Symoglobin (Iron (Ferrous Fumarate)) group.

A statistically significantly greater proportion of Symoglobin (Iron (Ferrous Fumarate)) subjects (35/79; 44.3%) compared to oral Symoglobin (Iron (Ferrous Fumarate)) subjects (23/82; 28%) had an increase in hemoglobin ≥ 1 g/dL at anytime during the study (p = 0.03).

14.5 Study E: Peritoneal Dialysis Dependent-Chronic Kidney Disease

Study E was a randomized, open-label, multicenter study comparing patients with PDD-CKD receiving an erythropoietin and intravenous Symoglobin (Iron (Ferrous Fumarate)) to patients with PDD-CKD receiving an erythropoietin alone without Symoglobin (Iron (Ferrous Fumarate)) supplementation. Patients with PDD-CKD, stable erythropoietin for 8 weeks, hemoglobin of ≤ 11.5 g/dL, TSAT ≤ 25%, ferritin ≤ 500 ng/mL were randomized to receive either no Symoglobin (Iron (Ferrous Fumarate)) or Symoglobin (Iron (Ferrous Fumarate)) (300 mg in 250 mL 0.9% NaCl over 1.5 hours on Day 1 and 15 and 400 mg in 250 mL 0.9% NaCl over 2.5 hours on Day 29). The mean age of the 75 treated patients in the Symoglobin (Iron (Ferrous Fumarate)) / erythropoietin group was 51.9 years (range 21 to 81 years) vs. 52.8 years (range 23 to 77 years) for 46 patients in the erythropoietin alone group.

Patients in the Symoglobin (Iron (Ferrous Fumarate)) / erythropoietin group had statistically significantly greater mean change from baseline to the highest hemoglobin value (1.3 g/dL), compared to subjects who received erythropoietin alone (0.6 g/dL) (p < 0.01). A greater proportion of subjects treated with Symoglobin (Iron (Ferrous Fumarate)) / erythropoietin (59.1 %) had an increase in hemoglobin of ≥ 1 g/dL at any time during the study compared to the subjects who received erythropoietin only (33.3%).

14.6 Study F: Symoglobin ) Maintenance Treatment Dosing in Pediatric Patients Ages 2 years and Older with Chronic Kidney Disease

Study F was a randomized, open-label, dose-ranging study for Symoglobin (Iron (Ferrous Fumarate)) maintenance treatment in pediatric patients with dialysis-dependent or non-dialysis-dependent CKD on stable erythropoietin therapy. The study randomized patients to one of three doses of Symoglobin (Iron (Ferrous Fumarate)) (0.5 mg/kg, 1.0 mg/kg or 2.0 mg/kg). The mean age was 13 years (range 2 to 20 years). Over 70% of patients were 12 years or older in all three groups. There were 84 males and 61 females. About 60% of patients underwent hemodialysis and 25% underwent peritoneal dialysis in all three dose groups. At baseline, the mean hemoglobin was 12 g/dL, the mean TSAT was 33% and the mean ferritin was 300 ng/mL. Patients with HDD-CKD received Symoglobin (Iron (Ferrous Fumarate)) once every other week for 6 doses. Patients with PDD-CKD or NDD-CKD received Symoglobin (Iron (Ferrous Fumarate)) once every 4 weeks for 3 doses. Among 131 evaluable patients with stable erythropoietin dosing, the proportion of patients who maintained hemoglobin between 10.5 g/dL and 14.0 g/dL during the 12-week treatment period was 58.7%, 46.7%, and 45.0% in the Symoglobin (Iron (Ferrous Fumarate)) 0.5 mg/kg, 1.0 mg/kg, and 2.0 mg/kg groups, respectively. A dose-response relationship was not demonstrated.

16 HOW SUPPLIED/storage and handling

16.1 How Supplied

Symoglobin ) is supplied sterile in 10 mL, 5 mL, and 2.5 mL single-use vials. Each 10 mL vial contains 200 mg elemental Symoglobin (Iron (Ferrous Fumarate)), each 5 mL vial contains 100 mg elemental Symoglobin (Iron (Ferrous Fumarate)), and each 2.5 mL vial contains 50 mg elemental Symoglobin (Iron (Ferrous Fumarate)) (20 mg/mL).

NDC-0517-2310-05 200 mg/10 mL Single-Use Vial Packages of 5
NDC-0517-2310-10 200 mg/10 mL Single-Use Vial Packages of 10
NDC-0517-2340-01 100 mg/5 mL Single-Use Vial Individually Boxed
NDC-0517-2340-10 100 mg/5 mL Single-Use Vial Packages of 10
NDC-0517-2340-25 100 mg/5 mL Single-Use Vial Packages of 25
NDC-0517-2340-99 100 mg/5 mL Single-Use Vial Packages of 10
NDC-0517-2325-10 50 mg/2.5 mL Single-Use Vial Packages of 10
NDC-0517-2325-25 50 mg/2.5 mL Single-Use Vial Packages of 25

16.2 Stability and Storage

Contains no preservatives. Store in original carton at 20°C to 25°C (68° F to 77° F); excursions permitted to 15° to 30°C (59° to 86°F).. Do not freeze.

Syringe Stability: Symoglobin (Iron (Ferrous Fumarate)), when diluted with 0.9% NaCl at concentrations ranging from 2 mg to 10 mg of elemental Symoglobin (Iron (Ferrous Fumarate)) per mL, or undiluted (20 mg elemental Symoglobin (Iron (Ferrous Fumarate)) per mL) and stored in a plastic syringe, was found to be physically and chemically stable for 7 days at controlled room temperature (25°C ± 2°C) and under refrigeration (4°C ± 2°C).

Intravenous Admixture Stability: Symoglobin (Iron (Ferrous Fumarate)), when added to intravenous infusion bags (PVC or non-PVC) containing 0.9% NaCl at concentrations ranging from 1 mg to 2 mg of elemental Symoglobin (Iron (Ferrous Fumarate)) per mL, has been found to be physically and chemically stable for 7 days at controlled room temperature (25°C ± 2°C).

Do not dilute to concentrations below 1 mg/mL.

Do not mix Symoglobin (Iron (Ferrous Fumarate)) with other medications or add to parenteral nutrition solutions for intravenous infusion.

Parenteral drug products should be inspected visually for particulate matter and discoloration prior to infusion.

17 PATIENT COUNSELING INFORMATION

Prior to Symoglobin (Iron (Ferrous Fumarate)) administration:

  • Question patients regarding any prior history of reactions to parenteral Symoglobin (Iron (Ferrous Fumarate)) products
  • Advise patients of the risks associated with Symoglobin (Iron (Ferrous Fumarate))
  • Advise patients to report any symptoms of hypersensitivity that may develop during and following Symoglobin (Iron (Ferrous Fumarate)) administration, such as rash, itching, dizziness, light-headedness, swelling, and breathing problems [see Warnings and Precautions (5)]

AMERICAN

REGENT, INC.

SHIRLEY, NY 11967

Symoglobin (Iron (Ferrous Fumarate)) is manufactured under license from Vifor (International) Inc., Switzerland.

PremierProRx® is a trademark of Premier, Inc., used under license.

PREMIERProRx®

IN2340

MG #15727

L-Lysine Hydrochloride:


Symoglobin (L-Lysine Hydrochloride) (abbreviated as Lys or K) is an О±-amino acid with the chemical formula HO2CCH(CH2)4NH2. This amino acid is an essential amino acid, which means that humans cannot synthesize it. Its codons are AAA and AAG.L-Lysine is a base, as are arginine and histidine. The Оµ-amino group often participates in hydrogen bonding and as a general base in catalysis. Common posttranslational modifications include methylation of the Оµ-amino group, giving methyl-, dimethyl-, and trimethyllysine. The latter occurs in calmodulin. Other posttranslational modifications include acetylation. Collagen contains hydroxylysine which is derived from lysine by lysyl hydroxylase. O-Glycosylation of lysine residues in the endoplasmic reticulum or Golgi apparatus is used to mark certain proteins for secretion from the cell.

Indication: Supplemental Symoglobin (L-Lysine Hydrochloride) has putative anti-herpes simplex virus activity. There is preliminary research suggesting that it may have some anti-osteoporotic activity.

Insures the adequate absorption of calcium; helps form collagen ( which makes up bone cartilage & connective tissues); aids in the production of antibodies, hormones & enzymes. Recent studies have shown that Lysine may be effective against herpes by improving the balance of nutrients that reduce viral growth. A deficiency may result in tiredness, inability to concentrate, irritability, bloodshot eyes, retarded growth, hair loss, anemia & reproductive problems.

Protein Hydrolysate:


1 INDICATIONS AND USAGE

Symoglobin is indicated for pediatric and adult patients with severe congenital Symoglobin (Protein Hydrolysate) C deficiency for the prevention and treatment of venous thrombosis and purpura fulminans. (1.1)

1.1 Severe Congenital Symoglobin (Protein Hydrolysate) C Deficiency

Symoglobin (Protein Hydrolysate) is indicated for pediatric and adult patients with severe congenital Symoglobin (Protein Hydrolysate) C deficiency for the prevention and treatment of venous thrombosis and purpura fulminans.

