Pyridoxine, or vitamin B6, is a naturally occurring, water-soluble B vitamin found in food such as cereal grains, legumes, vegetables, liver, meat, and eggs. Pyridoxine is used to treat and prevent vitamin B6 deficiency; to prevent or treat toxicity from isoniazid, cycloserine, or hydralazine; and to treat sideroblastic anemia associated with elevated serum iron levels. It also has been used in pyridoxine-dependent neonates to treat seizures that are unresponsive to conventional therapy and in patients with metabolic disorders such as xanthurenic aciduria, primary hyperoxaluria, primary cystathioninuria, and primary homocystinuria. Pyridoxine is considered a first-line pharmacologic agent in the ACOG treatment algorithm for nausea and vomiting due to pregnancy, and may be used with or without doxylamine.
General Administration Information
For storage information, see the specific product information within the How Supplied section.
Route-Specific Administration
Oral Administration
Oral Solid Formulations
-Administer with a meal preferably.
For acute isoniazid overdose
-If sufficient quantities of the injectable formulation are not available, consideration may be given to crushing oral pyridoxine tablets and administering with fluids via a nasogastric tube.
Extemporaneous Compounding-Oral
NOTE: Extemporaneous compounding of oral suspension from the injectable product is not FDA-approved.
-A 25 mg/mL oral suspension was compounded by diluting pyridoxine injection (100 mg/mL) with Oral Mix or Oral Mix SF suspension vehicles.
-Storage: The suspension was stable in amber glass bottles, plastic bottles, or oral plastic syringes at 25 degrees C or in amber glass bottles or plastic bottles at 4 degrees C for up to 91 days.
Injectable Administration
-Visually inspect parenteral products for particulate matter and discoloration prior to administration whenever solution and container permit.
Intravenous Administration
Intravenous (IV) Push
Vials for Injection
-Administration via slow IV push over 3 to 5 minutes has been suggested in cases of acute isoniazid overdose.
Intravenous (IV) Infusion
Vials for Injection
Dilution
-5 g diluted in 50 to 100 mL 5% Dextrose Injection has been suggested in cases of acute isoniazid overdose.
Intermittent IV Infusion
-Administration via IV infusion over 30 to 60 minutes or at a rate of 500 mg/minute has been suggested in cases of acute isoniazid overdose.
Intramuscular Administration
Intramuscular Injection
-Inject deeply into a large muscle (e.g., ventrogluteal, anterolateral thigh, or deltoid).
Pyridoxine is considered nontoxic in regular doses; however, nausea/vomiting, headache, paresthesias, hyperesthesia, somnolence, and low serum folic acid levels have been reported. Excessive, chronic dosages of pyridoxine (2-6 grams/day) have been associated with a severe sensory peripheral neuropathy or neuronopathy syndrome. This may result from neuron susceptibility in the dorsal root ganglia. One patient who consumed 5 g/day developed pseudoathetosis of the outstretched arms, ataxia, and absent limb reflexes. Seven months after discontinuation of high-dose pyridoxine, she felt much improved, could walk steadily without a cane, could stand with her eyes closed, but still had shooting pains in her calves and shins. Other patients who took several g/day for several months developed unstable gait, perioral numbness, and a "stocking-glove" sensory loss. Seizures have occurred following large IV doses of pyridoxine. Seizures in neonates have occurred following the use of large doses of pyridoxine during pregnancy. Adverse neurologic reactions with lower dosages have been reported less frequently.
A transient worsening of metabolic acidosis, which is frequently present in patients with seizures, may occur after rapid infusion of large pyridoxine doses. Pyridoxine injection is acidic (pH 2-3.8). In a randomized, controlled crossover trial of 5 adult patients, 5000 mg of pyridoxine administered over 5 minutes induced a significant but transient increase in the base deficit; mean maximal increase in base deficit was 2.74 mEq/L at 3 minutes after infusion. Resolution occurred 30 minutes after the infusion.
Parenteral pyridoxine solutions contain varying concentrations of aluminum. Patients with renal impairment, especially as seen in premature neonates, are at risk of aluminum accumulation which may result in toxicity. Limit intravenous pyridoxine therapy and consider the cumulative aluminum content among all therapies under administration in patients with renal impairment. It is noted that 4-5 mcg/kg/day of IV aluminum leads to accumulation at concentrations associated with CNS and bone toxicity; further, aluminum tissue loading is possible at lesser, but undefined, daily administration rates. Aluminum concentration in parenteral solutions can be obtained by direct manufacturer inquiry.
