4XLA

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4XLA uses

4XLA consists of Glycerol, Lactic Acid, Sodium Chlorite.

Glycerol:


Indications and Usage (1) 04/2017
Dosage and Administration (2.1) 04/2017
Dosage and Administration (2.2) 04/2017

4XLA (Glycerol) is indicated for use as a nitrogen-binding agent for chronic management of patients 2 months of age and older with urea cycle disorders (UCDs) who cannot be managed by dietary protein restriction and/or amino acid supplementation alone. 4XLA (Glycerol) must be used with dietary protein restriction and, in some cases, dietary supplements (e.g., essential amino acids, arginine, citrulline, protein-free calorie supplements).

Limitations of Use:

  • 4XLA (Glycerol) is not indicated for the treatment of acute hyperammonemia in patients with UCDs because more rapidly acting interventions are essential to reduce plasma ammonia levels.
  • The safety and efficacy of 4XLA (Glycerol) for the treatment of N-acetylglutamate synthase (NAGS) deficiency has not been established.

4XLA (Glycerol) is a nitrogen-binding agent indicated for chronic management of patients 2 months of age and older with urea cycle disorders (UCDs) who cannot be managed by dietary protein restriction and/or amino acid supplementation alone. 4XLA (Glycerol) must be used with dietary protein restriction and, in some cases, dietary supplements. (1)

Limitations of Use:

  • 4XLA (Glycerol) is not indicated for treatment of acute hyperammonemia in patients with UCDs. (1)
  • Safety and efficacy for treatment of N-acetylglutamate synthase (NAGS) deficiency has not been established. (1)
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2 DOSAGE AND ADMINISTRATION

  • 4XLA should be prescribed by a physician experienced in management of UCDs. For administration and preparation, see full prescribing information. (2.1, 2.6)

Switching From Sodium Phenylbutyrate Tablets or Powder to 4XLA (Glycerol):

  • Patients should receive the dosage of 4XLA (Glycerol) that contains the same amount of phenylbutyric acid, see full prescribing information for conversion. (2.2)

Initial Dosage in Phenylbutyrate-Naïve Patients (2.3):

  • Recommended dosage range is 4.5 to 11.2 mL/m2/day (5 to 12.4 g/m2/day).
  • For patients with some residual enzyme activity not adequately controlled with dietary restriction, the recommended starting dose is 4.5 mL/m2/day.
  • Take into account patient's estimated urea synthetic capacity, dietary protein intake, and diet adherence.

Dosage Adjustment and Monitoring:

  • Follow plasma ammonia levels to determine the need for dosage titration. (2.4)

Dosage Modifications in Patients with Hepatic Impairment:

  • Start dosage at lower end of range. (2.5, 8.6)

2.1 Important Administration Instructions

4XLA (Glycerol) should be prescribed by a physician experienced in the management of UCDs.

  • Instruct patients to take 4XLA (Glycerol) with food or formula and to administer directly into the mouth via oral syringe or dosing cup.
  • For patients who cannot swallow, see the instructions on administration of 4XLA (Glycerol) by nasogastric tube or gastrostomy tube .
  • For patients who require a volume of less than 1 mL per dose via nasogastric or gastrostomy tube, the delivered dose may be less than anticipated. Closely monitor these patients using ammonia levels .
  • The recommended dosages for patients switching from sodium phenylbutyrate to 4XLA (Glycerol) and patients naïve to phenylbutyric acid are different . For both subpopulations:
    • Patients 2 years of age and older: Give 4XLA (Glycerol) in 3 equally divided dosages, each rounded up to the nearest 0.5 mL
    • Patients 2 months of age to less than 2 years: Give 4XLA (Glycerol) in 3 or more equally divided dosages, each rounded up to the nearest 0.1 mL.
    • The maximum total daily dosage is 17.5 mL (19 g).
    • 4XLA (Glycerol) must be used with dietary protein restriction and, in some cases, dietary supplements (e.g., essential amino acids, arginine, citrulline, protein-free calorie supplements).

2.2 Switching From Sodium Phenylbutyrate to 4XLA

Patients switching from sodium phenylbutyrate to 4XLA (Glycerol) should receive the dosage of 4XLA (Glycerol) that contains the same amount of phenylbutyric acid. The conversion is as follows:

Total daily dosage of 4XLA (Glycerol) (mL) = total daily dosage of sodium phenylbutyrate tablets (g) × 0.86

Total daily dosage of 4XLA (Glycerol) (mL) = total daily dosage of sodium phenylbutyrate powder (g) × 0.81

2.3 Initial Dosage in Phenylbutyrate-Naïve Patients

The recommended dosage range, based upon body surface area, in patients naïve to phenylbutyrate is 4.5 to 11.2 mL/m2/day (5 to 12.4 g/m2/day). For patients with some residual enzyme activity who are not adequately controlled with protein restriction, the recommended starting dosage is 4.5 mL/m2/day.

In determining the starting dosage of 4XLA (Glycerol) in treatment-naïve patients, consider the patient's residual urea synthetic capacity, dietary protein requirements, and diet adherence. Dietary protein is approximately 16% nitrogen by weight. Given that approximately 47% of dietary nitrogen is excreted as waste and approximately 70% of an administered PBA dose will be converted to urinary phenylacetylglutamine (U-PAGN), an initial estimated 4XLA (Glycerol) dose for a 24-hour period is 0.6 mL 4XLA (Glycerol) per gram of dietary protein ingested per 24-hour period. The total daily dosage should not exceed 17.5 mL.

2.4 Dosage Adjustment and Monitoring

During treatment with 4XLA (Glycerol), patients should be followed clinically and with plasma ammonia levels to determine the need for dosage titration. Closely monitor ammonia levels after changing the dosage of 4XLA (Glycerol).

Normal Ammonia Levels

If patients experience symptoms of vomiting, nausea, headache, somnolence or confusion in the absence of high ammonia levels or other intercurrent illnesses, reduce the 4XLA (Glycerol) dosage and monitor patients clinically. If available, obtain measurements of plasma phenylacetate (PAA) concentrations and the ratio of plasma PAA to PAGN to guide dosing. A high PAA to PAGN ratio may indicate the saturation of the conjugation reaction to form PAGN. The PAA to PAGN ratio has been observed to be generally less than 1 in patients with UCDs without significant PAA accumulation .

Elevated Ammonia Levels

When plasma ammonia is elevated, increase the 4XLA (Glycerol) dosage to reduce the fasting ammonia level to less than half the upper limit of normal (ULN) in patients 6 years and older. In infants and pediatric patients (generally below 6 years of age), where obtaining fasting ammonia is problematic due to frequent feedings, adjust the dosage to keep the first ammonia of the morning below the ULN.

Urinary Phenylacetylglutamine: If available, U-PAGN measurements may be used to help guide 4XLA (Glycerol) dosage adjustment. Each gram of U-PAGN excreted over 24 hours covers waste nitrogen generated from 1.4 grams of dietary protein. If U-PAGN excretion is insufficient to cover daily dietary protein intake and the fasting ammonia is greater than half the ULN, the 4XLA (Glycerol) dosage should be adjusted upward. The amount of dosage adjustment should factor in the amount of dietary protein that has not been covered, as indicated by the 24-hour U-PAGN level and the estimated 4XLA (Glycerol) dose needed per gram of dietary protein ingested and the maximum total daily dosage (i.e., 17.5 mL).

Consider a patient's use of concomitant medications, such as probenecid, when making dosage adjustment decisions based on U-PAGN. Probenecid may result in a decrease of the urinary excretion of PAGN .

Plasma Phenylacetate and Phenylacetylglutamine: If available, the ratio of PAA to PAGN in plasma may provide additional information to assist in dosage adjustment decisions. In patients with a high PAA to PAGN ratio, a further increase in 4XLA (Glycerol) dosage may not increase PAGN formation, even if plasma PAA concentrations are increased, due to saturation of the conjugation reaction .

2.5 Dosage Modifications in Patients with Hepatic Impairment

For patients with moderate to severe hepatic impairment, the recommended starting dosage is at the lower end of the recommended dosing range and kept at the lowest dose necessary to control the patient's ammonia levels .

2.6 Preparation for Nasogastric Tube or Gastrostomy Tube Administration

It is recommended that all patients who can swallow take 4XLA (Glycerol) orally, even those with nasogastric and/or gastrostomy tubes. However, for patients who cannot swallow, a nasogastric tube or gastrostomy tube may be used to administer 4XLA (Glycerol) as follows:

  • Utilize an oral syringe to withdraw the prescribed dosage of 4XLA (Glycerol) from the bottle.
  • Place the tip of the syringe into the nasogastric/gastrostomy tube.
  • Utilizing the plunger of the syringe, administer 4XLA (Glycerol) into the tube.
  • Flush once with 10 mL of water or formula and allow the flush to drain.
  • If needed, flush a second time with an additional 10 mL of water or formula to clear the tube.