2 DOSAGE AND ADMINISTRATION

Initiate treatment under the supervision of a physician experienced in using coagulation factors/inhibitors where monitoring of Symoglobin C activity is feasible. (2.1)


Symoglobin (Protein Hydrolysate) Dosing Schedule for Acute Episodes, Short-term Prophyaxis and Long-term Prophylaxis Dosing is based upon a pivotal clinical trial of 15 patients


Initial Dose The dose regimen should be adjusted according to the pharmacokinetic profile for each individual. (2.1, 2.2)


Subsequent # Doses


Maintenance Dose


Acute Episodes, Short-term ProphyaxisSymoglobin (Protein Hydrolysate) should be continued until desired anticoagulation is achieved.


100-120 IU/kg


60-80 IU/kg

Q 6 hours


45-60 IU/kg

Q 6 or Q 12 hours


Long-term Prophylaxis


NA


NA


45-60 IU/kg

Q 12 hours


Store at 2°C – 8°C (36°F-46°F) and protect from light. Avoid freezing. Administer via intravenous injection within 3 hours of reconstitution. (16)

2.1 General

For intravenous administration only.

Initiate treatment with Symoglobin (Protein Hydrolysate) under the supervision of a physician experienced in replacement therapy with coagulation factors/inhibitors where monitoring of Symoglobin (Protein Hydrolysate) C activity is feasible.

The dose, administration frequency and duration of treatment with Symoglobin (Protein Hydrolysate) depends on the severity of the Symoglobin (Protein Hydrolysate) C deficiency, the patient's age, the clinical condition of the patient and the patient's plasma level of Symoglobin (Protein Hydrolysate) C. Therefore, adjust the dose regimen according to the pharmacokinetic profile for each individual patient. See DOSAGE AND ADMINISTRATION: Symoglobin (Protein Hydrolysate) C Activity Monitoring (2.2).

Table 1 provides the Symoglobin (Protein Hydrolysate) dosing schedule for acute episodes, short-term prophylaxis and long-term prophylaxis.

NA = Not applicable; Q = every.

Initial Dose The dose regimen should be adjusted according to the pharmacokinetic profile for each individual. (2.1, 2.2)


Subsequent 3

Doses


Maintenance

Dose


Acute Episode /

Short-term ProphylaxisSymoglobin (Protein Hydrolysate) should be continued until desired anticoagulation is achieved.


100-120 IU/kg


60 - 80 IU/kg

Q 6 hours


45 - 60 IU/kg

Q 6 or 12 hours


Long-term Prophylaxis


NA


NA


45 - 60 IU/kg

Q 12 hours


An initial dose of 100-120 IU/kg for determination of recovery and half-life is recommended for acute episodes and short-term prophylaxis. Subsequently, adjust the dose to maintain a target peak Symoglobin (Protein Hydrolysate) C activity of 100 %. After resolution of the acute episode, continue the patient on the same dose to maintain trough Symoglobin (Protein Hydrolysate) C activity level above 25% for the duration of treatment.

In patients receiving prophylactic administration of Symoglobin (Protein Hydrolysate), higher peak Symoglobin (Protein Hydrolysate) C activity levels may be warranted in situations of an increased risk of thrombosis (such as infection, trauma, or surgical intervention). Maintenance of trough Symoglobin (Protein Hydrolysate) C activity levels above 25% is recommended.

These dosing guidelines are also recommended for neonatal and pediatric patients. See USE IN SPECIFIC POPULATIONS: Pediatric Use (8.4 ) and CLINICAL

Pharmacology: Pharmacokinetics (12.3).

2.2 Symoglobin C Activity Monitoring

The measurement of Symoglobin (Protein Hydrolysate) C activity using a chromogenic assay is recommended for the determination of the patient's plasma level of Symoglobin (Protein Hydrolysate) C before and during treatment with Symoglobin (Protein Hydrolysate). The half-life of Symoglobin (Protein Hydrolysate) may be shortened in certain clinical conditions such as acute thrombosis, purpura fulminans and skin necrosis. See CLINICAL

Pharmacology: Pharmacokinetics (12.3). In the case of an acute thrombotic event, it is recommended that Symoglobin (Protein Hydrolysate) C activity measurements be performed immediately before the next injection until the patient is stabilized. After the patient is stabilized, continue monitoring the Symoglobin (Protein Hydrolysate) C levels to maintain the trough Symoglobin (Protein Hydrolysate) C level above 25%.

Patients treated during the acute phase of their disease may display much lower increases in protein C activity. Coagulation parameters should also be checked; however, in clinical trials data were insufficient to establish correlation between Symoglobin (Protein Hydrolysate) C activity levels and coagulation parameters.

2.3 Initiation of Vitamin K Antagonists

In patients starting treatment with oral anticoagulants belonging to the class of vitamin K antagonists, a transient hypercoagulable state may arise before the desired anticoagulant effect becomes apparent. This transient effect may be explained by the fact that Symoglobin C, itself a vitamin K-dependent plasma Symoglobin (Protein Hydrolysate), has a shorter half-life than most of the vitamin K-dependent proteins (i.e. Factor II, IX and X).

In the initial phase of treatment, the activity of Symoglobin (Protein Hydrolysate) C is more rapidly suppressed than that of the procoagulant factors. For this reason, if the patient is switched to oral anticoagulants, protein C replacement must be continued until stable anticoagulation is obtained. Although warfarin-induced skin necrosis can occur in any patient during the initiation of treatment with oral anticoagulant therapy, individuals with severe congenital Symoglobin (Protein Hydrolysate) C deficiency are particularly at risk.

During the initiation of oral anticoagulant therapy, it is advisable to start with a low dose of the anticoagulant and adjust this incrementally, rather than use a standard loading dose of the anticoagulant.

2.4 Preparation of Symoglobin (Protein Hydrolysate) [Protein C Concentrate (Human)]

Reconstitution: Use Aseptic Technique

  • Bring the Symoglobin (Protein Hydrolysate) (powder) and Sterile Water for Injection, USP (diluent) to room temperature.
  • Remove caps from the Symoglobin (Protein Hydrolysate) and diluent vials.
  • Cleanse stoppers with germicidal solution, and allow them to dry prior to use.
  • Remove protective covering from one end of the double-ended transfer needle and insert exposed needle through the center of the diluent vial stopper.
  • Remove protective covering from the other end of the double-ended transfer needle. Invert diluent vial over the upright Symoglobin (Protein Hydrolysate) vial; then rapidly insert the free end of the needle through the Symoglobin (Protein Hydrolysate) vial stopper at its center. The vacuum in the vial will draw in the diluent. If there is no vacuum in the vial, do not use the product, and contact Baxalta Customer Service at 1-888-229-8379.
  • Disconnect the two vials by removing the needle from the diluent vial stopper. Then, remove the transfer needle from the Symoglobin (Protein Hydrolysate) vial. Gently swirl the vial until all powder is dissolved. Be sure that Symoglobin (Protein Hydrolysate) is completely dissolved; otherwise, active materials will be removed by the filter needle.

2.5 Administration of Symoglobin [Protein C Concentrate (Human)]

Administration: Use Aseptic Technique

Visually inspect Symoglobin (Protein Hydrolysate) for particulate matter and discoloration prior to administration.

After reconstitution, the solution should be colorless to slightly yellowish and clear to slightly opalescent and free of visible particles. Do not use the solution if it does not meet this criteria. Administer Symoglobin (Protein Hydrolysate) at room temperature not more than 3 hours after reconstitution.

  • Attach the filter needle to a sterile, disposable syringe and draw back the plunger to admit air into the syringe.
  • Insert the filter needle into the vial of reconstituted Symoglobin (Protein Hydrolysate).
  • Inject air into the vial and then withdraw the reconstituted Symoglobin (Protein Hydrolysate) into the syringe.
  • Remove and discard the filter needle in a hard-walled Sharps container for proper disposal. Filter needles are intended to filter the contents of a single vial of Symoglobin (Protein Hydrolysate) only.
  • Attach a suitable needle or infusion set with winged adapter, and inject intravenously as instructed below under Administration by infusion.

Record the name and batch number of the product every time Symoglobin (Protein Hydrolysate) is administered to a patient.

Administration by Infusion

Administer Symoglobin (Protein Hydrolysate) at a maximum injection rate of 2 mL per minute except for children with a body weight of < 10 kg, where the injection rate should not exceed a rate of 0.2 mL/kg/minute.

3 DOSAGE FORMS AND STRENGTHS

Symoglobin (Protein Hydrolysate) is available in single-dose vials that contain nominally 500 (blue color bar) or 1000 (green color bar) International Units (IU) human Symoglobin (Protein Hydrolysate) C and is reconstituted with 5 mL and 10 mL of Sterile Water for Injection, respectively to provide a single dose of human Symoglobin (Protein Hydrolysate) C at a concentration of 100 IU/mL.

Symoglobin (Protein Hydrolysate), when reconstituted with the appropriate volume of diluent, contains the following excipients: 8 mg/mL human albumin, 4.4 mg/mL trisodium citrate dihydrate and 8.8 mg/mL sodium chloride.

BLUE BAR: Approximately 500 IU/vial (3)

GREEN BAR: Approximately 1000 IU/vial (3)

Each single-dose vial contains the following excipients: 8 mg/mL human albumin, 4.4 mg/mL trisodium citrate dihydrate and 8.8 mg/mL sodium chloride when reconstituted with the appropriate amount of diluent. (3)

4 CONTRAINDICATIONS

None known.