Appropriate maternal pyridoxine (vitamin B6) intake is encouraged during pregnancy, and the requirement for pyridoxine appears to be increased during pregnancy. Pyridoxine (up to 40 mg/day) in combination with doxylamine is FDA-approved for the treatment of pregnancy-induced nausea and vomiting. Pyridoxine is a first-line pharmacologic agent in the ACOG treatment algorithm for nausea and vomiting due to pregnancy and may be used with or without doxylamine. A meta-analysis of 16 cohort and 11 case-control studies published between 1963 and 1991 reported no increased risk for malformations from first trimester exposures to doxylamine succinate and pyridoxine hydrochloride, with or without dicyclomine hydrochloride. A second meta-analysis of 12 cohort and 5 case-control studies published between 1963 and 1985 reported no statistically significant relationships between fetal abnormalities and the first trimester use of the combination doxylamine succinate and pyridoxine hydrochloride with or without dicyclomine hydrochloride.
Pyridoxine is considered compatible with breast-feeding. Pyridoxine is excreted in human milk. Appropriate maternal intake of pyridoxine (vitamin B6) is important during lactation, and no problems have been identified with maternal supplementation to achieve adequate intake goals during breast-feeding. Consider the benefits of breast-feeding, the risk of potential infant drug exposure, and the risk of an untreated or inadequately treated condition.
For nutritional supplementation:
-the recommended dietary allowance (RDA) of pyridoxine for nutritional supplementation in healthy individuals:
Oral dosage:
Adult and Adolescent pregnant females: 1.9 mg/day PO.
Adult and Adolescent lactating females: 2 mg/day PO.
Adult females 51 years and older: 1.5 mg/day PO.
Adult males 51 years and older: 1.7 mg/day PO.
Adults 19 to 50 years: 1.3 mg/day PO.
Adolescent females 14 years and older: 1.2 mg/day PO is the recommended dietary allowance (RDA).
Adolescent males 14 years and older: 1.3 mg/day PO is the recommended dietary allowance (RDA).
Children and Adolescents 9 to 13 years: 1 mg/day PO is the recommended dietary allowance (RDA)..
Children 4 to 8 years: 0.6 mg/day PO is the recommended dietary allowance (RDA)..
Children 1 to 3 years: 0.5 mg/day PO is the recommended dietary allowance (RDA).
Infants older than 6 months: 0.3 mg/day PO is the Adequate Intake (AI). Alternatively, weight-based dosing is approximately 0.033 mg/kg/day.
Neonates and Infants 6 months and younger: 0.1 mg/day PO is the Adequate Intake (AI). Alternatively, weight-based dosing is approximately 0.014 mg/kg/day.
Premature neonates: 150 to 210 mcg/kg/day PO. The daily requirement is directly related to protein intake.
-in patients receiving total parenteral nutrition (TPN):
Intravenous dosage:
Adults: Specific recommendations are not available; however, 10 mL/day of the IV adult parenteral multivitamin preparation, which contains 6 mg of pyridoxine, is recommended to be added to the TPN for nutritional supplementation in patients weighing more than 40 kg.
Children* and Adolescents* weighing more than 40 kg: Specific recommendations are not available; however, 10 mL/day of the IV adult parenteral multivitamin preparation, which contains 6 mg of pyridoxine, is recommended to be added to the TPN for nutritional supplementation in patients weighing more than 40 kg.
Neonates*, Infants*, Children*, and Adolescents* weighing 2.5 to 40 kg: 1 mg/day IV admixed with TPN.
Neonates* less than 2.5 kg: 0.4 mg/kg/day IV admixed with TPN. Max: 1 mg/day.
For the treatment of vitamin B6 deficiency states, including neuritis, that are not drug-induced:
Oral dosage:
Adults without neuritis: 2.5 to 10 mg/day PO. After the deficiency has been corrected, 2 to 5 mg/day may be given for several weeks.
Adults with neuritis: 100 to 200 mg/day PO for 3 weeks, then 25 to 100 mg/day PO thereafter.
Children without neuritis: 5 to 25 mg/day PO for 3 weeks, then 1.5 to 2.5 mg/day PO supplemented in a multivitamin product. A pyridoxal phosphate concentration less than 20 nmol/L indicates a vitamin B6 deficiency.