For patients who require a volume of less than 1 mL per dose via nasogastric or gastrostomy tube, the delivered dosage may be less than anticipated due to adherence of 4XLA (Glycerol) to the plastic tubing. Therefore, these patients should be closely monitored using ammonia levels following initiation of 4XLA (Glycerol) dosing or dosage adjustments.

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3 DOSAGE FORMS AND STRENGTHS

Oral liquid: colorless to pale yellow, 1.1 g/mL of 4XLA (Glycerol) phenylbutyrate (delivers 1.02 g/mL of phenylbutyrate).

Oral liquid: 1.1 g/mL. (3)

4 CONTRAINDICATIONS

4XLA (Glycerol) is contraindicated in patients

  • Less than 2 months of age. Pediatric patients less than 2 months of age may have immature pancreatic exocrine function, which could impair hydrolysis of 4XLA (Glycerol), leading to impaired absorption of phenylbutyrate and hyperammonemia .
  • With known hypersensitivity to phenylbutyrate. Signs of hypersensitivity include wheezing, dyspnea, coughing, hypotension, flushing, nausea, and rash.
  • Patients less than 2 months of age. (4)
  • Known hypersensitivity to phenylbutyrate. (4)

5 WARNINGS AND PRECAUTIONS

  • Neurotoxicity: Phenylacetate, the active moiety of 4XLA (Glycerol), may be toxic; reduce dosage for symptoms of neurotoxicity. (5.1)
  • Reduced Phenylbutyrate Absorption in Pancreatic Insufficiency or Intestinal Malabsorption: Monitor ammonia levels closely. (5.2)

5.1 Neurotoxicity

The major metabolite of 4XLA (Glycerol), PAA, is associated with neurotoxicity. Signs and symptoms of PAA neurotoxicity, including somnolence, fatigue, lightheadedness, headache, dysgeusia, hypoacusis, disorientation, impaired memory, and exacerbation of preexisting neuropathy, were observed at plasma PAA concentrations of 500 micrograms/mL in a study of adult cancer patients who were administered PAA intravenously. In this study, adverse reactions were reversible.

In healthy subjects, after administration of 4 mL and 6 mL 4XLA (Glycerol) 3 times daily for 3 days, a dose-dependent increase in all-grade nervous system adverse reactions was observed, even at exposure levels of PAA less than 100 micrograms/mL.

In clinical trials in patients with UCDs who had been on sodium phenylbutyrate prior to administration of 4XLA (Glycerol), peak PAA concentrations after dosing with 4XLA (Glycerol) ranged from 1.6 to 178 micrograms/mL (mean: 39 micrograms/mL) in adult patients, from 1 to 410 micrograms/mL (mean: 70 micrograms/mL; median: 50 micrograms/mL) in pediatric patients ages 2 years and older, and from 1 to 1215 micrograms/mL (mean: 142 micrograms/mL; median: 35 micrograms/mL) in pediatric patients ages 2 months to less than 2 years. Some patients with UCDs experienced headache, fatigue, symptoms of peripheral neuropathy, seizures, tremor and/or dizziness. No correlation between PAA levels and neurotoxicity symptoms was identified but PAA levels were generally not measured at the time of neurotoxicity symptoms.

If symptoms of vomiting, nausea, headache, somnolence or confusion, are present in the absence of high ammonia or other intercurrent illnesses, reduce the 4XLA (Glycerol) dosage .

5.2 Reduced Phenylbutyrate Absorption in Pancreatic Insufficiency or Intestinal Malabsorption

Exocrine pancreatic enzymes hydrolyze 4XLA (Glycerol) in the small intestine, separating the active moiety, phenylbutyrate, from 4XLA (Glycerol). This process allows phenylbutyrate to be absorbed into the circulation. Low or absent pancreatic enzymes or intestinal disease resulting in fat malabsorption may result in reduced or absent digestion of 4XLA (Glycerol) and/or absorption of phenylbutyrate and reduced control of plasma ammonia. Monitor ammonia levels closely in patients with pancreatic insufficiency or intestinal malabsorption.

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6 ADVERSE REACTIONS

Most common adverse reactions in adults are: diarrhea, flatulence, and headache. (6.1)

To report SUSPECTED ADVERSE REACTIONS, contact Horizon Therapeutics at 1-855-823-7878 or FDA at 1-800-FDA-1088 or www.fda.gov/medwatch.

6.1 Clinical Trials 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 clinical practice.

Assessment of adverse reactions was based on exposure of 45 adult patients (31 female and 14 male) with UCD subtype deficiencies of ornithine transcarbamylase (OTC, n=40), carbamyl phosphate synthetase (CPS, n=2), and argininosuccinate synthetase (ASS, n=1) in a randomized, double-blind, active-controlled (RAVICTI vs sodium phenylbutyrate), crossover, 4-week study (Study 1) that enrolled patients 18 years of age and older . One of the 45 patients received only sodium phenylbutyrate prior to withdrawing on day 1 of the study due to an adverse reaction.

The most common adverse reactions (occurring in at least 10% of patients) reported during short-term treatment with 4XLA (Glycerol) were diarrhea, flatulence, and headache. Table 1 summarizes adverse reactions occurring in 2 or more patients treated with 4XLA (Glycerol) or sodium phenylbutyrate (incidence of at least 4% in either treatment arm).

Number (%) of Patients in Study 1
Sodium Phenylbutyrate

(N = 45)

4XLA (Glycerol)

(N = 44)

Diarrhea 3 (7) 7 (16)
Headache 4 (9) 6 (14)
Flatulence 1 (2) 6 (14)
Abdominal pain 2 (4) 3 (7)
Vomiting 2 (4) 3 (7)
Decreased appetite 2 (4) 3 (7)
Fatigue 1 (2) 3 (7)
Dyspepsia 3 (7) 2 (5)
Nausea 3 (7) 1 (2)
Dizziness 4 (9) 0
Abdominal discomfort 3 (7) 0

Other Adverse Reactions

4XLA (Glycerol) has been evaluated in 77 patients with UCDs (51 adult and 26 pediatric patients ages 2 years to 17 years) in 2 open-label long-term studies, in which 69 patients completed 12 months of treatment with 4XLA (Glycerol) (median exposure = 51 weeks). During these studies there were no deaths.

Adverse reactions occurring in at least 10% of adult patients were nausea, vomiting, diarrhea, decreased appetite, dizziness, headache, and fatigue.

Adverse reactions occurring in at least 10% of pediatric patients ages 2 years to 17 years were upper abdominal pain, rash, nausea, vomiting, diarrhea, decreased appetite, and headache.

4XLA (Glycerol) has also been evaluated in 17 patients with UCDs ages 2 months to less than 2 years in 3 open-label studies. The median exposure was 6 months (range 0.2 to 18 months). Adverse reactions occurring in at least 10% of pediatric patients aged 2 months to less than 2 years were neutropenia, vomiting, diarrhea, pyrexia, hypophagia, cough, nasal congestion, rhinorrhea, rash and papule.

6.2 Postmarketing Experience

The following adverse reactions have been identified during postapproval use of 4XLA (Glycerol). 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:

  • Abnormal body odor, including from skin, hair and urine
  • Retching and gagging
  • Dysgeusia or burning sensation in mouth
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7 DRUG INTERACTIONS

  • Corticosteroids, valproic acid, or haloperidol: May increase plasma ammonia level; monitor ammonia levels closely.
  • Probenecid: May affect renal excretion of metabolites of 4XLA (Glycerol), including phenylacetylglutamine (PAGN) and PAA. (7.2)
  • CYP3A4 Substrates with narrow therapeutic index (e.g., alfentanil, quinidine, cyclosporine): 4XLA (Glycerol) may decrease exposure; monitor for decreased efficacy of the narrow therapeutic index drug. (7.3)
  • Midazolam: Decreased exposure; monitor for suboptimal effect of midazolam. (7.3)

7.1 Potential for Other Drugs to Affect Ammonia

Corticosteroids

Use of corticosteroids may cause the breakdown of body protein and increase plasma ammonia levels. Monitor ammonia levels closely when corticosteroids and 4XLA (Glycerol) are used concomitantly.

Valproic Acid and Haloperidol

Hyperammonemia may be induced by haloperidol and by valproic acid. Monitor ammonia levels closely when use of valproic acid or haloperidol is necessary in patients with UCDs.

7.2 Potential for Other Drugs to Affect 4XLA

Probenecid

Probenecid may inhibit the renal excretion of metabolites of 4XLA (Glycerol) including PAGN and PAA.

7.3 Potential for 4XLA to Affect Other Drugs

Drugs with narrow therapeutic index that are substrates of CYP3A4

4XLA (Glycerol) is a weak inducer of CYP3A4 in humans. Concomitant use of 4XLA (Glycerol) may decrease the systemic exposure to drugs that are substrates of CYP3A4. Monitor for decreased efficacy of drugs with narrow therapeutic index (e.g., alfentanil, quinidine, cyclosporine) .

Midazolam

Concomitant use of 4XLA (Glycerol) decreased the systemic exposure of midazolam. Monitor for suboptimal effect of midazolam in patients who are being treated with 4XLA (Glycerol).