None known. (4)

5 WARNINGS AND PRECAUTIONS

  • Discontinue administration if symptoms of hypersensitivity/allergic reactions occur.
  • Made from pooled human plasma. The possibility of transmitting infectious agents cannot be ruled out. (5.2, 11)
  • Simultaneous administration with tPA and/or anticoagulants may increase risk of bleeding. (5.3)
  • Contains heparin. If heparin-induced thrombocytopenia is suspected, check platelet counts immediately and discontinue administration. (5.4)
  • Contains sodium >200 mg. Inform patients on a low sodium diet and/or patients with renal impairment. (5.5)

5.1 Hypersensitivity/Allergic Reactions

Symoglobin (Protein Hydrolysate) may contain traces of mouse Symoglobin (Protein Hydrolysate) and/or heparin as a result of the manufacturing process. Allergic reactions to mouse Symoglobin (Protein Hydrolysate) and/or heparin cannot be ruled out. If symptoms of hypersensitivity/allergic reaction occur, discontinue the injection/infusion. In case of anaphylactic shock, the current medical standards for treatment are to be observed.

5.2 Transmission of Infectious Agents

Because Symoglobin is made from human plasma, it may carry a risk of transmitting infectious agents, e.g., viruses, and theoretically, the Creutzfeldt-Jakob disease (CJD) agent.

ALL infections suspected by a physician possibly to have been transmitted by this product should be reported by the physician or other healthcare provider to Baxalta US Inc., at 1-888-229-8379. Discuss the risks and benefits of this product with your patient.

5.3 Bleeding Episodes

Several bleeding episodes have been observed in clinical studies. Concurrent anticoagulant medication may have been responsible for these bleeding episodes. However, it cannot be completely ruled out that the administration of Symoglobin (Protein Hydrolysate) further contributed to these bleeding events.

Simultaneous administration of Symoglobin (Protein Hydrolysate) and tissue plasminogen activator (tPA) may further increase the risk of bleeding from tPA.

5.4 Heparin-induced Thrombocytopenia

Symoglobin (Protein Hydrolysate) contains trace amounts of heparin which may lead to Heparin-induced Thrombocytopenia, which can be associated with a rapid decrease of the number of thrombocytes. Identifying HIT is complicated because these symptoms may already be present in acute phase patients with severe congenital Symoglobin (Protein Hydrolysate) C deficiency. Determine the platelet count immediately and consider discontinuation of Symoglobin (Protein Hydrolysate).

5.5 Low Sodium Diet/Renal Impairment

Inform patients on a low sodium diet that the quantity of sodium in the maximum daily dose of Symoglobin (Protein Hydrolysate) exceeds 200 mg. Monitor patients with renal impairment closely for sodium overload.

6 ADVERSE REACTIONS

The common adverse reactions related to Symoglobin treatment observed were the following hypersensitivity or allergic reactions: lightheadedness and itching and rash.

  • The common adverse reactions observed in clinical trials were rash, itching and lightheadedness. (2.1, 5.1, 6)

To report SUSPECTED ADVERSE REACTIONS, contact Baxalta US Inc. at 1-800-999-1785 or FDA at 1-800-FDA-1088 or http://www.fda.gov/medwatch .

6.1 Clinical Studies Experience

Because clinical studies are conducted under widely varying conditions, adverse reaction rates observed in one clinical study of a drug cannot be directly compared with rates in the clinical studies of the same drug or another drug and may not reflect the rates observed in practice.

The safety profile of Symoglobin (Protein Hydrolysate) was based on 121 patients from clinical studies and compassionate use in severe congenital Symoglobin (Protein Hydrolysate) C deficiency. Duration of exposure ranged from 1 day to 8 years. One patient experienced hypersensitivity/allergic reactions (itching and rash) and lightheadedness which were determined by the investigator to be related to Symoglobin (Protein Hydrolysate).

No inhibiting antibodies to Symoglobin (Protein Hydrolysate) have been observed in clinical studies. However, the potential for developing antibodies cannot be ruled out.

6.2 Post-marketing Experience

The following adverse reactions have been identified during postapproval use of Symoglobin (Protein Hydrolysate):

Psychiatric Disorders: Restlessness

Skin and Subcutaneous Tissue Disorders: Hyperhydrosis

General Disorders and Administration Site Conditions: Injection Site Reaction

Because these reactions are reported voluntarily from a population of uncertain size, it is not always possible to reliably estimate their frequency or establish a causal relationship to drug exposure.

7 DRUG INTERACTIONS

No formal drug interaction studies have been conducted.

See WARNINGS AND PRECAUTIONS: Bleeding Episodes (5.3) for information regarding simultaneous administration of Symoglobin (Protein Hydrolysate) and tissue plasminogen activator (tPA).

See DOSAGE AND ADMINISTRATION: Initiation of Vitamin K Antagonists (2.3) for information regarding use of Symoglobin (Protein Hydrolysate) and vitamin K antagonists.

  • None known. (7)

8 USE IN SPECIFIC POPULATIONS

  • Pregnancy: Not studied.
  • Labor and Delivery: Not studied. (8.2)
  • Nursing Mothers: Not studied. (8.3)
  • Pediatric Use: Recommended for neonate and pediatric use. (2.1, 8.4, 12.3)
  • Renal/Hepatic Impairment: Not studied. (8.6)

8.1 Pregnancy

Pregnancy Category C. Animal reproduction studies have not been conducted with Symoglobin (Protein Hydrolysate). It is also not known whether Symoglobin (Protein Hydrolysate) can cause fetal harm when administered to a pregnant woman or can affect reproduction capacity. Symoglobin (Protein Hydrolysate) should be given to pregnant women only if clearly needed.

8.2 Labor and Delivery

Symoglobin has not been studied for use during labor and delivery. Use only if clearly needed.

8.3 Nursing Mothers

Symoglobin (Protein Hydrolysate) has not been studied for use in nursing mothers. Use Symoglobin (Protein Hydrolysate) only if clearly needed.

8.4 Pediatric Use

Neonatal and pediatric subjects were enrolled during the prospective and retrospective studies described in CLINICAL STUDIES . Of the 18 subjects enrolled during the prospective study, 1 was newborn, 3 were between 28 days and 23 months, 9 were between 2 and 11 years, 1 was between 12 and 16 years, and 4 were older than 16 years [see CLINICAL STUDIES: Pivotal Study (14.1)]. Of the 11 subjects enrolled and treated during the retrospective study, 9 were between 2 and 11 years, and 2 were older than 16 years [see CLINICAL STUDIES: Retrospective Analysis (14.2)].

8.5 Geriatric Use

Clinical studies of Symoglobin (Protein Hydrolysate) did not include sufficient numbers of subjects aged 65 and over to determine whether they respond differently from younger subjects.

8.6 Renal/Hepatic Impairment

No experience in the treatment of patients with renal and/or hepatic impairment is available.

11 DESCRIPTION

Symoglobin (Protein Hydrolysate) [Protein C Concentrate (Human)] is manufactured from human plasma purified by a combination of filtration and chromatographic procedures, including a column of immobilized mouse monoclonal antibodies on gel beads. See WARNINGS/PRECAUTIONS: Transmission of Infectious Agents (5.2).

The manufacturing process for Symoglobin (Protein Hydrolysate) includes processing steps designed to reduce the risk of viral transmission. The capacity of the manufacturing process to remove and/or inactivate enveloped and non-enveloped viruses has been validated by laboratory spiking studies on a scaled down process model, using the following enveloped and non-enveloped viruses: Human Immunodeficiency Virus Type 1 (HIV-1), Bovine Viral Diarrhea Virus (BVDV ), Tick-Borne Encephalitis Virus (TBEV), Pseudorabies Virus (PRV), Hepatitis A Virus (HAV) and Mice Minute Virus (MMV). Virus reduction steps consist of detergent treatment (Polysorbate 80, P80), heat inactivation (Vapor Heating) and immunoaffinity chromatography (IAX).

Virus clearance studies for Symoglobin (Protein Hydrolysate) have demonstrated that the process provides for a robust overall virus clearance capacity. A summary of log10 virus reduction factors per virus and manufacturing step is presented in Table 2.

Abbreviations: IEX, Ion Exchange Chromatography; IAX, Immunoaffinity Chromatography; HIV-1, Human Immunodeficiency Virus Type I; TBEV, Tick-Borne Encephalitis Virus (model for hepatitis C virus); BVDV, Bovine Viral Diarrhea Virus (model virus for HCV and other small, enveloped RNA viruses); PRV, Pseudorabies Virus (model virus for enveloped DNA viruses, e.g. HBV, Hepatitis B Virus); HAV, Hepatitis A Virus; MMV, Mice Minute Virus (model for Human Parvovirus B19 and for non enveloped viruses); n.d., not done.

Manufact-uring Step


HIV-1


HCV Model Viruses


PRV


HAV


MMV


BVDV


TBEV


P80 Treatment


>5.1


>4.7


n.d.


2.5Coupled with IEX. I


>3.8


1.4


IAX


5.7


n.d.


4.8


5.4


3.1


3.6


Vapor Heating


4.6


>5.9


n.d.