Children with neuritis: 10 to 50 mg/day for 3 weeks, then 1 to 2 mg/day PO supplemented in a multivitamin product. A pyridoxal phosphate concentration less than 20 nmol/L indicates a vitamin B6 deficiency.
For the treatment of sideroblastic anemia:
Oral dosage:
Adults: 200-600 mg/day PO. Following an adequate response, 30-50 mg/day PO may be used.
Children: Dosage not established.
For the treatment of seizures due to acute mushroom poisoning:
Intravenous dosage:
Adults: 25 mg/kg IV administered over 15 to 30 minutes. May be repeated as necessary to a total dose of 15 to 20 g/day.
Infants*, Children*, and Adolescents*: 25 mg/kg IV administered over 15 to 30 minutes. Max initial dose: 5 grams. Repeat dose as necessary up to 300 mg/kg/day. Max: 15 to 20 grams/day.
For the treatment of cycloserine toxicity related to pyridoxine deficiency:
Oral dosage:
Adults: 100 mg PO once daily. The FDA-approved dosage is 200 to 300 mg PO once daily. However, pyridoxine-related neuropathy has been reported with doses more than 100 mg/day and some experts would not exceed 100 mg/day. Doses more than 200 mg/day should not be used.
Infants*, Children*, and Adolescents*: 2 to 5 mg/kg/dose (Max: 100 mg/dose) PO once daily.
For the treatment of hydralazine toxicity related to pyridoxine deficiency:
Oral dosage:
Adults: 100 to 300 mg/day PO.
Adolescents: 100 to 300 mg/day PO.
Children: 10 to 50 mg/day PO.
For cycloserine toxicity prophylaxis:
Oral dosage:
Adults: 50 mg PO once daily. The FDA-approved dosage is 200 to 300 mg PO once daily. However, pyridoxine-related neuropathy has been reported with doses more than 100 mg/day and some experts would not exceed 100 mg/day. Doses more than 200 mg/day should not be used.
Infants*, Children*, and Adolescents*: 0.5 to 2 mg/kg/dose (Max: 50 mg/dose) PO once daily.
For hydralazine toxicity prophylaxis:
Oral dosage:
Adults: 100 mg PO once daily.
Adolescents*: 25 to 100 mg/day PO.
Children*: 1 to 2 mg/kg/day PO.
For the treatment of isoniazid toxicity (other than seizures) related to pyridoxine deficiency:
Oral dosage*:
Adults: 100 mg PO once daily.
Infants, Children, and Adolescents: 2 to 5 mg/kg/dose (Max: 100 mg/dose) PO once daily.
Intravenous or Intramuscular dosage:
Adults: 100 mg IV or IM once daily for 3 weeks, followed by 30 mg IV or IM once daily.
For oral contraceptive toxicity prophylaxis:
Oral dosage:
Adult females: 25-30 mg/day PO.
For the treatment of acute isoniazid overdose, including drug-induced seizures:
-for the treatment of acute isoniazid overdose in an asymptomatic person with a known amount of isoniazid ingested:
Intravenous dosage:
Adults: 1 g pyridoxine IV per 1 g isoniazid as a single dose. May repeat dose if necessary. Usual Max: 5 g.
Infants*, Children*, and Adolescents*: 1 g pyridoxine IV per 1 g isoniazid as a single dose. May repeat dose if necessary. Usual Max: 5 g or 80 mg/kg, whichever is lower.
Oral dosage*:
Adults: 1 g pyridoxine PO per 1 g isoniazid if IV pyridoxine is unavailable. May repeat dose if necessary. Usual Max: 5 g.
Infants, Children, and Adolescents: 1 g pyridoxine PO per 1 g isoniazid if IV pyridoxine is unavailable. May repeat dose if necessary. Usual Max: 5 g or 80 mg/kg, whichever is lower.
-for the treatment of acute isoniazid overdose in an asymptomatic person with an unknown amount of isoniazid ingested:
Intravenous dosage:
Adults: 5 g IV as a single dose. May repeat dose if necessary. Usual Max: 5 g.
Infants*, Children*, and Adolescents*: 70 to 80 mg/kg/dose IV as a single dose. May repeat dose if necessary. Usual Max: 5 g or 80 mg/kg, whichever is lower.