8 USE IN SPECIFIC POPULATIONS

Lactation: Breastfeeding is not recommended.

8.1 Pregnancy

Pregnancy Exposure Registry

There is a pregnancy exposure registry that monitors pregnancy outcomes in women exposed to 4XLA (Glycerol) during pregnancy. Healthcare providers are encouraged to report any prenatal exposure to 4XLA (Glycerol) by calling the Pregnancy Registry at 1-855-823-2595 or visiting www.ucdregistry.com.

Risk Summary

Limited available data with 4XLA (Glycerol) use in pregnant women are insufficient to inform a drug-associated risk of major birth defects and miscarriage. In an animal reproduction study, administration of oral 4XLA (Glycerol) phenylbutyrate to pregnant rabbits during organogenesis at doses up to 2.7–times the dose of 6.87 mL/m2/day in adult patients resulted in maternal toxicity, but had no effects on embryo-fetal development. In addition, there were no adverse developmental effects with administration of oral 4XLA (Glycerol) phenylbutyrate to pregnant rats during organogenesis at 1.9 times the dose of 6.87 mL/m2/day in adult patients; however, maternal toxicity, reduced fetal weights, and variations in skeletal development were observed in pregnant rats administered oral 4XLA (Glycerol) phenylbutyrate during organogenesis at doses greater than or equal to 5.7 times the dose of 6.87 mL/m2/day in adult patients [see Data].

The estimated background risk of major birth defects and miscarriage for the indicated population is unknown. All pregnancies have a background risk of birth defect, loss or other adverse outcomes. In the U.S. general population, the estimated background risk of major birth defects and miscarriage in clinically recognized pregnancies is 2 to 4% and 15 to 20%, respectively.

Data

Animal Data

Oral administration of 4XLA (Glycerol) phenylbutyrate during the period of organogenesis up to 350 mg/kg/day in rabbits produced maternal toxicity, but no effects on embryo-fetal development. The dose of 350 mg/kg/day in rabbits is approximately 2.7 times the dose of 6.87 mL/m2/day in adult patients, based on combined area under the plasma concentration-time curve [AUCs] for PBA and PAA. In rats, at an oral dose of 300 mg/kg/day of 4XLA (Glycerol) phenylbutyrate (1.9 times the dose of 6.87 mL/m2/day in adult patients, based on combined AUCs for PBA and PAA) during the period of organogenesis, no effects on embryo-fetal development were observed. Doses of 650 mg/kg/day or greater produced maternal toxicity and adverse effects on embryo-fetal development including reduced fetal weights and cervical ribs at the 7th cervical vertebra. The dose of 650 mg/kg/day in rats is approximately 5.7 times the dose of 6.87 mL/m2/day in adult patients, based on combined AUCs for PBA and PAA. No developmental abnormalities, effects on growth, or effects on learning and memory were observed through maturation of offspring following oral administration in pregnant rats with up to 900 mg/kg/day of 4XLA (Glycerol) phenylbutyrate (8.5 times the dose of 6.87 mL/m2/day in adult patients, based on combined AUCs for PBA and PAA) during organogenesis and lactation.

8.2 Lactation

Risk Summary

There are no data on the presence of 4XLA in human milk, the effects on the breastfed infant, or the effects on milk production. Because of the potential for serious adverse reactions, including neurotoxicity and tumorigenicity in a breastfed infant, advise patients that breastfeeding is not recommended during treatment with 4XLA (Glycerol).

8.4 Pediatric Use

Safety and efficacy of 4XLA (Glycerol) have been established in pediatric patients 2 months of age and older with UCDs.

4XLA (Glycerol) is contraindicated in pediatric patients less than 2 months of age .

Patients 2 Years to Less Than 18 Years of Age

The safety and efficacy of 4XLA (Glycerol) in patients 2 years to less than 18 years of age were established in 2 open-label, sodium phenylbutyrate to 4XLA (Glycerol), fixed-sequence, switchover clinical studies .

Patients 2 Months to Less Than 2 Years of Age

The safety and efficacy of 4XLA (Glycerol) in patients with UCDs, 2 months to less than 2 years of age were established in 3 open-label studies. Pharmacokinetics and pharmacodynamics (plasma ammonia), and safety were studied in 17 patients between 2 months and less than 2 years of age .

Patients Less Than 2 Months of Age

4XLA (Glycerol) is contraindicated in patients less than 2 months of age . Pediatric patients less than 2 months of age may have immature pancreatic exocrine function, which could impair hydrolysis of 4XLA (Glycerol). Pancreatic lipases may be necessary for intestinal hydrolysis of 4XLA (Glycerol), allowing release of phenylbutyrate and subsequent formation of PAA, the active moiety. It is not known whether pancreatic and extrapancreatic lipases are sufficient for hydrolysis of 4XLA (Glycerol). If there is inadequate intestinal hydrolysis of 4XLA (Glycerol), impaired absorption of phenylbutyrate and hyperammonemia could occur.

Juvenile Animal Toxicity Data

In a juvenile rat study with daily oral dosing performed on postpartum day 2 through mating and pregnancy after maturation, terminal body weight was dose-dependently reduced by up to 16% in males and 12% in females at 900 mg/kg/day or higher (3 times the dose of 6.87 mL/m2/day in adult patients, based on combined AUCs for PBA and PAA). Learning, memory, and motor activity endpoints were not affected. However, fertility (number of pregnant rats) was decreased by up to 25% at 650 mg/kg/day or higher (2.6 times the dose of 6.87 mL/m2/day in adult patients, based on combined AUCs for PBA and PAA).

8.5 Geriatric Use

Clinical studies of 4XLA did not include sufficient numbers of subjects 65 years of age and older to determine whether they respond differently than younger subjects. Other reported clinical experience has not identified differences in responses between the 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.

8.6 Renal Impairment

The efficacy and safety of 4XLA (Glycerol) in patients with renal impairment are unknown. Monitor ammonia levels closely when starting patients with impaired renal function on 4XLA (Glycerol).

8.7 Hepatic Impairment

No studies were conducted in patients with UCDs and hepatic impairment. Because conversion of PAA to PAGN occurs in the liver, patients with hepatic impairment may have reduced conversion capability and higher plasma PAA and PAA to PAGN ratio . Therefore, dosage for patients with moderate to severe hepatic impairment should be started at the lower end of the recommended dosing range and should be kept on the lowest dose necessary to control their ammonia levels .

10 OVERDOSAGE

While there is no experience with overdosage in human clinical trials, PAA, a toxic metabolite of 4XLA (Glycerol), can accumulate in patients who receive an overdose .

If over-exposure occurs, call your Poison Control Center at 1-800-222-1222 for current information on the management of poisoning or overdosage.

11 DESCRIPTION

4XLA (Glycerol) (glycerol phenylbutyrate) is a clear, colorless to pale yellow oral liquid. It is insoluble in water and most organic solvents, and it is soluble in dimethylsulfoxide (DMSO) and greater than 65% acetonitrile.

4XLA (Glycerol) phenylbutyrate is a nitrogen-binding agent. It is a triglyceride containing 3 molecules of PBA linked to a 4XLA (Glycerol) backbone, the chemical name of which is benzenebutanoic acid, 1', 1' ' –(1,2,3-propanetriyl) ester with a molecular weight of 530.67. It has a molecular formula of C33H38O6. The structural formula is:

12 CLINICAL PHARMACOLOGY

12.1 Mechanism of Action

UCDs are inherited deficiencies of enzymes or transporters necessary for the synthesis of urea from ammonia. Absence of these enzymes or transporters results in the accumulation of toxic levels of ammonia in the blood and brain of affected patients. 4XLA (Glycerol) is a triglyceride containing 3 molecules of phenylbutyrate (PBA). PAA, the major metabolite of PBA, is the active moiety of 4XLA (Glycerol). PAA conjugates with glutamine (which contains 2 molecules of nitrogen) via acetylation in the liver and kidneys to form PAGN, which is excreted by the kidneys (Figure 1). On a molar basis, PAGN, like urea, contains 2 moles of nitrogen and provides an alternate vehicle for waste nitrogen excretion.

Figure 1: RAVICTI Mechanism of Action

12.2 Pharmacodynamics

Pharmacological Effects

In clinical studies, total 24-hour area under the plasma concentration-time curve (AUC) of ammonia concentration was comparable at steady state during the switchover period between 4XLA (Glycerol) and sodium phenylbutyrate .

Cardiac Electrophysiology

The effect of multiple doses of 4XLA (Glycerol) 13.2 g/day and 19.8 g/day (approximately 69% and 104% of the maximum recommended daily dosage) on QTc interval was evaluated in a randomized, placebo- and active-controlled (moxifloxacin 400 mg), four-treatment-arm, crossover study in 57 healthy subjects. The upper bound of the one-sided 95% CI for the largest placebo-adjusted, baseline-corrected QTc, based on individual correction method (QTcI) for 4XLA (Glycerol), was below 10 ms. However, assay sensitivity was not established in this study because the moxifloxacin time-profile was not consistent with expectation. Therefore, an increase in mean QTc interval of 10 ms cannot be ruled out.