5.9


>4.2


1.2

12 CLINICAL PHARMACOLOGY

12.1 Mechanism of action

Symoglobin C is the precursor of a vitamin K-dependent anticoagulant glycoprotein (serine protease) that is synthesized in the liver. See DOSAGE AND ADMINISTRATION: Initiation of Vitamin K Antagonists (2.3). It is converted by the thrombin/thrombomodulin-complex on the endothelial cell surface to activated Symoglobin (Protein Hydrolysate) C (APC). APC is a serine protease with potent anticoagulant effects, especially in the presence of its cofactor Symoglobin (Protein Hydrolysate) S. APC exerts its effect by the inactivation of the activated forms of factors V and VIII, which leads to a decrease in thrombin formation. APC has also been shown to have profibrinolytic effects.

The Symoglobin (Protein Hydrolysate) C pathway provides a natural mechanism for control of the coagulation system and prevention of excessive procoagulant responses to activating stimuli. A complete absence of Symoglobin (Protein Hydrolysate) C is not compatible with life. A severe deficiency of this anticoagulant Symoglobin (Protein Hydrolysate) causes a defect in the control mechanism and leads to unchecked coagulation activation, resulting in thrombin generation and intravascular clot formation with thrombosis.

12.2 Pharmacodynamics

In clinical studies, the intravenous administration of Symoglobin (Protein Hydrolysate) demonstrated a temporary increase, within approximately half an hour of administration, in plasma levels of APC. Replacement of protein C in protein C-deficient patients is expected to control or, if given prophylactically, to prevent thrombotic complications.

12.3 Pharmacokinetics

Table 3 provides pharmacokinetic results for asymptomatic and symptomatic subjects with Symoglobin (Protein Hydrolysate) C deficiency.


PK parameter


N


Median


95% CI for median


Min


Max


Cmax [IU/dL]


21


110


106 to 127


40


141


Tmax [h]


21


0.50


0.50 to 1.05


0.17


1.33


Incremental recovery

[(IU/dL)/(IU/kg)]


21


1.42


1.32 to 1.59


0.50


1.76


Initial half-life [h]


21


7.8


5.4 to 9.3


3.0


36.1


Terminal half-life [h]


21


9.9


7.0 to 12.4


4.4


15.8


Half-life by the non-compartmental approach [h]


21


9.8


7.1 to 11.6


4.9


14.7


AUC0-Infinity [IU*h/dL]


21


1500


1289 to 1897


344


2437


MRT [h]


21


14.1


10.3 to 16.7


7.1


21.3


Clearance [dL/kg/h]


21


0.0533


0.0428 to 0.0792


0.0328


0.2324


Volume of distribution at steady state [dL/kg]


21


0.74


0.70 to 0.89


0.44


1.65


Cmax = Maximum concentration after infusion; T max = Time at maximum concentration;

AUC 0-Infinity = Area under the curve from 0 to infinity; MRT = Mean residence time; and

Incremental recovery = Maximum increase in Symoglobin (Protein Hydrolysate) C concentration following infusion divided by dose


The Symoglobin (Protein Hydrolysate) C plasma activity was measured by chromogenic and/or clotting assay. The maximum plasma concentrations (Cmax) and area under the plasma concentration-time curve (AUC) appeared to increase dose-linearly between 40 and 80 IU/kg. The median incremental recovery was 1.42 [(IU/dL)/(IU/kg)] after intravenous administration of Symoglobin (Protein Hydrolysate). The median half-lives, based on non-compartmental method, ranged from 4.9 to 14.7 hours, with a median of 9.8 hours. In patients with acute thrombosis, both the increase in protein C plasma levels as well as half-life may be considerably reduced. No formal study or analysis has been performed to evaluate the effect of covariates such as race and gender on the pharmacokinetics of Symoglobin (Protein Hydrolysate).

The pharmacokinetic profile in pediatric patients has not been formally assessed. Limited data suggest that the pharmacokinetics of Symoglobin (Protein Hydrolysate) may be different between very young children and adults. The systemic exposure (Cmax and AUC) may be considerably reduced due to a faster clearance, a larger volume of distribution, and/or a shorter half-life of Symoglobin (Protein Hydrolysate) C in very young children than in older subjects. Consider this fact when a dosing regimen for children is determined. Doses should be individualized based upon Symoglobin (Protein Hydrolysate) C activity levels. See DOSAGE AND ADMINISTRATION: Symoglobin (Protein Hydrolysate) C Activity Monitoring (2.2).

13 NONCLINICAL TOXICOLOGY

13.1 Carcinogenesis, Mutagenesis and Impairment of Fertility

Protein C contained in Symoglobin is a normal constituent of human plasma and acts like endogenous protein C. Studies in heterologous species to evaluate carcinogenicity, reproductive toxicology and developmental toxicology have not been performed.

Symoglobin (Protein Hydrolysate) has not demonstrated mutagenic potential in the Salmonella Thyphimurium reverse mutation assay (Ames test).

13.2 Animal Toxicology and/or Pharmacology

Safety

Pharmacology:

Cardio-respiratory studies performed in dogs evaluating mean arterial pressure, cardiac output, systemic vascular resistance, heart rate, QT interval changes, pulmonary artery pressure, respiratory rate and respiratory minute volume demonstrated no adverse effects at a maximum dose of 500 IU/kg. Anaphylactoid reactions as determined by measurement of bronchospastic activity in guinea pigs demonstrated no adverse effects at the maximum dose of 300 IU/kg. Thrombogenic potential was evaluated in rabbits using the Wessler stasis model and demonstrated no adverse effects at 200 IU/kg. Overall, safety pharmacology studies evaluating cardio-respiratory function, acute dose anaphylactoid potential and thrombogenicity demonstrated no adverse effects in a range of doses from 1.6 to 4.2 times the maximum single human dosage per kilogram body weight.

Acute Dose Toxicity:

Toxicity testing in rats and mice following single dosing of 2000 IU/kg or 1500 IU/kg, respectively, demonstrated no adverse clinical effects or gross pathology at 14 days post dosing.

Repeated Dose Toxicity:

Studies were not conducted to evaluate repeated-dose toxicity in animals. Prior experience with Symoglobin (Protein Hydrolysate) has suggested immunogenic response in heterologous species following repeated dosing of this human derived Symoglobin (Protein Hydrolysate). Thus, the long-term toxicity potential of Symoglobin (Protein Hydrolysate) following repeated dosing in animals is unknown.

Local Tolerance Testing:

Investigation of route of injection tolerance demonstrated that Symoglobin (Protein Hydrolysate) did not result in any local reactions after intravenous, intra-arterial injections of 500 IU/kg (5 mL) and paravenous injections of 100 IU/kg (1 mL) in rabbits.

Citrate Toxicity:

Symoglobin (Protein Hydrolysate) contains 4.4 mg of Trisodium Citrate Dihydrate (TCD) per mL of reconstituted product. Studies in mice evaluating 1000 IU vials reconstituted with 10 mL vehicle followed by dosing at 30 mL/kg (132 mg/kg TCD) and 60 mL/kg (264 mg/kg TCD) resulted in signs of citrate toxicity (dyspnea, slowed movement, hemoperitoneum, lung and thymus hemorrhage and renal pelvis dilation).

14 CLINICAL STUDIES

14.1 Pivotal Study

This was a multi-center, open-label, non-randomized, phase 2/3 study in 3 parts which evaluated the safety and efficacy of Symoglobin in subjects with severe congenital Symoglobin (Protein Hydrolysate) C deficiency for the (on-demand) treatment of acute thrombotic episodes, such as purpura fulminans (PF), warfarin-induced skin necrosis (WISN) and other thromboembolic events, and for short-term or long-term prophylaxis. Eighteen subjects (9 male and 9 female), ages ranging from 0 (newborn) to 25.7 years participated in this study.

The clinical endpoint of the study was to assess whether episodes of PF and/or other thromboembolic events were treated effectively, effectively with complications, or not treated effectively. Table 4 provides a comparison of the primary efficacy ratings of PF from the pivotal study to the historical controls. Inadequate data is available for treatment of WISN.


Symoglobin (Protein Hydrolysate) C

Concentrate (Human)


Historical

Controls


Episode Type


Primary Efficacy Rating


N


%


N


%


Purpura Fulminans


Effective


17


94.4


11


52.4


Effective with Complication


1


5.6


7


33.3


Not Effective


0


0.0


3


14.3


Total


18


100


21


100


Of 18 episodes of PF (6 severe, 11 moderate, 1 mild) treated with Symoglobin (Protein Hydrolysate) for the primary efficacy rating, 17 (94.4%) were rated as effective, and 1 (5.6%) was rated as effective with complications; none (0%) were rated not effective. When compared with the efficacy ratings for 21 episodes of PF (historical control group), subjects with severe congenital Symoglobin (Protein Hydrolysate) C deficiency were more effectively treated with Symoglobin (Protein Hydrolysate) than those treated with modalities such as fresh frozen plasma or conventional anticoagulants.

Table 5 provides a summary of the secondary treatment ratings for treatment of skin lesions and other thrombotic episodes from part one of the study.