Oral dosage*:
Adults: 5 g PO as a single dose if IV pyridoxine is unavailable. May repeat dose if necessary. Usual Max: 5 g.
Infants, Children, and Adolescents: 70 to 80 mg/kg/dose PO as a single dose if IV pyridoxine is unavailable. May repeat dose if necessary. Usual Max: 5 g or 80 mg/kg, whichever is lower.
-for the treatment of acute isoniazid overdose in a symptomatic person with a known amount of isoniazid ingested:
Intravenous or Intramuscular dosage:
Adults: 1 g pyridoxine IV per 1 g isoniazid as a single dose. Alternatively, 0.5 mg/minute IV until seizures stop or maximum dose reached; once seizures stop, infuse the remainder of the dose over 4 to 6 hours to maintain pyridoxine availability during isoniazid elimination. May repeat dose if necessary. Usual Max: 5 g. The FDA-approved dose is 4 g IV as a single dose, followed by 1 g IM every 30 minutes for 6 doses for ingestion of more than 10 g of isoniazid.
Infants*, Children*, and Adolescents*: 1 g pyridoxine IV per 1 g isoniazid as a single dose. Alternatively, 0.5 mg/minute IV until seizures stop or maximum dose reached; once seizures stop, infuse the remainder of the dose over 4 to 6 hours to maintain pyridoxine availability during isoniazid elimination. May repeat dose if necessary. Usual Max: 5 g or 80 mg/kg, whichever is lower.
Oral dosage*:
Adults: 1 g pyridoxine PO per 1 g isoniazid if IV pyridoxine is unavailable. May repeat dose if necessary. Usual Max: 5 g.
Infants, Children, and Adolescents: 1 g pyridoxine PO per 1 g isoniazid if IV pyridoxine is unavailable. May repeat dose if necessary. Usual Max: 5 g or 80 mg/kg, whichever is lower.
-for the treatment of acute isoniazid overdose in a symptomatic person with an unknown amount of isoniazid ingested:
Intravenous dosage:
Adults: 5 g IV as a single dose. Alternatively, 0.5 mg/minute IV until seizures stop or maximum dose reached; once seizures stop, infuse the remainder of the dose over 4 to 6 hours to maintain pyridoxine availability during isoniazid elimination. May repeat dose if necessary. Usual Max: 5 g.
Infants*, Children*, and Adolescents*: 70 to 80 mg/kg/dose IV as a single dose. Alternatively, 0.5 mg/minute IV until seizures stop or maximum dose reached; once seizures stop, infuse the remainder of the dose over 4 to 6 hours to maintain pyridoxine availability during isoniazid elimination. May repeat dose if necessary. Usual Max: 5 g or 80 mg/kg, whichever is lower.
Oral dosage*:
Adults: 5 g PO as a single dose if IV pyridoxine is unavailable. May repeat dose if necessary. Usual Max: 5 g.
Infants, Children, and Adolescents: 70 to 80 mg/kg/dose PO as a single dose if IV pyridoxine is unavailable. May repeat dose if necessary. Usual Max: 5 g or 80 mg/kg, whichever is lower.
For the treatment of acute penicillamine toxicity:
Oral dosage:
Adults: 25 to 100 mg PO once daily for 3 weeks followed by 2 to 2.5 mg PO once daily.
Adolescents*: 100 to 300 mg/day PO.
Children*: 10 to 50 mg/day PO.
For isoniazid toxicity prophylaxis:
-for isoniazid toxicity prophylaxis during treatment of active tuberculosis infection:
Oral dosage:
Adults: 25 to 50 mg PO once daily for patients at risk of neuropathy (e.g., persons with HIV, diabetes, alcoholism, nutritional deficiency, chronic renal failure, advanced age).
Infants, Children, and Adolescents: 0.5 to 2 mg/kg/dose (Max: 50 mg/dose) PO once daily for patients at risk of neuropathy (e.g., persons with HIV, diabetes, alcoholism, nutritional deficiency, chronic renal failure, or breast-feeding children).
Neonates*: 1 to 2 mg/kg/dose PO once daily for patients at risk of neuropathy (e.g., persons with HIV, nutritional deficiency, or breast-feeding children).
-for isoniazid toxicity prophylaxis during daily treatment for latent tuberculosis infection (LTBI):
Oral dosage:
Adults: 25 to 50 mg PO once daily for patients at risk of neuropathy (e.g., persons with HIV, diabetes, alcoholism, nutritional deficiency, chronic renal failure, advanced age).