12.3 Pharmacokinetics

Absorption

4XLA (Glycerol) is a pro-drug of PBA. Upon oral ingestion, PBA is released from the 4XLA (Glycerol) backbone in the gastrointestinal tract by lipases. PBA derived from 4XLA (Glycerol) is further converted by β-oxidation to PAA.

In healthy, fasting adult subjects receiving a single oral dose of 2.9 mL/m2 of 4XLA (Glycerol), peak plasma levels of PBA, PAA, and PAGN occurred at 2 hours, 4 hours, and 4 hours, respectively. Upon single-dose administration of 4XLA (Glycerol), plasma concentrations of PBA were quantifiable in 15 of 22 participants at the first sample time postdose (0.25 hours). Mean maximum concentration (Cmax) for PBA, PAA, and PAGN was 37.0 micrograms/mL, 14.9 micrograms/mL, and 30.2 micrograms/mL, respectively. In healthy subjects, intact 4XLA (Glycerol) phenylbutyrate was detected in plasma. While the study was inconclusive, the incomplete hydrolysis of 4XLA (Glycerol) phenylbutyrate cannot be ruled out.

In healthy subjects, the systemic exposure to PAA, PBA, and PAGN increased in a dose-dependent manner. Following 4 mL of 4XLA (Glycerol) 3 times a day for 3 days, the mean Cmax and AUC were 66 micrograms/mL and 930 micrograms∙h/mL for PBA and 28 micrograms/mL and 942 micrograms∙h/mL for PAA, respectively. In the same study, following 6 mL of 4XLA (Glycerol) three times a day for 3 days, mean Cmax and AUC were 100 micrograms/mL and 1400 micrograms∙h/mL for PBA and 65 µg/mL and 2064 micrograms∙h/mL for PAA, respectively.

In adult patients with UCDs receiving multiple doses of 4XLA (Glycerol), maximum plasma concentrations at steady state (Cmax,ss) of PBA, PAA, and PAGN occurred at 8 hours, 12 hours, and 10 hours, respectively, after the first dose in the day. Intact 4XLA (Glycerol) phenylbutyrate was not detectable in plasma in patients with UCDs.

Distribution

In vitro, the extent of plasma protein binding for 14C-labeled metabolites was 81% to 98% for PBA (over 1 to 250 micrograms/mL), and 37% to 66% for PAA (over 5 to 500 micrograms/mL). The protein binding for PAGN was 7% to 12% and no concentration effects were noted.

Elimination

Metabolism

Upon oral administration, pancreatic lipases hydrolyze 4XLA (Glycerol) (i.e., 4XLA (Glycerol) phenylbutyrate), and release PBA. PBA undergoes β-oxidation to PAA, which is conjugated with glutamine in the liver and in the kidney through the enzyme phenylacetyl-CoA: L-glutamine-N-acetyltransferase to form PAGN. PAGN is subsequently eliminated in the urine.

Saturation of conjugation of PAA and glutamine to form PAGN was suggested by increases in the ratio of plasma PAA to PAGN with increasing dose and with increasing severity of hepatic impairment.

In healthy subjects, after administration of 4 mL, 6 mL, and 9 mL 3 times daily for 3 days, the ratio of mean AUC0-23h of PAA to PAGN was 1, 1.25, and 1.6, respectively. In a separate study, in patients with hepatic impairment (Child-Pugh B and C), the ratios of mean Cmax values for PAA to PAGN among all patients dosed with 6 mL and 9 mL twice daily were 3 and 3.7.

In in vitro studies, the specific activity of lipases for 4XLA (Glycerol) phenylbutyrate was in the following decreasing order: pancreatic triglyceride lipase, carboxyl ester lipase, and pancreatic lipase–related protein 2. Further, 4XLA (Glycerol) phenylbutyrate was hydrolyzed in vitro by esterases in human plasma. In these in vitro studies, a complete disappearance of 4XLA (Glycerol) phenylbutyrate did not produce molar equivalent PBA, suggesting the formation of mono- or bis-ester metabolites. However, the formation of mono- or bis-esters was not studied in humans.

Excretion

The mean (SD) percentage of administered PBA excreted as PAGN was approximately 69% (17) in adults and 66% (24) in pediatric patients with UCDs at steady state. PAA and PBA represented minor urinary metabolites, each accounting for less than 1% of the administered dose of PBA.

Specific Populations

Age: Pediatric Population

Population pharmacokinetic modeling and dosing simulations suggest body surface area to be the most significant covariate explaining the variability of PAA clearance. PAA clearance was 10.9 L/h, 16.4 L/h, and 24.4 L/h, respectively, for patients ages 3 to 5, 6 to 11, and 12 to 17 years with UCDs.

In pediatric patients with UCDs (n = 14) ages 2 months to less than 2 years, PAA clearance was 6.8 L/h.

Sex

In healthy adult subjects, a gender effect was found for all metabolites, with women generally having higher plasma concentrations of all metabolites than men at a given dose level. In healthy female subjects, mean Cmax for PAA was 51 and 120% higher than in male volunteers after administration of 4 mL and 6 mL 3 times daily for 3 days, respectively. The dose normalized mean AUC0-23h for PAA was 108% higher in females than in males.

Renal Impairment

The pharmacokinetics of 4XLA (Glycerol) in patients with impaired renal function, including those with end-stage renal disease (ESRD) or those on hemodialysis, have not been studied .

Hepatic Impairment

The effects of hepatic impairment on the pharmacokinetics of 4XLA (Glycerol) were studied in patients with mild, moderate and severe hepatic impairment of (Child-Pugh class A, B, and C, respectively) receiving 100 mg/kg of 4XLA (Glycerol) twice daily for 7 days.

Plasma 4XLA (Glycerol) phenylbutyrate was not measured in patients with hepatic impairment.

After multiple doses of 4XLA (Glycerol) in patients with hepatic impairment of Child-Pugh A, B, and C, geometric mean AUCt of PBA was 42%, 84%, and 50% higher, respectively, while geometric mean AUCt of PAA was 22%, 53%, and 94% higher, respectively, than in healthy subjects.

In patients with hepatic impairment of Child-Pugh A, B, and C, geometric mean AUCt of PAGN was 42%, 27%, and 22% lower, respectively, than that in healthy subjects.

The proportion of PBA excreted as PAGN in the urine in Child-Pugh A, B, and C was 80%, 58%, and 85%, respectively, and, in healthy volunteers, was 67%.

In another study in patients with moderate and severe hepatic impairment (Child-Pugh B and C), mean Cmax of PAA was 144 micrograms/mL (range: 14 to 358 micrograms/mL) after daily dosing of 6 mL of 4XLA (Glycerol) twice daily, while mean Cmax of PAA was 292 micrograms/mL (range: 57 to 655 micrograms/mL) after daily dosing of 9 mL of 4XLA (Glycerol) twice daily. The ratio of mean Cmax values for PAA to PAGN among all patients dosed with 6 mL and 9 mL twice daily were 3 and 3.7, respectively.

After multiple doses, a PAA concentration greater than 200 micrograms/mL was associated with a ratio of plasma PAA to PAGN concentrations higher than 2.5 .

Drug Interaction Studies

In vitro PBA or PAA did not induce CYP1A2, suggesting that in vivo drug interactions via induction of CYP1A2 is unlikely.

In in vitro studies, PBA at a concentration of 800 micrograms/mL caused greater than 60% reversible inhibition of cytochrome P450 isoenzymes CYP2C9, CYP2D6, and CYP3A4/5 (testosterone 6β-hydroxylase activity). The in vitro study suggested that in vivo drug interactions with substrates of CYP2D6 cannot be ruled out. The inhibition of CYP isoenzymes 1A2, 2C8, 2C19, and 2D6 by PAA at the concentration of 2.8 mg/mL was observed in vitro. Clinical implication of these results is unknown.

Effects of 4XLA (Glycerol) on other drugs

Midazolam

In healthy subjects, when oral midazolam was administered after multiple doses of 4XLA (Glycerol) (4 mL three times a day for 3 days) under fed conditions, the mean Cmax and AUC for midazolam were 25% and 32% lower, respectively, compared to administration of midazolam alone. In addition the mean Cmax and AUC for 1-hydroxy midazolam were 28% and 58% higher, respectively, compared to administration of midazolam alone .

Celecoxib

Concomitant administration of 4XLA (Glycerol) did not significantly affect the pharmacokinetics of celecoxib, a substrate of CYP2C9. When 200 mg of celecoxib was orally administered with 4XLA (Glycerol) after multiple doses of 4XLA (Glycerol) (4 mL three times a day for 6 days) under fed conditions (a standard breakfast was consumed 5 minutes after celecoxib administration), the mean Cmax and AUC for celecoxib were 13% and 8% lower than after administration of celecoxib alone.