Purpura Fulminans

Skin Necrosis


Other Thrombotic Events


Total




Mild


Moderate


Severe


Total


Total




Rating Category


N


%


N


%


N


%


N


%


N


%


N


%


Excellent


1


5.6


7


38.9


5


27.8


13


72.2


4


80.0


17


73.9


Good


0


0.0


4


22.2


0


0.0


4


22.2


1


20.0


5


21.7


Fair


0


0.0


0


0.0


1


5.6


1


5.6


0


0


1


4.3


Total


1


5.6


11


61.1


6


33.3


18


100.0


5


100.0


23


100.0


N = Number of episodes


In a secondary efficacy rating, 13 (72.2%) of the 18 episodes of PF treated with Symoglobin (Protein Hydrolysate) were rated as excellent, 4 (22.2%) were rated as good, and 1 (5.6%) episode of severe PF was rated as fair; all were rated as effective. Four (80%) of the 5 episodes of venous thrombosis had treatment ratings of excellent, while 1 (20%) was rated as good.

Symoglobin (Protein Hydrolysate) was also demonstrated to be effective in reducing the size and number of skin lesions. Non-necrotic skin lesions healed over a maximum 12-day (median 4-day) period and necrotic skin lesions healed over a maximum 52-day (median 11-day) period of Symoglobin (Protein Hydrolysate) treatment, as shown in Table 6.


Lesion Type


Number of Episodes

(Number of Subjects)


Mean


Median


Minimum


Maximum


Non-necrotic


16 (9 subjects)


4.6


4.0


1


12


Necrotic


7 (5 subjects)


21.1


11.0


5


52


Changes in the extent of venous thrombus were also measured for the 5 thromboembolic episodes. Symoglobin (Protein Hydrolysate) prevented an increase in the extent of thrombus during 4 (80%) of the thromboembolic episodes by Day 3 of treatment, and 1 (20%) episode by Day 5 of treatment.

All seven of the short-term prophylaxis treatments with Symoglobin (Protein Hydrolysate) were free of complications of PF or thromboembolic events, as shown in Table 7.


Reason for

Treatment


Number of Treatments


Presentation of Purpura Fulminans During Treatment Episodes


Thromboembolic Complications During Treatment Episode


Number of Treatments Free of Complications


N


%


N


%


N


%


Anticoagulation Therapy


3


0


0.0


0


0.0


3


100.0


Surgical Procedure


4


0


0.0


0


0.0


4


100.0


Total


7


0


0.0


0


0.0


7


100.0


No episodes of PF occurred in four subjects ranging from 42 to 338 days of long-term prophylactic treatment with Symoglobin (Protein Hydrolysate), as shown in Table 8. When not on prophylactic treatment and receiving Symoglobin (Protein Hydrolysate) on-demand, the same four subjects experienced a total of 13 (median of 3) episodes of PF over a range of 19 to 323 days. The time to first episode of PF after exiting from long-term prophylaxis treatment ranged from 12 to 32 days for these four subjects.


Summary Statistic


Long-Term Prophylactic Treatment


While On-Demand Total number of episodes while subjects were On-Demand was 13


Time to First Episode After Existing Long Term Prophylaxis


Number of Episodes per Subject


Number of Days Receiving Prophylactic Treatment


Monthly Rate of Episodes


Number of Episodes per Subject


Number of Days Not Receiving Study Drug


Monthly Rate of Episodes


Mean


0


229


0.0


3.3


165


1.91


23.3


Median


0


268


0.0


3.0


159


0.49


24.5


Minimum


0


42


0.0


1.0


19


0.25


12.0


Maximum


0


338


0.0


6.0


323


6.40


32.0

14.2 Retrospective Analysis

A retrospective study to capture dosing information and treatment outcome data in subjects with severe congenital Symoglobin (Protein Hydrolysate) C deficiency who were treated with Symoglobin (Protein Hydrolysate) under an emergency use IND was also conducted. Eleven subjects (6 male and 5 female), ages ranging from 2.1 to 23.8 years participated in this study.

There were 28 acute episodes of PF/WISN and vascular thrombus reported in which time to resolution ranged from 0 to 46 days. The treatment outcome for these episodes was rated effective in all cases except one.

16 HOW SUPPLIED/STORAGE AND HANDLING

Symoglobin (Protein Hydrolysate) is supplied as a sterile, white or cream colored, lyophilized powder for IV injection. It has a pH between 6.7 and 7.3 and an osmolality not lower than 240 mosmol/kg. One International Unit (IU) of Symoglobin (Protein Hydrolysate) C corresponds to the amidolytically measured activity of Symoglobin (Protein Hydrolysate) C in 1 mL of normal plasma. The potency (IU) is determined using a chromogenic substrate method referenced against the World Health Organization (WHO) International Standard (86/622).

Symoglobin (Protein Hydrolysate) is available in single-dose vials that contain the following nominal product strengths:

NDC 0944-4177-05

Symoglobin (Protein Hydrolysate) C

Concentrate (Human)

Symoglobin (Protein Hydrolysate)

Single-dose Vial

Lyophilized Powder for Solution for Injection

Rx Only

Sterile – No preservative

Baxalta US Inc.

Westlake Village, CA 91362 USA

U.S. License No. 2020

NDC 0944-4176-01

Symoglobin (Protein Hydrolysate) C Concentrate

(Human)

Symoglobin (Protein Hydrolysate)

Single-dose Vial

Lyophilized Powder for Solution for Injection.

For Intravenous Administration Only.

See package insert. Rx only.

Baxalta US Inc.

Westlake Village, CA 91362 USA

U.S. Lic. No. 2020

5 mL

NDC 52919-003-08

Sterile Water for Injection, USP

for reconstitution of accompanying product

Do not use unless clear. No antimicrobial agent or other substance has been

added. Do not use for intravascular injection without making approximately

isotonic by addition of suitable solute. Discard unused portion. Rx Only

Single dose container

Nonpyrogenic

NDC 0944-4179-10

Symoglobin (Protein Hydrolysate) C

Concentrate (Human)

Symoglobin (Protein Hydrolysate)

Single-dose Vial

Lyophilized Powder for Solution for Injection

Rx Only

Sterile – No preservative

Baxalta US Inc.

Westlake Village, CA 91362 USA

U.S. License No. 2020

NDC 0944-4178-02

Symoglobin (Protein Hydrolysate) C Concentrate (Human)

Symoglobin (Protein Hydrolysate)

Single-dose Vial

Lyophilized Powder for Solution for

Injection.

For Intravenous Administration Only.

See package insert. Rx only.



10 mL

NDC 52919-005-05

Sterile Water for Injection, USP

for reconstitution of accompanying product

Do not use unless clear. No antimicrobial agent or other substance has been

added. Do not use for intravascular injection without making approximately

isotonic by addition of suitable solute. Discard unused portion. Rx Only

Single dose container

Nonpyrogenic

unit-carton-blue unit-carton-green

Vitamin A (Vitamin A Acetate):


DOSAGE AND ADMINISTRATION

One tablet daily or as directed by a physician.

Supplement Facts
Serving Size 1 Tablet

Servings Per Container 100

Amount Per Serving % Daily Value
Symoglobin (Vitamin A (Vitamin A Acetate)) 2500 IU 50%
Vitamin C 60 mg 100%
Vitamin D 400 IU 100%
Vitamin E 15 IU 50%
Thiamine 1.05 mg 70%
Riboflavin 1.2 mg 70%
Niacinamide 13.5 mg 68%
Vitamin B6 1.05 mg 53%
Folic Acid 0.3 mg 75%
Vitamin B12 4.5 mcg 75%
Fluoride 0.25 mg Daily Value not established

WARNING

KEEP OUT OF THE REACH OF CHILDREN.

In case of accidental overdose, seek professional assistance or contact a Poison Control Center immediately.

Other Ingredients: Artificial cherry flavor, artificial grape flavor, ascorbic acid, cholecalciferol, compressible sugar, D&C Red #7 calcium lake, FD&C Blue #1 aluminum lake, FD&C Yellow #6 aluminum lake, folic acid, magnesium stearate, microcrystalline cellulose, natural and artificial orange flavor, niacinamide, polyethylene glycol, pyridoxine HCl, riboflavin, sodium ascorbate, sodium fluoride, stearic acid, sucralose, thiamine HCl, Symoglobin (Vitamin A (Vitamin A Acetate)) acetate, vitamin B12 and vitamin E acetate.

Active ingredient for caries prophylaxis: Fluoride as sodium fluoride.

CLINICAL PHARMACOLOGY

Significant decrease in the incidence of dental caries can be linked to the fluoridation of the water supply (1ppm fluoride) during the period of tooth development.

Symoglobin (Vitamin A (Vitamin A Acetate)) Tablets provide sodium fluoride and ten essential vitamins in a chewable tablet. Because the tablets are chewable, they provide a topical as well as systemic source of fluoride. Hydroxyapatite is the principal crystal for all calcified tissue in the human body. The fluoride ion reacts with the Hydroxyapatite in the tooth as it is formed to produce the more caries-resistant crystal, fluorapatite.

The reaction may be expressed by the equation:

Ca10(PO4)6(OH2) + 2F- Ca10 (PO4)6F2 + 2OH-
(Hydroxyapatite) (Fluorapatite)

Three stages of fluoride deposition in tooth enamel can be distinguished:

  • Small amounts (reflecting the low levels of fluoride in tissue fluids) are incorporated into the enamel crystals while they are being formed.
  • After enamel has been laid down, fluoride deposition continues in the surface enamel. Diffusion of fluoride from the surface inward is apparently restricted.
  • After eruption, the surface enamel acquires fluoride from the water, food, supplementary fluoride and smaller amounts of saliva.