Infants, Children, and Adolescents: 0.5 to 2 mg/kg/dose (Max: 50 mg/dose) PO once daily for patients at risk of neuropathy (e.g., persons with HIV, diabetes, alcoholism, nutritional deficiency, chronic renal failure, or breast-feeding children).
-for isoniazid toxicity prophylaxis during weekly treatment of latent tuberculosis infection (LTBI):
Oral dosage:
Adults: 50 mg PO once weekly for patients at risk of neuropathy (e.g., persons with HIV, diabetes, alcoholism, nutritional deficiency, chronic renal failure, advanced age).
Children and Adolescents 2 to 17 years: 50 mg PO once weekly for patients at risk of neuropathy (e.g., persons with HIV, diabetes, alcoholism, nutritional deficiency, chronic renal failure, or breast-feeding children).
For penicillamine toxicity prophylaxis:
Oral dosage:
Adults: 10 to 50 mg/day PO.
Adolescents*: 25 to 100 mg/day PO.
Children*: 1 to 2 mg/kg/day PO.
For the treatment of selected metabolic disorders including primary cystathioninuria, primary homocystinuria, or xanthurenic aciduria:
Oral dosage:
Adults: 100-500 mg/day PO, or more, adjusted to clinical response.
Children: Listings in pediatric references vary. Typical doses range from 200-1000 mg/day PO, adjusted to clinical response.
For the treatment of primary hyperoxaluria* in combination with oral orthophosphate therapy:
Oral dosage:
Adults: An initial dose of 1.8 to 7 mg/kg/day (mean 3.4 mg/kg/day) PO with a final dose of 1 to 7 mg/kg/day (mean 2.9 mg/kg/day) was used in 1 study (n = 25). Five patients progressed to end-stage renal disease which occurred from 7 to 23 years after treatment began. No patient had neuropathy or other signs of pyridoxine toxicity.
Children and Adolescents: An initial dose of 1.8 to 7 mg/kg/day (mean 3.4 mg/kg/day) PO with a final dose of 1 to 7 mg/kg/day (mean 2.9 mg/kg/day) was used in 1 study (n = 25). Five patients progressed to end-stage renal disease which occurred from 7 to 23 years after treatment began. No patient had neuropathy or other signs of pyridoxine toxicity.
For the treatment of premenstrual syndrome (PMS):
Oral dosage:
Adults: Most studies have shown some benefit of pyridoxine in PMS, but some studies fail to meet methodologic standards for research of this condition. Doses have ranged from 80 to 500 mg/day PO.
For the treatment of pregnancy-induced nausea/vomiting*:
Oral dosage:
Adult pregnant females: 10 mg to 25 mg PO (taken either alone or in combination with doxylamine 12.5 mg PO), 3 or 4 times per day. Pyridoxine is a first-line pharmacologic agent in the ACOG treatment algorithm for nausea and vomiting due to pregnancy. In clinical trials, pyridoxine decreased the number of vomiting episodes and reduced nausea severity as compared with data from women who received placebo. Treatment was for 3 days in 1 study and for 5 days in the other; reassess women for continued need of pyridoxine.
Adolescent pregnant females: 10 mg to 25 mg PO (taken either alone or in combination with doxylamine 12.5 mg PO), 3 or 4 times per day. Pyridoxine is a first-line pharmacologic agent in the ACOG treatment algorithm for nausea and vomiting due to pregnancy. In clinical trials, pyridoxine decreased the number of vomiting episodes and reduced nausea severity as compared with data from women who received placebo. Treatment was for 3 days in 1 study and for 5 days in the other; reassess women for continued need of pyridoxine.
For the treatment of pyridoxine-dependent seizures*:
Intravenous dosage:
Neonates, Infants, and Children: 50 to 100 mg IV as a single dose for diagnostic purposes. If EEG and/or clinical improvement is not observed within 10 minutes, administer 100 mg IV sequentially every 5 to 10 minutes until improvement is seen. Recommended max: 500 mg total dose, however larger doses have been reported. Monitor neurologic, respiratory, and cardiovascular status carefully; resuscitative equipment should be readily available. If the patient responds to pyridoxine, it is recommended to begin a daily oral maintenance dose and discontinue other anticonvulsant medications.