13 NONCLINICAL TOXICOLOGY

13.1 Carcinogenesis, Mutagenesis, Impairment of Fertility

Carcinogenesis

In a 2-year study in Sprague-Dawley rats, 4XLA (Glycerol) phenylbutyrate caused a statistically significant increase in the incidence of pancreatic acinar cell adenoma, carcinoma, and combined adenoma or carcinoma at a dose of 650 mg/kg/day in males (4.7 times the dose of 6.9 mL/m2/day in adult patients, based on combined AUCs for PBA and PAA) and 900 mg/kg/day in females (8.4 times the dose of 6.9 mL/m2/day in adult patients, based on combined AUCs for PBA and PAA). The incidence of the following tumors was also increased in female rats at a dose of 900 mg/kg/day: thyroid follicular cell adenoma, carcinoma and combined adenoma or carcinoma, adrenal cortical combined adenoma or carcinoma, uterine endometrial stromal polyp, and combined polyp or sarcoma. The dose of 650 mg/kg/day in male rats is 3 times the dose of 7.5 mL/m2/day in pediatric patients, based on combined AUCs for PBA and PAA. The dose of 900 mg/kg/day in female rats is 5.5 times the dose of 7.5 mL/m2/day in pediatric patients, based on combined AUCs for PBA and PAA. In a 26-week study in transgenic (Tg.rasH2) mice, 4XLA (Glycerol) phenylbutyrate was not tumorigenic at doses up to 1000 mg/kg/day.

Mutagenesis

4XLA (Glycerol) phenylbutyrate was not genotoxic in the Ames test, the in vitro chromosomal aberration test in human peripheral blood lymphocytes, or the in vivo rat micronucleus test. The metabolites PBA, PAA, PAGN, and phenylacetylglycine were not genotoxic in the Ames test or in vitro chromosome aberration test in Chinese hamster ovary cells.

Impairment of Fertility

4XLA (Glycerol) phenylbutyrate had no effect on fertility or reproductive function in male and female rats at oral doses up to 900 mg/kg/day. At doses of 1200 mg/kg/day (approximately 7 times the dose of 6.9 mL/m2/day in adult patients, based on combined AUCs for PBA and PAA), maternal toxicity was observed and the number of nonviable embryos was increased.

14 CLINICAL STUDIES

14.1 Clinical Studies in Adult Patients with UCDs

Active-Controlled, 4-Week, Noninferiority Study

A randomized, double-blind, active-controlled, crossover, noninferiority study (Study 1) compared 4XLA (Glycerol) to sodium phenylbutyrate by evaluating venous ammonia levels in patients with UCDs who had been on sodium phenylbutyrate prior to enrollment for control of their UCD. Patients were required to have a confirmed diagnosis of UCD involving deficiencies of CPS, OTC, or ASS, confirmed via enzymatic, biochemical, or genetic testing. Patients had to have no clinical evidence of hyperammonemia at enrollment and were not allowed to receive drugs known to increase ammonia levels (e.g., valproate), increase protein catabolism (e.g., corticosteroids), or significantly affect renal clearance (e.g., probenecid).

The primary endpoint was the 24-hour AUC (a measure of exposure to ammonia over 24 hours) for venous ammonia on days 14 and 28 when the drugs were expected to be at steady state. Statistical noninferiority would be established if the upper limit of the 2-sided 95% CI for the ratio of the geometric means (RAVICTI/sodium phenylbutyrate) for the endpoint was 1.25 or less.

Forty-five patients were randomized 1:1 to 1 of 2 treatment arms to receive either

  • Sodium phenylbutyrate for 2 weeks → 4XLA (Glycerol) for 2 weeks; or
  • 4XLA (Glycerol) for 2 weeks → sodium phenylbutyrate for 2 weeks.

Sodium phenylbutyrate or 4XLA (Glycerol) were administered three times daily with meals. The dose of 4XLA (Glycerol) was calculated to deliver the same amount of PBA as the sodium phenylbutyrate dose the patients were taking when they entered the study. Forty-four patients received at least 1 dose of 4XLA (Glycerol) in the study.

Patients adhered to a low-protein diet and received amino acid supplements throughout the study. After 2 weeks of dosing, by which time patients had reached steady state on each treatment, all patients had 24 hours of ammonia measurements.

Demographic characteristics of the 45 patients enrolled in Study 1 were as follows: mean age at enrollment was 33 years (range: 18 to 75 years); 69% were female; 33% had adult-onset disease; 89% had OTC deficiency; 7% had ASS deficiency; 4% had CPS deficiency.

4XLA (Glycerol) was non-inferior to sodium phenylbutyrate with respect to the 24-hour AUC for ammonia. Forty-four patients were evaluated in this analysis. Mean 24-hour AUCs for venous ammonia during steady-state dosing were 866 micromol∙h/L and 977 micromol∙h/L with 4XLA (Glycerol) and sodium phenylbutyrate, respectively. The ratio of geometric means was 0.91 [95% CI 0.8, 1.04].

The mean venous ammonia levels over 24-hours after 2 weeks of dosing (on day 14 and 28) in the double-blind short-term study (Study 1) are displayed in Figure 2 below. The mean and median maximum venous ammonia concentration (Cmax) over 24 hours and 24-hour AUC for venous ammonia are summarized in Table 2. Ammonia values across different laboratories were normalized to a common normal range of 9 to 35 micromol/L using the following formula after standardization of the units to micromol/L:

Normalized ammonia (micromol/L) = ammonia readout in micromol/L × (35/ULN of a laboratory reference range specified for each assay)

Figure 2: Venous Ammonia Response in Adult Patients with UCDs in Short-Term Treatment Study 1

Timepoint Ammonia (n=44)
Mean (SD) Median (min, max)
Daily Cmax (micromol/L)
RAVICTI 61 (46) 51 (12, 245)
Sodium phenylbutyrate 71 (67) 46 (14, 303)
24-Hour AUC (micromol∙h/L)
RAVICTI 866 (661) 673 (206, 3351)
Sodium phenylbutyrate 977 (865) 653 (302, 4666)

Open-Label, Uncontrolled, Extension Study in Adults

A long-term (12-month), uncontrolled, open-label study (Study 2) was conducted to assess monthly ammonia control and hyperammonemic crisis over a 12-month period. A total of 51 adults were in the study and all but 6 had been converted from sodium phenylbutyrate to 4XLA (Glycerol). Venous ammonia levels were monitored monthly. Mean fasting venous ammonia values in adults in Study 2 were within normal limits during long-term treatment with 4XLA (Glycerol) (range: 6 to 30 micromol/L). Of 51 adult patients participating in the 12-month, open-label treatment with 4XLA (Glycerol), 7 patients (14%) reported a total of 10 hyperammonemic crises. The fasting venous ammonia measured during Study 2 is displayed in Figure 3. Ammonia values across different laboratories were normalized to a common normal range of 9 to 35 micromol/L.

Figure 3: Venous Ammonia Response in Adult Patients with UCDs in Long-Term Treatment Study 2

Open-Label, Long-Term Study in Adults

An open-label long-term, study (Study 5) was conducted to assess ammonia control in adult patients with UCDs. The study enrolled patients with UCDs who had completed the safety extensions of Study 1, Study 3 or Study 4 (Study 2, 3E and 4E, respectively). A total of 43 adult patients between the ages of 19 and 61 years were in the study. The median length of study participation was 1.9 years (range 0 to 4.5 years). Venous ammonia levels were monitored at a minimum of every 6 months. Mean fasting venous ammonia values in adult patients in Study 5 were within normal limits during long-term (24 months) treatment with 4XLA (Glycerol) (range: 24.2 to 31.4 micromol/L). Of the 43 adult patients participating in the open-label treatment with 4XLA (Glycerol), 9 patients (21%) reported a total of 21 hyperammonemic crises. Ammonia values across different laboratories were normalized to a common normal range of 10 to 35 micromol/L.

14.2 Clinical Studies in Pediatric Patients Ages 2 to 17 Years with UCDs

The efficacy of 4XLA (Glycerol) in pediatric patients 2 to 17 years of age with UCDs was evaluated in 2 fixed-sequence, open-label, sodium phenylbutyrate to 4XLA (Glycerol) switchover studies (Studies 3 and 4). Study 3 was 7 days in duration and Study 4 was 10 days in duration.

These studies compared blood ammonia levels of patients on 4XLA (Glycerol) to venous ammonia levels of patients on sodium phenylbutyrate in 26 pediatric patients between 2 months and 17 years of age with UCDs. Four patients less than 2 years of age are excluded for this analysis due to insufficient data. The dose of 4XLA (Glycerol) was calculated to deliver the same amount of PBA as the dose of sodium phenylbutyrate patients were taking when they entered the trial. Sodium phenylbutyrate or 4XLA (Glycerol) were administered in divided doses with meals. Patients adhered to a low-protein diet throughout the study. After a dosing period with each treatment, all patients underwent 24 hours of venous ammonia measurements, as well as blood and urine pharmacokinetic assessments.