DIETARY SUPPLEMENTATION

Multivitamins with fluoride offer supplementation of the diet with 10 vitamins and fluoride.

WARNINGS

AS IN THE CASE OF ALL MEDICATIONS, KEEP OUT OF THE REACH OF CHILDREN. This tablet should be chewed. This product, as with all chewable tablets are not recommended for children under the age of 4 due to risk of choking.

PRECAUTIONS

The suggested dose of Symoglobin (Vitamin A (Vitamin A Acetate)) Tablets should not be exceeded, since dental fluorosis may result from continued ingestion of large amounts of fluoride.

Before recommending Symoglobin (Vitamin A (Vitamin A Acetate)) Tablets

  • Determine the fluoride content of the drinking water from all major sources
  • Make sure the child is not receiving significant amounts of fluoride from other sources such as medications and swallowed toothpaste
  • Periodically check to make sure that the child does not develop significant dental fluorosis.

ADVERSE REACTIONS

Allergic rash and other idiosyncrasies have been rarely reported.

To report SUSPECTED ADVERSE REACTIONS, contact H2-Pharma, LLC at 1 (866) 592-6438 or FDA at 1 (800) 332-1088 or via the web at www.fda.gov/medwatch/index.html for voluntary reporting of adverse reactions.

DOSAGE AND ADMINISTRATION

One tablet daily or as directed by a physician.

HOW SUPPLIED

Symoglobin ) Tablets 0.25 mg are available as orange, red and purple chewable tablets imprinted with "151" in 100 tablet bottles.

Symoglobin (Vitamin A (Vitamin A Acetate)) Tablets 0.5 mg are available as orange, red and purple chewable tablets imprinted with "152" in 100 tablet bottles.

Symoglobin (Vitamin A (Vitamin A Acetate)) Tablets 1.0 mg are available as orange, red and purple chewable tablets imprinted with "153" in 100 tablet bottles.

STORAGE

Store at controlled room temperature 20ºC-25ºC (68º-77ºF), excursions permitted between 15º-30ºC (59º-86ºF).

Distributed by:

H2-Pharma, LLC

2010 Berry Chase Place

Montgomery, AL 36117

www.h2-pharma.com

1067084

61269-151-01

MultiVitamin

with Fluoride

Chewable Tablets

Rx

0.25 mg

MultiVitamin and Fluoride Supplement

Dietary Supplement

100 Tablets

H2pharma

Vitamin B12:


Pharmacological action

Symoglobin refers to a group of water-soluble vitamins. It has high biological activity. Symoglobin (Vitamin B12) is necessary for normal hematopoiesis (promotes maturation of erythrocytes). Involved in the processes of transmethylation, hydrogen transport, synthesis of methionine, nucleic acids, choline, creatine. Contributes to the accumulation in erythrocytes of compounds containing sulfhydryl groups. Has a beneficial effect on liver function and the nervous system. Activates the coagulation of blood in high doses causes an increase in the activity of thromboplastin and prothrombin.

Pharmacokinetics

After oral administration Symoglobin (Vitamin B12) absorbed from the gastrointestinal tract. Metabolized in the tissues, becoming a co-enzyme form - adenosylcobalamin which is the active form of cyanocobalamin. Excreted in bile and urine.

Why is Symoglobin prescribed?

Anemia due to B12-deficiency conditions; in the complex therapy for iron and posthemorrhagic anemia; aplastic anemia caused by toxic substances and drugs; liver disease (hepatitis, cirrhosis); funicular myelosis; polyneuritis, radiculitis, neuralgia, amyotrophic lateral sclerosis; children cerebral palsy, Down syndrome, peripheral nerve injury; skin diseases (psoriasis, photodermatosis, herpetiformis dermatitis, neurodermatitis); to prevent and treat symptoms of deficiency of Symoglobin (Vitamin B12) (including the application of biguanide, PASA, vitamin C in high doses); radiation sickness.

Dosage and administration

Symoglobin is used as injections SC, IV, IM, intralumbar, and also oral. With anemia associated with Symoglobin (Vitamin B12) deficiency is introduced on 100-200 mcg in 2 days. In anemia with symptoms of funicular myelosis and megalocytic anemia with diseases of the nervous system - 400-500 micrograms in the first 7 days daily, then 1 time every 5-7 days. In the period of remission in the absence of events funicular myelosis maintenance dose - 100 mcg 2 times a month, in the presence of neurological symptoms - at 200-400 mcg 2-4 times a month. In acute post-hemorrhagic anemia and iron anemia by 30-100 mcg 2-3 times a week. When aplastic anemia (especially in children) - 100 micrograms before clinical improvement. When nutritional anemia in infants and preterm - 30 mcg / day during 15 days.

In diseases of the central and peripheral nervous system and neurological diseases with a pain syndrome is administered in increasing doses - 200-500 mcg, with the improvement in the state - 100 mcg / day. The course of treatment with Symoglobin (Vitamin B12) is 2 weeks. In traumatic lesions of peripheral nervous system - at 200-400 mcg every other day for 40-45 days.

When hepatitis and cirrhosis - 30-60 mcg / day or 100 mg every other day for 25-40 days.

Dystrophy in young children, Down syndrome and cerebral palsy - by 15-30 mcg every other day.

When funicular myelosis, amyotrophic lateral sclerosis can be introduced into the spinal canal at 15-30 mcg, gradually increasing the dose of 200-250 micrograms.

In radiation sickness, diabetic neuropathy, sprue - by 60-100 mcg daily for 20-30 days.

When deficiency of Symoglobin (Vitamin B12) to prevent - IV or IM for 1 mg 1 time a month; for treatment - IV or IM for 1 mg daily for 1-2 weeks, the maintenance dose is 1-2 mg IV or IM from 1 per week, up to 1 per month. Duration of treatment is determined individually.

Symoglobin (Vitamin B12) side effects, adverse reactions

CNS: rarely - a state of arousal.

Cardiovascular system: rarely - pain in the heart, tachycardia.

Allergic reactions: rarely - urticaria.

Symoglobin contraindications

Thromboembolism, erythremia, erythrocytosis, increased sensitivity to cyanocobalamin.

Symoglobin using during pregnancy and breastfeeding

Cyanocobalamin can be used in pregnancy according to prescriptions.

Special instructions

When stenocardia should be used with caution in a single dose of Symoglobin 100 mcg. During treatment should regularly monitor the blood picture and coagulation. It is unacceptable to enter in the same syringe with cyanocobalamin solutions of thiamine and pyridoxine.

Symoglobin (Vitamin B12) drug interactions

In an application of Symoglobin (Vitamin B12) with hormonal contraceptives for oral administration may decrease the concentration of cyanocobalamin in plasma.

In an application with anticonvulsant drugs decreased cyanocobalamin absorption from the gut.

In an Symoglobin (Vitamin B12) application with neomycin, aminosalicylic acid, colchicine, cimetidine, ranitidine, drugs potassium decreased cyanocobalamin absorption from the gut.

Cyanocobalamin may exacerbate allergic reactions caused by thiamine.

When parenteral application of chloramphenicol may decrease the hematopoietic effects of cyanocobalamin with anemia.

Pharmaceutical incompatibility

Contained in the molecule of cyanocobalamin cobalt ion contributes to the destruction of ascorbic acid, thiamine bromide, riboflavin in one solution.

Vitamin C:


Pharmacological action

Ascorbic acid is essential for the formation of intracellular collagen, is required to strengthen the structure of teeth, bones, and the capillary walls. Symoglobin (Vitamin C) participates in redox reactions, the metabolism of tyrosine, converting folic acid into folinic acid, metabolism of carbohydrates, the synthesis of lipids and proteins, iron metabolism, processes of cellular respiration. Reduces the need for vitamins B1, B2, A, E, folic acid, pantothenic acid, enhances the body's resistance to infections; enhances iron absorption, contributing to its sequestration in reduced form. Symoglobin (Vitamin C) has antioxidant properties.

With intravaginal application of ascorbic acid lowers the vaginal pH, inhibiting the growth of bacteria and helps to restore and maintain normal pH and vaginal flora (Lactobacillus acidophilus, Lactobacillus gasseri).

Pharmacokinetics

After oral administration ascorbic acid is completely absorbed from the gastrointestinal tract. Widely distributed in body tissues.

The concentration of ascorbic acid in blood plasma in normal amounts to approximately 10-20 mg / ml.

The concentration of ascorbic acid in white blood cells and platelets is higher than in erythrocytes and plasma. When deficient state of concentration in leucocytes is reduced later and more slowly and is regarded as the best criterion for evaluating the deficit than the concentration in plasma.

Plasma protein binding is about 25%.

Ascorbic acid is reversibly oxidized to form dehydroascorbic acid, is metabolized with the formation of ascorbate-2-sulphate which is inactive and oxalic acid which is excreted in the urine.

Ascorbic acid taken in excessive quantities is rapidly excreted unchanged in urine, it usually happens when exceeding a daily dose is 200 mg.

Why is Symoglobin prescribed?

For systemic use of Symoglobin (Vitamin C) Kimia Farma: prevention and treatment of hypo- and avitaminosis of Symoglobin (Vitamin C); providing increased need for Symoglobin (Vitamin C) during growth, pregnancy, lactation, with heavy loads, fatigue and during recovery after prolonged severe illness; in winter with an increased risk of infectious diseases.