Oral dosage (Diagnosis):
Neonates, Infants, Children: 50 to 100 mg PO as a single dose; response should occur within 12 hours. Alternatively, 15 to 30 mg/kg/day PO has been used with a less dramatic clinical response occurring within 3 to 7 days of implementation. While some experts use a maximum dose similar to single dose therapy (50 mg), doses as high as 1000 mg/kg/day have been described. Monitor neurologic, respiratory, and cardiovascular status carefully during administration of large doses; resuscitative equipment should be readily available. Definitive diagnosis is made when therapy discontinuation results in a reemergence of seizure activity within several days to 6 weeks, which then again responds to pyridoxine monotherapy. Although dosing is provided for the oral formulation, most experts recommend IV pyridoxine for diagnosis. If the patient responds to a diagnostic dose of pyridoxine, it is recommended to begin a daily oral maintenance dose and discontinue other anticonvulsant medications.
Oral dosage (Maintenance):
Neonates, Infants, Children: If the patient responds to a diagnostic dose of pyridoxine, it is recommended to begin a daily oral maintenance dose and discontinue other anticonvulsant medications. An initial maintenance dose of 5 mg/kg/day PO once daily or divided twice daily, titrated as needed to suppress seizure activity has been recommended. Maintenance dosing is not firmly established; some experts recommend doses up to 20 mg/kg/day with a maximum dose of 500 mg. Typically, the final dose maintains efficacy throughout childhood, without weight-adjustment for growth. Dosing requirements may transiently increase with illness.
For ethionamide toxicity prophylaxis:
Oral dosage:
Adults: 50 mg PO once daily.
Infants, Children, and Adolescents: 0.5 to 2 mg/kg/dose (Max: 50 mg/dose) PO once daily.
Maximum Dosage Limits:
NOTE: The Tolerable Upper Intake Level (UL) is defined as the highest daily intake of a nutrient that is likely to pose no risk (e.g., sensory neuropathy) in otherwise healthy individuals. The ULs are not intended to apply to individuals with specific vitamin-deficiency conditions; maximum doses for these conditions are based on indication and patient response.
-Adults
100 mg/day PO. Maximum doses have not been established for treatment of isoniazid overdose; however, doses up to and exceeding 5 g IV and PO have been recommended. Doses up to 20 g/day IV have been used for mushroom poisoning.
-Geriatric
100 mg/day PO. Maximum doses have not been established for treatment of isoniazid overdose; however, doses up to and exceeding 5 g IV and PO have been recommended. Doses up to 20 g/day IV have been used for mushroom poisoning.
-Adolescents
14 to 17 years: 80 mg/day PO is the tolerable upper intake level (UL). Maximum doses have not been established for treatment of isoniazid overdose; however, doses up to and exceeding 80 mg/kg/dose or 5 g IV and PO have been recommended. Doses up to 20 g/day IV have been used for mushroom poisoning.
13 years: 60 mg/day PO is the tolerable upper intake level (UL). Maximum doses have not been established for treatment of isoniazid overdose; however, doses up to and exceeding 80 mg/kg/dose or 5 g IV and PO have been recommended. Doses up to 20 g/day IV have been used for mushroom poisoning.
-Children
9 to 12 years: 60 mg/day PO is the tolerable upper intake level (UL). Maximum doses have not been established for treatment of isoniazid overdose; however, doses up to and exceeding 80 mg/kg/dose or 5 g IV and PO have been recommended. Doses up to 20 g/day IV have been used for mushroom poisoning.
4 to 8 years: 40 mg/day PO is the tolerable upper intake level (UL). Maximum doses have not been established for treatment of isoniazid overdose; however, doses up to and exceeding 80 mg/kg/dose IV and PO have been recommended. Doses up to 20 g/day IV have been used for mushroom poisoning.
1 to 3 years: 30 mg/day PO is the tolerable upper intake level (UL). Maximum doses have not been established for treatment of isoniazid overdose; however, doses up to and exceeding 80 mg/kg/dose IV and PO have been recommended. Doses up to 20 g/day IV have been used for mushroom poisoning.
-Infants
Tolerable upper intake level (UL) is not determinable. Maximum doses have not been established for treatment of isoniazid overdose; however, doses up to and exceeding 80 mg/kg/dose IV and PO have been recommended. Doses up to 20 g/day IV have been used for mushroom poisoning.