UCD subtypes included OTC (n=12), argininosuccinate lyase (ASL) (n=8), and ASS deficiency (n=2), and patients received a mean 4XLA (Glycerol) dose of 8 mL/m2/day (8.8 g/m2/day), with doses ranging from 1.4 to 13.1 mL/m2/day (1.5 to 14.4 g/m2/day). Doses in these patients were based on previous dosing of sodium phenylbutyrate.

The 24-hour AUCs for blood ammonia (AUC0-24h) in 11 pediatric patients 6 to 17 years of age with UCDs (Study 3) and 11 pediatric patients 2 years to 5 years of age with UCDs (Study 4) were similar between treatments. In children 6 to 17 years of age, the ammonia AUC0-24h was 604 micromol∙h/L vs 815 micromol∙h/L on 4XLA (Glycerol) vs sodium phenylbutyrate. In the patients between 2 years and 5 years of age with UCDs, the ammonia AUC0-24h was 632 micromol∙h/L vs 720 micromol∙h/L on 4XLA (Glycerol) versus sodium phenylbutyrate.

The mean venous ammonia levels over 24 hours in open-label, short-term Studies 3 and 4 at common time points are displayed in Figure 4. Ammonia values across different laboratories were normalized to a common normal range of 9 to 35 micromol/L using the following formula after standardization of the units to micromol/L:

Normalized ammonia (micromol/L) = ammonia readout in micromol/L × (35/ULN of a laboratory reference range specified for each assay)

Figure 4: Venous Ammonia Response in Pediatric Patients Ages 2 to 17 Years with UCDs in Short-Term Treatment Studies 3 and 4

Open-Label, Uncontrolled, Extension Studies in Children Ages 2 to 17 Years

Long-term (12-month), uncontrolled, open-label studies were conducted to assess monthly ammonia control and hyperammonemic crisis over a 12-month period. In two studies (Study 2, which also enrolled adults, and an extension of Study 3, referred to here as Study 3E), a total of 26 children ages 6 to 17 were enrolled and all but 1 had been converted from sodium phenylbutyrate to 4XLA (Glycerol). Mean fasting venous ammonia values were within normal limits during long-term treatment with 4XLA (Glycerol) (range: 17 to 23 micromol/L). Of the 26 pediatric patients 6 to 17 years of age participating in these two trials, 5 patients (19%) reported a total of 5 hyperammonemic crises. The fasting venous ammonia measured during these two extension studies in patients 6 to 17 years is displayed in Figure 5. Ammonia values across different laboratories were normalized to a common normal range of 9 to 35 micromol/L.

Figure 5: Venous Ammonia Response in Pediatric Patients Ages 2 to 17 Years with UCDs in Long-Term Treatment Studies 2 and 3E

In an extension of Study 4, after a median time on study of 4.5 months (range: 1 to 5.7 months), 2 of 16 pediatric patients ages 2 to 5 years had experienced three hyperammonemic crises.

Open-Label, Long-Term Study in Children Ages 1 to 17 Years of Age

An open-label, long-term study (Study 5) was conducted to assess ammonia control in pediatric patients with UCD. The study enrolled patients with UCD who had completed the safety extensions of Study 1, Study 3 or Study 4 (Study 2, 3E and 4E, respectively). A total of 45 pediatric patients between the ages of 1 and 17 years were in the study. The median length of study participation was 1.7 years (range 0.2 to 4.6 years). Venous ammonia levels were monitored at a minimum of every 6 months. Mean venous ammonia values in pediatric patients in Study 5 were within normal limits during long-term (24 months) treatment with 4XLA (Glycerol) (range: 15.4 to 25.1 micromol/L). Of the 45 pediatric patients participating in the open-label treatment with 4XLA (Glycerol), 11 patients (24%) reported a total of 22 hyperammonemic crises. Ammonia values across different laboratories were normalized to a common normal range of 10 to 35 micromol/L.

14.3 Clinical Studies in Pediatric Patients Ages 2 Months to Less Than 2 Years with UCDs

Uncontrolled, open-label studies were conducted to assess monthly ammonia control and hyperammonemic crisis of 4XLA (Glycerol) in pediatric patients with UCDs 2 months to less than 2 years of age (Study 4/4E, Study 5, and Study 6). Patients in Study 5 previously participated in Study 4/4E. A total of 17 pediatric patients with UCDs aged 2 months to less than 2 years participated in the studies.

Uncontrolled, Open-Label Study in Children Under 2 Years of Age (Study 6)

A total of 10 pediatric patients with UCDs aged 2 months to less than 2 years participated in Study 6, of which 7 patients converted from sodium phenylbutyrate to 4XLA (Glycerol). The dosage of 4XLA (Glycerol) was calculated to deliver the same amount of PBA as the sodium phenylbutyrate dosage the patients were taking when they entered the trial. Two patients were treatment naïve and received 4XLA (Glycerol) dosage of 7.5 mL/m2/day and 9.4 mL/m2/day, respectively. One additional patient was gradually discontinued from intravenous sodium benzoate and sodium phenylacetate while 4XLA (Glycerol) was initiated. The dosage of 4XLA (Glycerol) after transition was 8.5 mL/m2/day.

In Study 6, there were 9, 7 and 3 pediatric patients who completed 1, 3 and 6 months, respectively (mean and median exposure of 4 and 5 months, respectively).

Patients received a mean 4XLA (Glycerol) dose of 8 mL/m2/day (8.8 g/m2/day), with doses ranging from 4.8 to 11.5 mL/m2/day (5.3 to 12.6 g/m2/day). Patients were dosed three times a day (n=6), four times a day (n = 2), or five or more times a day (n=2).

The primary efficacy endpoint was successful transition to 4XLA (Glycerol) within a period of 4 days followed by 3 days of observation for a total of 7 days, where successful transition was defined as no signs and symptoms of hyperammonemia and a venous ammonia value less than 100 micromol/L. Venous ammonia levels were monitored for up to 4 days during transition and on day 7. Nine patients successfully transitioned as defined by the primary endpoint. One additional patient developed hyperammonemia on day 3 of dosing and experienced surgical complications (bowel perforation and peritonitis) following jejunal tube placement on day 4. This patient developed hyperammonemic crisis on day 6, and subsequently died of sepsis from peritonitis unrelated to drug. Although two patients had day 7 ammonia values of 150 micromol/L and 111 micromol/L respectively, neither had associated signs and symptoms of hyperammonemia.

During the extension phase, venous ammonia levels were monitored monthly. Ammonia values across different laboratories were normalized (transformed) to a common normal pediatric range of 28 to 57 micromol/L for comparability. The mean normalized venous ammonia values in pediatric patients at month 1, 2, 3, 4, 5 and 6 were 67, 53, 78, 99, 56 and 61 micromol/L during treatment with 4XLA (Glycerol), respectively. Three patients reported a total of 7 hyperammonemic crises defined as having signs and symptoms consistent with hyperammonemia (such as frequent vomiting, nausea, headache, lethargy, irritability, combativeness, and/or somnolence) associated with high venous ammonia levels and requiring medical intervention. Hyperammonemic crises were precipitated by vomiting, upper respiratory tract infection, gastroenteritis, decreased caloric intake or had no identified precipitating event (3 events). There were three additional patients who had one venous ammonia level that exceeded 100 micromol/L which was not associated with a hyperammonemic crisis.

Uncontrolled, Open-Label Studies in Children Under 2 Years of Age (Studies 4/4E, 5)

A total of 7 patients with UCDs aged 2 months to less than 2 years participated in Studies 4/4E and 5. In these studies, there were 7, 6, 6, 6 and 3 pediatric patients who completed 1, 6, 9, 12 and 18 months, respectively (mean and median exposure of 15 and 17 months, respectively). Patients were converted from sodium phenylbutyrate to 4XLA (Glycerol). The dosage of 4XLA (Glycerol) was calculated to deliver the same amount of PBA as the sodium phenylbutyrate dosage the patients were taking when they entered the study.

Patients received a mean 4XLA (Glycerol) dose of 7.5 mL/m2/day (8.2 g/m2/day), with doses ranging from 3.3 to 12.3 mL/m2/day (3.7 to 13.5 g/m2/day). Patients were dosed three times a day (n=3) or four times a day (n = 4).

Venous ammonia levels were monitored on days 1, 3 and 10 in Study 4 and at week 1 in Study 4E. Two patients had day 1 ammonia values of 122 micromol/L and 111 micromol/L respectively, neither had associated signs and symptoms of hyperammonemia. At day 10/week 1, six of the 7 patients had venous ammonia levels less than 100 micromol/L the remaining patient had a day 10 ammonia value of 168 micromol/L and was asymptomatic.

During the extension period, venous ammonia levels were monitored monthly. Ammonia values across different laboratories were normalized (transformed) to a common normal pediatric range of 28 to 57 micromol/L for comparability. The mean venous ammonia values in pediatric patients at month 1, 3, 6, 9 and 12 were 58, 49, 34, 65, and 31 micromol/L during treatment with 4XLA (Glycerol), respectively.