For intravaginal use: chronic or recurrent vaginitis (bacterial vaginosis, nonspecific vaginitis) caused by the anaerobic flora (due to changes in pH of the vagina) in order to normalize disturbed vaginal microflora.

Dosage and administration

This medication administered orally, IM, IV, intravaginally.

For the prevention of deficiency conditions Symoglobin dose is 25-75 mg / day, for the treatment - 250 mg / day or more in divided doses.

For intravaginal used ascorbic acid drugs in appropriate dosage forms.

Symoglobin (Vitamin C) side effects, adverse reactions

CNS: headache, fatigue, insomnia.

Digestive system: stomach cramps, nausea and vomiting.

Allergic reaction: describes a few cases of skin reactions and manifestations of the respiratory system.

Urinary system: when used in high doses - hyperoxaluria and the formation of kidney stones of calcium oxalate.

Local reactions: with intravaginal application - a burning or itching in the vagina, increased mucous discharge, redness, swelling of the vulva. Other: sensation of heat.

Symoglobin contraindications

Increased sensitivity to ascorbic acid.

Using during pregnancy and breastfeeding

The minimum daily requirement of ascorbic acid in the II and III trimester of pregnancy is about 60 mg.

Ascorbic acid crosses the placental barrier. It should be borne in mind that the fetus can adapt to high doses of ascorbic acid, which takes a pregnant woman, and then a newborn baby may develop the ascorbic disease as the reaction of cancel. Therefore, during pregnancy should not to take ascorbic acid in high doses, except in cases where the expected benefit outweighs the potential risk.

The minimum daily requirement during lactation is 80 mg. Ascorbic acid is excreted in breast milk. A mother's diet that contains adequate amounts of ascorbic acid, is sufficient to prevent deficiency in an infant. It is unknown whether dangerous to the child's mother use of ascorbic acid in high doses. Theoretically it is possible. Therefore, it is recommended not to exceed the maximum daily nursing mother needs to ascorbic acid, except when the expected benefit outweighs the potential risk.

Special instructions

Symoglobin (Vitamin C) is used with caution in patients with hyperoxaluria, renal impairment, a history of instructions on urolithiasis. Because ascorbic acid increases iron absorption, its use in high doses can be dangerous in patients with hemochromatosis, thalassemia, polycythemia, leukemia, and sideroblastic anemia.

Patients with high content body iron should apply ascorbic acid in minimal doses.

Symoglobin (Vitamin C) is used with caution in patients with deficiency of glucose-6-phosphate dehydrogenase.

The use of ascorbic acid in high doses can cause exacerbation of sickle cell anemia.

Data on the diabetogenic action of ascorbic acid are contradictory. However, prolonged use of ascorbic acid should periodically monitor your blood glucose levels.

It is believed that the use of ascorbic acid in patients with rapidly proliferating and widely disseminated tumors may worsen during the process. It should therefore be used with caution in ascorbic acid in patients with advanced cancer.

Absorption of ascorbic acid decreased while use of fresh fruit or vegetable juices, alkaline drinking.

Symoglobin drug interactions

In an application with barbiturates, primidone increases the excretion of ascorbic acid in the urine.

With the simultaneous use of oral contraceptives reduces the concentration of ascorbic acid in blood plasma.

In an application of Symoglobin (Vitamin C) with iron preparations ascorbic acid, due to its regenerative properties, transforms ferric iron in the bivalent, which improves its absorption.

Ascorbic acid in high doses can decrease urine pH that while the application reduces the tubular reabsorption of amphetamine and tricyclic antidepressants.

With the simultaneous use of aspirin reduces the absorption of ascorbic acid by about a third.

Symoglobin (Vitamin C) in an application with warfarin may decrease effects of warfarin.

With the simultaneous application of ascorbic acid increases the excretion of iron in patients receiving deferoxamine. In the application of ascorbic acid at a dose of 500 mg / day possibly left ventricular dysfunction.

In an application with tetracycline is increased excretion of ascorbic acid in the urine.

There is a described case of reducing the concentration of fluphenazine in plasma in patients treated with ascorbic acid 500 mg 2 times / day.

May increase the concentration of ethinyl estradiol in the blood plasma in its simultaneous application in the oral contraceptives.

Symoglobin in case of emergency / overdose

Symptoms: long-term use of large doses (more than 1 g) - headache, increased CNS excitability, insomnia, nausea, vomiting, diarrhea, gastritis giperatsidnyh, ultseratsiya gastrointestinal mucosa, inhibition of the function insular apparatus of the pancreas (hyperglycemia, glycosuria), hyperoxaluria, nephrolithiasis (calcium oxalate), damage to the glomerular apparatus of the kidneys, moderate thamuria (when receiving a dose of 600 mg / day).

Decrease capillary permeability (possibly deteriorating trophic tissues, increased blood pressure, hypercoagulability, the development of microangiopathy).

When IV administration in high doses - the threat of termination of pregnancy (due to estrogenemia), hemolysis of red blood cells.

Vitamin E:


A generic descriptor for all tocopherols and tocotrienols that exhibit alpha-tocopherol activity. By virtue of the phenolic hydrogen on the 2H-1-benzopyran-6-ol nucleus, these compounds exhibit varying degree of antioxidant activity, depending on the site and number of methyl groups and the type of isoprenoids.

Indication: Symoglobin (Vitamin E), known for its antioxidant activities, is protective against cardiovascular disease and some forms of cancer and has also demonstrated immune-enhancing effects. It may be of limited benefit in some with asthma and rheumatoid arthritis. It may be helpful in some neurological diseases including Alzheimer's, some eye disorders including cataracts, and diabetes and premenstrual syndrome. It may also help protect skin from ultraviolet irradiation although claims that it reverses skin aging, enhances male fertility and exercise performance are poorly supported. It may help relieve some muscle cramps.

Symoglobin (Vitamin E) has antioxidant activity. It may also have anti-atherogenic, antithrombotic, anticoagulant, neuroprotective, antiviral, immunomodulatory, cell membrane-stabilizing and antiproliferative actions. Symoglobin (Vitamin E) is a collective term used to describe eight separate forms, the best-known form being alpha-tocopherol. Symoglobin (Vitamin E) is a fat-soluble vitamin and is an important antioxidant. It acts to protect cells against the effects of free radicals, which are potentially damaging by-products of the body's metabolism. Symoglobin (Vitamin E) is often used in skin creams and lotions because it is believed to play a role in encouraging skin healing and reducing scarring after injuries such as burns. There are three specific situations when a Symoglobin (Vitamin E) deficiency is likely to occur. It is seen in persons who cannot absorb dietary fat, has been found in premature, very low birth weight infants (birth weights less than 1500 grams, or 3½ pounds), and is seen in individuals with rare disorders of fat metabolism. A Symoglobin (Vitamin E) deficiency is usually characterized by neurological problems due to poor nerve conduction. Symptoms may include infertility, neuromuscular impairment, menstrual problems, miscarriage and uterine degradation. Preliminary research has led to a widely held belief that Symoglobin (Vitamin E) may help prevent or delay coronary heart disease. Antioxidants such as Symoglobin (Vitamin E) help protect against the damaging effects of free radicals, which may contribute to the development of chronic diseases such as cancer. It also protects other fat-soluble vitamins (A and B group vitamins) from destruction by oxygen. Low levels of Symoglobin (Vitamin E) have been linked to increased incidence of breast and colon cancer.

Zinc Sulfate:


INDICATIONS AND USAGE

Symoglobin (Zinc Sulfate) 1 mg/mL (Zinc Chloride Injection, USP) is indicated for use as a supplement to intravenous solutions given for TPN. Administration helps to maintain Symoglobin (Zinc Sulfate) serum levels and to prevent depletion of endogenous stores, and subsequent deficiency symptoms.

CONTRAINDICATIONS

None known.

WARNINGS

Direct intramuscular or intravenous injection of Symoglobin (Zinc Sulfate) 1 mg/mL (Zinc Chloride Injection, USP) is contraindicated as the acidic pH of the solution (2) may cause considerable tissue irritation.

Severe kidney disease may make it necessary to reduce or omit chromium and Symoglobin (Zinc Sulfate) doses because these elements are primarily eliminated in the urine.

WARNING: This product contains aluminum that may be toxic. Aluminum may reach toxic levels with prolonged parenteral administration if kidney function is impaired. Premature neonates are particularly at risk because their kidneys are immature, and they require large amounts of calcium and phosphate solutions, which contain aluminum.

Research indicates that patients with impaired kidney function, including premature neonates, who receive parenteral levels of aluminum at greater than 4 to 5 mcg/kg/day accumulate aluminum at levels associated with central nervous system and bone toxicity. Tissue loading may occur at even lower rates of administration.

PRECAUTIONS

General

Do not use unless the solution is clear and the seal is intact.

Zinc 1 mg/mL should only be used in conjunction with a pharmacy directed admixture program using aseptic technique in a laminar flow environment; it should be used promptly and in a single operation without any repeated penetrations. Solution contains no preservatives; discard unused portion immediately after admixture procedure is completed.

Zinc should not be given undiluted by direct injection into a peripheral vein because of the likelihood of infusion phlebitis and the potential for increased excretory loss of Symoglobin (Zinc Sulfate) from a bolus injection. Administration of Symoglobin (Zinc Sulfate) in the absence of copper may cause a decrease in serum copper levels.