-Neonates
Tolerable upper intake level (UL) is not determinable. For pyridoxine-dependent seizures, a maximum diagnostic dose of 500 mg IV has been recommended; however, higher doses have been used. Dose is dependent on patient response.
Patients with Hepatic Impairment Dosing
Specific guidelines for dosage adjustments in hepatic impairment are not available; it appears that no dosage adjustments are needed.
Patients with Renal Impairment Dosing
Specific guidelines for dosage adjustments in renal impairment are not available; it appears that no dosage adjustments are needed with oral therapy. However, limit intravenous pyridoxine use as aluminum accumulation may result (see Contraindications).
*non-FDA-approved indication
Abacavir; Dolutegravir; Lamivudine: (Moderate) Administer dolutegravir 2 hours before or 6 hours after taking supplements containing calcium if given under fasting conditions. When taken with food, dolutegravir and supplements containing calcium can be taken at the same time. Simultaneous administration under fasted conditions may result in reduced bioavailability of dolutegravir.
Alendronate: (Moderate) Separate administration of alendronate and calcium-containing supplements by at least 30 minutes. Calcium will interfere with the absorption of alendronate.
Alendronate; Cholecalciferol: (Moderate) Separate administration of alendronate and calcium-containing supplements by at least 30 minutes. Calcium will interfere with the absorption of alendronate.
Aliskiren; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Amiloride; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Amlodipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Amlodipine; Atorvastatin: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Amlodipine; Benazepril: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Amlodipine; Celecoxib: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Amlodipine; Olmesartan: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Amlodipine; Valsartan: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Amlodipine; Valsartan; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium. (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Atenolol: (Minor) Calcium antacids (e.g., calcium carbonate) and supplements (e.g., other oral calcium salts) have been reported to reduce the mean peak concentrations by 51% and the AUC of atenolol by 32%. In another study, antacids reduced the AUC of atenolol by 33%. Separate doses of atenolol and calcium-containing antacids or supplements by at least 2 hours to minimize this potential interaction,. However, most clinicians consider the interaction of atenolol with antacids to be of minor clinical significance, since clinical efficacy (heart rate and blood pressure parameters) appear to be unchanged under usual intermittent clinical use.
Atenolol; Chlorthalidone: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium. (Minor) Calcium antacids (e.g., calcium carbonate) and supplements (e.g., other oral calcium salts) have been reported to reduce the mean peak concentrations by 51% and the AUC of atenolol by 32%. In another study, antacids reduced the AUC of atenolol by 33%. Separate doses of atenolol and calcium-containing antacids or supplements by at least 2 hours to minimize this potential interaction,. However, most clinicians consider the interaction of atenolol with antacids to be of minor clinical significance, since clinical efficacy (heart rate and blood pressure parameters) appear to be unchanged under usual intermittent clinical use.
Atracurium: (Moderate) Concomitant use of neuromuscular blockers and calcium may result in resistance to neuromuscular blockade. Calcium antagonizes the potentiating effect of magnesium on neuromuscular blockade. Also, calcium triggers acetylcholine release, and therefore, may both reduce the sensitivity to neuromuscular blockers and decrease the duration of neuromuscular blockade.
Azilsartan; Chlorthalidone: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Baloxavir Marboxil: (Major) Do not administer baloxavir with products that contain calcium. Polyvalent cations, such as calcium, can chelate with baloxavir, reducing its absorption.
Benazepril; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Bictegravir; Emtricitabine; Tenofovir Alafenamide: (Moderate) Administer bictegravir with food at the same time as oral calcium supplements. Routine administration of bictegravir under fasting conditions simultaneously with, or 2 hours after, calcium supplements is not recommended. Calcium is a polyvalent cation that can bind bictegravir in the GI tract. Taking these drugs simultaneously without food results in reduced bioavailability of bictegravir. In drug interaction studies, simultaneous administration of bictegravir with another calcium supplement under fasted conditions decreased the mean AUC of bictegravir by approximately 33%.
Bismuth Subcitrate Potassium; Metronidazole; Tetracycline: (Moderate) Divalent or trivalent cations readily chelate with tetracycline antibiotics, forming insoluble compounds. The oral absorption of these antibiotics will be significantly reduced by other orally administered compounds that contain calcium salts, particularly if the time of administration is within 60 minutes of each other. Calcium salts and tetracyclines should not be administered within 1 to 2 hours of each other, although doxycycline chelates less with calcium than other tetracyclines.