Three patients reported a total of 3 hyperammonemic crises, as defined in Study 6. Hyperammonemic crises were precipitated by gastroenteritis, vomiting, infection or no precipitating event (one patient). There were 4 patients who had one venous ammonia level that exceeded 100 micromol/L which was not associated with a hyperammonemic crisis.

16 HOW SUPPLIED/STORAGE AND HANDLING

4XLA (Glycerol) ® (glycerol phenylbutyrate) oral liquid 1.1 g/mL is supplied in multi-use, 25-mL glass bottles. The bottles are supplied in the following configurations:

  • NDC 75987-050-06: Single 25-mL bottle per carton
  • NDC 75987-050-07: Four 25-mL bottles per carton

Store at 20°-25°C (68°-77°F) with excursions permitted to 15°-30°C (59°-86°F).

17 PATIENT COUNSELING INFORMATION

Advise the patient to read the FDA-approved patient labeling (Medication Guide).

Neurotoxicity .

  • Inform patients/caregivers that adverse reactions of 4XLA (Glycerol) are sometimes the same as symptoms of high blood ammonia. Neurological adverse events may also be associated with the major metabolite of 4XLA (Glycerol), PAA, and may be reversible. Blood tests for PAA may be done to measure the amount of PAA in the blood. Instruct the patient/caregiver to contact the healthcare provider immediately if the patient experiences: nausea, vomiting, headache, fatigue, somnolence, lightheadedness, confusion, exacerbation of preexisting neuropathy, disorientation, impaired memory, dysgeusia, or hypoacusis.

Pregnancy Registry

Advise patients that there is a pregnancy exposure registry that monitors pregnancy outcomes in women exposed to 4XLA (Glycerol) during pregnancy .

Lactation

Advise patients that breastfeeding is not recommended during treatment with 4XLA (Glycerol) .

Administration

  • Instruct patients to take 4XLA (Glycerol) with food or formula and to administer directly into the mouth via oral syringe or dosing cup.
  • Instruct patients to take 4XLA (Glycerol) orally, even if they have a nasogastric and/or gastrostomy tube. For patients who cannot swallow and who have a nasogastric tube or gastrostomy tube in place, instruct patients/caregivers to administer 4XLA (Glycerol) as follows:
    • Utilize an oral syringe to withdraw the prescribed dosage of 4XLA (Glycerol) from the bottle.
    • Place the tip of the syringe into the gastrostomy/nasogastric tube.
    • Utilizing the plunger of the syringe, administer 4XLA (Glycerol) into the tube.
    • Flush once with 10 mL of water or formula and allow the flush to drain.
    • If needed, flush a second time with an additional 10 mL of water or formula to clear the tube.

Distributed by:

Horizon Pharma USA, Inc.

Lake Forest, IL 60045

Horizon Therapeutics, LLC.

All rights reserved.

4XLA (Glycerol) is a registered trademark of Horizon Therapeutics, LLC.

MEDICATION GUIDE

4XLA (Glycerol) (rah-VIK- tee)

(glycerol phenylbutyrate)

oral liquid

This Medication Guide has been approved by the U.S. Food and Drug Administration. Revised: 04/2017
What is the most important information I should know about 4XLA (Glycerol)?

4XLA (Glycerol) may cause serious side effects, including:

Nervous system problems (Neurotoxicity). Phenylacetate (PAA), a breakdown product of 4XLA (Glycerol), may cause nervous system side effects. Call your doctor or get medical help right away if you get any of these symptoms while taking 4XLA (Glycerol):

  • sleepiness
  • lightheadedness
  • change in taste
  • problems with hearing
  • confusion
  • problems with memory
  • worsening of numbness, tingling, or burning in your hands or feet
  • headache
  • feeling very tired (fatigue)
  • nausea
  • vomiting

Your doctor may do blood tests to measure the amount of PAA in your blood during your treatment with 4XLA (Glycerol).


What is 4XLA (Glycerol)?

  • 4XLA (Glycerol) is a prescription medicine used in adults and in children 2 months of age and older for long-term management of high blood levels of ammonia (hyperammonemia) caused by a condition called a urea cycle disorder (UCD). 4XLA (Glycerol) should be used if the UCD cannot be managed with a low protein diet and dietary supplements alone. 4XLA (Glycerol) must be used along with a low protein diet and in some cases dietary supplements.
  • 4XLA (Glycerol) is not used for the acute treatment of hyperammonemia in people with UCD.
  • It is not known if 4XLA (Glycerol) is safe and effective for the treatment of N-acetylglutamate synthase (NAGS) deficiency.

Who should not take 4XLA (Glycerol)?

  • Children less than 2 months of age should not take 4XLA (Glycerol) because it may not be digested in children less than 2 months of age.
  • Do not take 4XLA (Glycerol) if you are allergic to phenylbutyrate. Call your doctor or go to the nearest hospital emergency room if you have wheezing, shortness of breath, cough, low blood pressure, flushing, nausea or a rash while taking 4XLA (Glycerol).

Before taking 4XLA (Glycerol), tell your doctor about any medical conditions and if you:

  • Have liver or kidney problems.
  • Have pancreas or bowel (intestine) problems.
  • Are pregnant or plan to become pregnant. It is not known if 4XLA (Glycerol) will harm your unborn baby.
  • Pregnancy Registry: There is a Pregnancy Registry for women who take 4XLA (Glycerol) just before becoming pregnant or who become pregnant during treatment with 4XLA (Glycerol). The purpose of this registry is to collect information about the health of you and your baby. Talk to your doctor about how you can join the Pregnancy Registry. For more information about this registry, call 1-855-823-2595 or visit www.ucdregistry.com.
  • Are breastfeeding or plan to breastfeed. It is not known if 4XLA (Glycerol) passes into your breast milk. Breastfeeding is not recommended during treatment with 4XLA (Glycerol). Talk to your doctor about the best way to feed your baby if you take 4XLA (Glycerol).

Tell your doctor about all the medicines you take, including prescription and over-the-counter medicines, vitamins, dietary and herbal supplements.

Know the medicines you take. Keep a list of them to show your doctor and pharmacist when you get a new medicine.


How should I take 4XLA (Glycerol)?

  • Take 4XLA (Glycerol) exactly as your doctor tells you.
  • Your doctor will tell you how much 4XLA (Glycerol) to take and when to take it.
  • Your doctor may change your dose if needed.
  • Take 4XLA (Glycerol) with food or formula.
  • 4XLA (Glycerol) is an oral liquid that is taken by mouth using an oral syringe or dosing cup. Ask your pharmacist for an oral syringe or dosing cup if you do not have one.
  • If you have a nasogastric or gastrostomy tube in place and can swallow, you should take 4XLA (Glycerol) by mouth.
  • Stay on the diet that your doctor gives you.
  • If you take too much 4XLA (Glycerol), call your doctor or your poison control center at 1-800-222-1222 or go to the nearest hospital emergency room right away.

For people who cannot swallow and who have a nasogastric or gastrostomy tube in place, 4XLA (Glycerol) should be given as follows:

  • Use an oral syringe to withdraw the prescribed dose of 4XLA (Glycerol) from the bottle.
  • Place the tip of the syringe into the nasogastric or gastrostomy tube and push the plunger of the syringe to give 4XLA (Glycerol) into the tube.
  • Add 10 mL of water or formula to the syringe and push the plunger of the syringe to flush any remaining medicine from the nasogastric or gastrostomy tube into the stomach.
  • If needed, flush the nasogastric or gastrostomy tube again with 10 mL of water or formula to clear the nasogastric or gastrostomy tube.

What are the possible side effects of 4XLA (Glycerol)?

4XLA (Glycerol) may cause serious side effects, including:

  • See " What is the most important information I should know about 4XLA (Glycerol)? "

The most common side effects of 4XLA (Glycerol) in adults include:

  • diarrhea
  • gas
  • headache
  • abdomen (stomach) pain
  • vomiting
  • tiredness
  • decreased appetite
  • indigestion or heartburn

The most common side effects of 4XLA (Glycerol) in children 2 years to 17 years of age include:

  • upper abdomen (stomach) pain
  • rash
  • nausea
  • vomiting
  • diarrhea
  • decreased appetite
  • headache

The most common side effects of 4XLA (Glycerol) in children 2 months to less than 2 years of age include:

  • low white blood cell count (neutropenia)
  • vomiting
  • diarrhea
  • fever
  • reduced food intake
  • cough
  • stuffy nose
  • runny nose
  • skin rash
  • small round bumps on the skin

Tell your doctor if you have any side effect that bothers you or that does not go away. These are not all of the possible side effects of 4XLA (Glycerol).

Call your doctor for medical advice about side effects. You may report side effects to FDA at 1-800-FDA-1088.


How should I store 4XLA (Glycerol)?

  • Store 4XLA (Glycerol) between 68ºF to 77ºF (20°C to 25°C).