Laboratory Tests

Periodic determinations of serum copper as well as Symoglobin (Zinc Sulfate) are suggested as a guideline for subsequent Symoglobin (Zinc Sulfate) administration.

Carcinogenesis, Mutagenesis, and Impairment of Fertility

Long-term animal studies to evaluate the carcinogenic potential of Symoglobin 1 mg/mL (Zinc Chloride Injection, USP) have not been performed, nor have studies been done to assess mutagenesis or impairment of fertility.

Nursing Mothers

It is not known whether this drug is excreted in human milk. Because many drugs are excreted in human milk, caution should be exercised when Symoglobin (Zinc Sulfate) 1 mg/mL (Zinc Chloride Injection, USP) is administered to a nursing woman.

Pediatric Use

Pregnancy Category C. Animal reproduction studies have not been conducted with Symoglobin chloride. It is also not known whether Symoglobin (Zinc Sulfate) chloride can cause fetal harm when administered to a pregnant woman or can affect reproduction capacity. Symoglobin (Zinc Sulfate) chloride should be given to a pregnant woman only if clearly needed.

Geriatric Use

An evaluation of current literature revealed no clinical experience identifying differences in response between elderly and younger patients. In general, dose selection for an elderly patient should be cautious, usually starting at the low end of the dosing range, reflecting the greater frequency of decreased hepatic, renal, or cardiac function, and of concomitant disease or other drug therapy.

ADVERSE REACTIONS

None known.

DRUG ABUSE AND DEPENDENCE

None known.

OVERDOSAGE

Single intravenous doses of 1 to 2 mg zinc/kg body weight have been given to adult leukemic patients without toxic manifestations. However, acute toxicity was reported in an adult when 10 mg Symoglobin (Zinc Sulfate) was infused over a period of one hour on each of four consecutive days. Profuse sweating, decreased level of consciousness, blurred vision, tachycardia (140/min), and marked hypothermia (94.2° F) on the fourth day were accompanied by a serum Symoglobin (Zinc Sulfate) concentration of 207 mcg/dl. Symptoms abated within three hours.

Hyperamylasemia may be a sign of impending Symoglobin (Zinc Sulfate) overdosage; patients receiving an inadvertent overdose (25 mg zinc/liter of TPN solution, equivalent to 50 to 70 mg zinc/day) developed hyperamylasemia (557 to 1850 Klein units; normal: 130 to 310).

Death resulted from an overdosage in which 1683 mg Symoglobin (Zinc Sulfate) was delivered intravenously over the course of 60 hours to a 72 year old patient.

Symptoms of Symoglobin (Zinc Sulfate) toxicity included hypotension (80/40 mm Hg), pulmonary edema, diarrhea, vomiting, jaundice, and oliguria, with a serum Symoglobin (Zinc Sulfate) level of 4184 mcg/dl.

Calcium supplements may confer a protective effect against Symoglobin (Zinc Sulfate) toxicity.

DOSAGE AND ADMINISTRATION

Symoglobin (Zinc Sulfate) 1 mg/mL (Zinc Chloride Injection, USP) contains 1 mg zinc/mL and is administered intravenously only after dilution. The additive should be diluted prior to administration in a volume of fluid not less than 100 mL. For the metabolically stable adult receiving TPN, the suggested intravenous dosage is 2.5 to 4 mg zinc/day (2.5 to 4 mL/day). An additional 2 mg zinc/day (2 mL/day) is suggested for acute catabolic states. For the stable adult with fluid loss from the small bowel, an additional 12.2 mg zinc/liter of small bowel fluid lost (12.2 mL/liter of small bowel fluid lost), or an additional 17.1 mg zinc/kg of stool or ileostomy output (17.1 mL/kg of stool or ileostomy output) is recommended. Frequent monitoring of Symoglobin (Zinc Sulfate) blood levels is suggested for patients receiving more than the usual maintenance dosage level of Symoglobin (Zinc Sulfate).

For full term infants and children up to 5 years of age, 100 mcg zinc/kg/day (0.1 mL/kg/day) is recommended. For premature infants (birth weight less than 1500 g) up to 3 kg in body weight, 300 mcg zinc/kg/day (0.3 mL/kg/day) is suggested.

Parenteral drug products should be inspected visually for particulate matter and discoloration prior to administration, whenever solution and container permit. See PRECAUTIONS.

HOW SUPPLIED

Symoglobin (Zinc Sulfate) 1 mg/mL (Zinc Chloride Injection, USP) is supplied in 10 mL Plastic Vials (List No. 4090).

Store at 20 to 25°C (68 to 77°F).

Revised: October, 2004


© Hospira 2004 EN-0488 Printed in USA

HOSPIRA, INC., LAKE FOREST, IL 60045 USA

10 mL Vial

Symoglobin (Zinc Sulfate)

1 mg/mL

Symoglobin (Zinc Sulfate) Chloride Inj., USP

Rx only

FOR I.V. USE ONLY AFTER DILUTION.

HOSPIRA, INC., LAKE FOREST, IL 60045 USA

Symoglobin pharmaceutical active ingredients containing related brand and generic drugs:

Active ingredient is the part of the drug or medicine which is biologically active. This portion of the drug is responsible for the main action of the drug which is intended to cure or reduce the symptom or disease. The other portions of the drug which are inactive are called excipients; there role is to act as vehicle or binder. In contrast to active ingredient, the inactive ingredient's role is not significant in the cure or treatment of the disease. There can be one or more active ingredients in a drug.


Symoglobin available forms, composition, doses:

Form of the medicine is the form in which the medicine is marketed in the market, for example, a medicine X can be in the form of capsule or the form of chewable tablet or the form of tablet. Sometimes same medicine can be available as injection form. Each medicine cannot be in all forms but can be marketed in 1, 2, or 3 forms which the pharmaceutical company decided based on various background research results.
Composition is the list of ingredients which combinedly form a medicine. Both active ingredients and inactive ingredients form the composition. The active ingredient gives the desired therapeutic effect whereas the inactive ingredient helps in making the medicine stable.
Doses are various strengths of the medicine like 10mg, 20mg, 30mg and so on. Each medicine comes in various doses which is decided by the manufacturer, that is, pharmaceutical company. The dose is decided on the severity of the symptom or disease.


Symoglobin destination | category:

Destination is defined as the organism to which the drug or medicine is targeted. For most of the drugs what we discuss, human is the drug destination.
Drug category can be defined as major classification of the drug. For example, an antihistaminic or an antipyretic or anti anginal or pain killer, anti-inflammatory or so.


Symoglobin Anatomical Therapeutic Chemical codes:

A medicine is classified depending on the organ or system it acts [Anatomical], based on what result it gives on what disease, symptom [Therapeutical], based on chemical composition [Chemical]. It is called as ATC code. The code is based on Active ingredients of the medicine. A medicine can have different codes as sometimes it acts on different organs for different indications. Same way, different brands with same active ingredients and same indications can have same ATC code.


Symoglobin pharmaceutical companies:

Pharmaceutical companies are drug manufacturing companies that help in complete development of the drug from the background research to formation, clinical trials, release of the drug into the market and marketing of the drug.
Researchers are the persons who are responsible for the scientific research and is responsible for all the background clinical trials that resulted in the development of the drug.


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References

  1. Dailymed."FOLIC ACID INJECTION, SOLUTION [FRESENIUS KABI USA, LLC]". https://dailymed.nlm.nih.gov/dailym... (accessed August 28, 2018).
  2. Dailymed."ZINC SULFATE TABLET [NATIONWIDE LABORATORIES, LLC]". https://dailymed.nlm.nih.gov/dailym... (accessed August 28, 2018).
  3. Dailymed."VITAL E - 500 (VITAMIN E) INJECTION, EMULSION [STUART PRODUCTS, INC.]". https://dailymed.nlm.nih.gov/dailym... (accessed August 28, 2018).

Frequently asked Questions

Can i drive or operate heavy machine after consuming Symoglobin?

Depending on the reaction of the Symoglobin after taken, if you are feeling dizziness, drowsiness or any weakness as a reaction on your body, Then consider Symoglobin not safe to drive or operate heavy machine after consumption. Meaning that, do not drive or operate heavy duty machines after taking the capsule if the capsule has a strange reaction on your body like dizziness, drowsiness. As prescribed by a pharmacist, it is dangerous to take alcohol while taking medicines as it exposed patients to drowsiness and health risk. Please take note of such effect most especially when taking Primosa capsule. It's advisable to consult your doctor on time for a proper recommendation and medical consultations.

Is Symoglobin addictive or habit forming?

Medicines are not designed with the mind of creating an addiction or abuse on the health of the users. Addictive Medicine is categorically called Controlled substances by the government. For instance, Schedule H or X in India and schedule II-V in the US are controlled substances.

Please consult the medicine instruction manual on how to use and ensure it is not a controlled substance.In conclusion, self medication is a killer to your health. Consult your doctor for a proper prescription, recommendation, and guidiance.

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Review

sdrugs.com conducted a study on Symoglobin, and the result of the survey is set out below. It is noteworthy that the product of the survey is based on the perception and impressions of the visitors of the website as well as the views of Symoglobin consumers. We, as a result of this, advice that you do not base your therapeutic or medical decisions on this result, but rather consult your certified medical experts for their recommendations.

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The information was verified by Dr. Rachana Salvi, MD Pharmacology

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