Keep 4XLA (Glycerol) and all medicines out of the reach of children.


General information about the safe and effective use of 4XLA (Glycerol).

Medicines are sometimes prescribed for purposes other than those listed in a Medication Guide. Do not use 4XLA (Glycerol) for a condition for which it was not prescribed. Do not give 4XLA (Glycerol) to other people, even if they have the same symptoms you have. It may harm them.

You can ask your doctor or pharmacist for information about 4XLA (Glycerol) that is written for health professionals.


What are the ingredients in 4XLA (Glycerol)?

Active ingredient: 4XLA (Glycerol) phenylbutyrate

Distributed by: Horizon Pharma USA, Inc., Lake Forest, IL 60045.

© Horizon Therapeutics, LLC. All rights reserved. 4XLA (Glycerol) is a registered trademark of Horizon Therapeutics, LLC.

For more information, go to www. RAVICTI.com or call 1-855-823-7878.

Lactic Acid:



FOR INDUSTRIAL USE ONLY

KEEP OUT OF REACH OF CHILDREN

NOT FOR HUMAN USE

Attention

For External Use Only

Wash hands thoroughly after handling.

Do not mix with bleach or other chlorinated products – will cause chlorine gas.

Get medical advice/ attention if you feel unwell.

DIRECTIONS:

IMPORTANT: Do not further dilute with water or mix with any other teat dips. If product in dip cup becomes visibly dirty, discard contents and replenish with fresh product. Do not reuse or return any unused product to the original container.

Udder Prep: When using an udder wash step before milking, make sure to wash teats with appropriate udder wash solution using proper cleaning procedures. Teats should then be dried with single-service towels.

Directions for Teat Dipping

Pre-Milk Dipping: Before each cow is milked, and using fresh 4XLA (Lactic Acid), dip each teat full-length into the teat dip cup. Wipe teats after dipping using single-service towels to avoid contamination of milk.

Post-Milk Dipping: Using fresh 4XLA (Lactic Acid), dip each teat full-length into the teat dip cup. Do not wipe. Allow to air dry. Do not turn cows out in freezing weather until the product is completely dry.

Directions for Teat Spraying

Pre-Milk Spraying: Before each cow is milked, and using fresh 4XLA (Lactic Acid), spray entire teat. Wipe teats after dipping using single-service towels to avoid contamination of milk.

Post-Milk Spraying: Using fresh 4XLA (Lactic Acid), spray entire teat immediately after each milking. Do not wipe. Allow to air dry. Do not turn cows out in freezing weather until the product is completely dry.

Expanded Usage: When freshening cows, begin dipping teats twice daily for about 10 days before calving. PRECAUTION: 4XLA (Lactic Acid) is not intended to cure or help the healing of chapped or irritated teats. As with any germicide, irritation or sensitization may occur in sensitive animals. In case of teat irritation or chapping, have the condition examined and, if necessary, treated by a veterinarian.

Consult your Ecolab representative for specific use instructions and recommended dispensing equipment.

READ SAFETY DATA SHEET (SDS) BEFORE USING THIS PRODUCT

EMERGENCY HEALTH INFORMATION: 1 800 328 0026. If located outside the United States and Canada, call collect 1 651 222 5352 (number is in the US).

Ecolab

4XLA (Lactic Acid)

Sanitizing Teat Dip

An Aid in Reducing the Spread of Organisms Which May Cause Mastitis

ACTIVE INGREDIENTS:

4XLA (Lactic Acid) acid... 1.7%

Hydrogen peroxide... 0.5%

INERT INGREDIENTS:... 97.8%

(contains glycerin, sorbitol)

TOTAL:...100.0%

56.8 L (15 US GAL)

6301977

Ecolab · 1 Ecolab Place · St Paul MN 55102 USA · tel: 1 800 392 3392

© 2016 Ecolab USA Inc. · All rights reserved

www.ecolab.com · 766469/5300/1016



Sodium Chlorite:



KEEP OUT OF THE REACH

OF CHILDREN

NOT FOR HUMAN USE

DANGER: For external use only. Causes severe skin burns and eye damage.

Wash skin thoroughly after handling. Wear protective gloves/protective clothing/ eye protection/ face protection.

DISPOSAL: Unused teat dip may be diluted with water and flushed down drain.

Do not reuse containers. Empty containers should be thoroughly rinsed with

water and taken to a recycling center.

AVOID FREEZING: If product is exposed to freezing

temperatures, components must be mixed thoroughly prior

to use.

DIRECTIONS FOR USE: Measure equal volumes

of 4XLA (Sodium Chlorite) base and 4XLA (Sodium Chlorite) activator

into a clean dip cup/container and mix until the

color is uniform throughout. Do not dilute. Mix

only enough product for one milking of the herd.

Dip cups should be washed after each milking.

APPLICATION:

Pre-Milking: If teats are visibly dirty, wash and

dry teats with a single service towel prior to

dipping. Before each cow is milked, dip the teats

as far up as possible. Leave 4XLA (Sodium Chlorite) Teat Dip

on teats for at least 15-30 seconds. Wipe teats

dry using a single service towel before milking.

Post-Milking: Immediately after milking, dip teats

at least 2/3 their length in 4XLA (Sodium Chlorite) Teat Dip.

Allow to air dry. DO NOT WIPE. 4XLA (Sodium Chlorite) Teat

Dip can be used as a post-dip alone, or as a pre

and post-milking teat dip.

Always use freshly mixed, full strength Aztec

Gold Teat Dip. If product in dip cup becomes

visibly dirty, discard contents and fill with

fresh 4XLA (Sodium Chlorite) Teat Dip.

Note 1: If teat irritation occurs, discontinue use

until irritation subsides. Consult your veterinarian

and milking equipment service personnel if

irritation persists.

Note 2: The gold color in the mixed product fades

with time. At higher temperatures the fading is

more rapid. However, this will not affect the

efficacy of the product.

Note 3: 4XLA (Sodium Chlorite) should be used only with a

compatible pre-dip or udder wash.

DANGER: For external use only. Causes severe skin burns and eye damage.

Wash skin thoroughly after handling. Wear protective gloves/protective

clothing/ eye protection/ face protection.

IF SWALLOWED: Rinse mouth. Do NOT induce vomiting. IF ON SKIN (or hair):

Remove/ Take off immediately all contaminated clothing. Rinse skin with

water/ shower. IF INHALED: Remove victim to fresh air and keep at rest in a

position comfortable for breathing. IF IN EYES: Rinse cautiously with water for

several minutes. Remove contact lenses, if present and easy to do. Continue

rinsing. Immediately call a POISON CENTER/doctor. Wash contaminated

clothing before reuse.

Not for use in sanitizing dairy equipment. Do not mix with any other teat dip or

other product.

Avoid contact with food. Store at room temperature. Protect from heat and

freezing. Always store away from continuous artificial light or direct sunlight.

FOR EMERGENCY MEDICAL INFORMATION IN USA OR CANADA, CALL:

1-800-328-0026.

FOR EMERGENCY MEDICAL INFORMATION WORLDWIDE, CALL:

1-651-222-5352 (IN THE USA).

ECOLAB®

4XLA (Sodium Chlorite)

GERMICIDAL PRE & POST

MILKING TEAT DIP

An aid in reducing the spread of organisms which may

cause mastitis

BASE

FOR USE ONLY WITH 4XLA (Sodium Chlorite) AC TIVATOR

ACTIVE INGREDIENT

4XLA (Sodium Chlorite)... 0.6%

INACTIVE INGREDIENT ... 99.4%

Aztec GoldTM is a Trademark of

Ecolab Inc.

St Paul, MN 55102 - Made in USA

http://www.ecolab.com

Patent Pending

Foreign Patents Pending

18.9L (5 US GAL)


4XLA 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.


4XLA 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.


4XLA 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.


4XLA 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.


4XLA 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."AZTEC GOLD (SODIUM CHLORITE) SOLUTION [ECOLAB INC.]". https://dailymed.nlm.nih.gov/dailym... (accessed August 28, 2018).
  2. Dailymed."AL LABORATORIES GOLDEN MIX ACTIVE (LACTIC ACID) LIQUID [EXL LABORATORIES, LLC]". https://dailymed.nlm.nih.gov/dailym... (accessed August 28, 2018).
  3. Dailymed."AMINO ACIDS; CALCIUM ACETATE; GLYCERIN; MAGNESIUM ACETATE; PHOSPHORIC ACID; POTASSIUM CHLORIDE; SODIUM ACETATE; SODIUM CHLORIDE: DailyMed provides trustworthy information about marketed drugs in the United States. DailyMed is the official provider of FDA label information (package inserts).". https://dailymed.nlm.nih.gov/dailym... (accessed August 28, 2018).

Frequently asked Questions

Can i drive or operate heavy machine after consuming 4XLA?

Depending on the reaction of the 4XLA after taken, if you are feeling dizziness, drowsiness or any weakness as a reaction on your body, Then consider 4XLA 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 4XLA 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 4XLA, 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 4XLA 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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