Bismuth Subsalicylate; Metronidazole; Tetracycline: (Moderate) Divalent or trivalent cations readily chelate with tetracycline antibiotics, forming insoluble compounds. The oral absorption of these antibiotics will be significantly reduced by other orally administered compounds that contain calcium salts, particularly if the time of administration is within 60 minutes of each other. Calcium salts and tetracyclines should not be administered within 1 to 2 hours of each other, although doxycycline chelates less with calcium than other tetracyclines.
Bisoprolol; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Cabotegravir: (Moderate) Administer oral calcium at least two hours before or four hours after taking oral cabotegravir. Calcium is a polyvalent cation that can bind cabotegravir in the GI tract. Taking these drugs simultaneously may result in reduced oral bioavailability of cabotegravir.
Cabotegravir; Rilpivirine: (Moderate) Administer oral calcium at least two hours before or four hours after taking oral cabotegravir. Calcium is a polyvalent cation that can bind cabotegravir in the GI tract. Taking these drugs simultaneously may result in reduced oral bioavailability of cabotegravir.
Calcifediol: (Moderate) Monitor serum calcium concentrations during concomitant use of high doses of calcium and vitamin D analogs; a dosage adjustment of the vitamin D analog may be needed. Hypercalcemia may be exacerbated by concomitant administration.
Calcipotriene: (Minor) There is evidence that calcipotriene can be absorbed in amounts that are sufficient to produce systemic effects, including elevated serum calcium; hypercalcemia has been observed in normal prescription use. Use calcipotriene cautiously with other agents that can produce hypercalcemia (e.g., calcium salts or supplements including calcium carbonate).
Calcipotriene; Betamethasone: (Minor) There is evidence that calcipotriene can be absorbed in amounts that are sufficient to produce systemic effects, including elevated serum calcium; hypercalcemia has been observed in normal prescription use. Use calcipotriene cautiously with other agents that can produce hypercalcemia (e.g., calcium salts or supplements including calcium carbonate).
Calcitonin: (Moderate) Calcitonin is given to hypercalcemic patients to reduce serum calcium concentrations. For the treatment of hypercalcemia, calcium supplements should be avoided. Calcium salts, including calcium carbonate, can elevate serum calcium concentrations and antagonize the effects of the calcitonin for this condition. For the treatment of osteoporosis adequate intake of calcium salts are necessary in conjunction with calcitonin. An increase in serum calcium concentrations helps to reduce bone resorption and loss of bone mass, and offsets the effect of calcitonin in lowering serum calcium levels.
Calcitriol: (Moderate) Monitor serum calcium concentrations during concomitant use of high doses of calcium and vitamin D analogs; a dosage adjustment of the vitamin D analog may be needed. Hypercalcemia may be exacerbated by concomitant administration.
Calcium Phosphate, Supersaturated: (Moderate) The concomitant use of oral sodium phosphate monobasic monohydrate; sodium phosphate dibasic anhydrous preparations in conjunction with antacids containing calcium (e.g., calcium carbonate, calcium salts) may bind the phosphate in the stomach and reduce its absorption. If the patient requires multiple mineral supplements or concurrent use of antacids, it is prudent to separate the administration of sodium phosphate salts from calcium containing products by at least one hour.
Calcium-channel blockers: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Candesartan; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Captopril; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Carbidopa; Levodopa: (Moderate) Monitor for reduced levodopa efficacy during concomitant use of pyridoxine (vitamin B6). Pyridoxine, in doses as low as 10 mg/day, may reverse the effects of levodopa by increasing the rate of aromatic amino acid decarboxylation. Carbidopa inhibits this action of pyridoxine.
Carbidopa; Levodopa; Entacapone: (Moderate) Monitor for reduced levodopa efficacy during concomitant use of pyridoxine (vitamin B6). Pyridoxine, in doses as low as 10 mg/day, may reverse the effects of levodopa by increasing the rate of aromatic amino acid decarboxylation. Carbidopa inhibits this action of pyridoxine.
Cardiac glycosides: (Moderate) Monitor for signs and symptoms of digoxin toxicity during concomitant calcium use. Hypercalcemia may predispose persons to digoxin toxicity. If IV calcium is administered rapidly in a person receiving digoxin, serious arrhythmias may occur. Monitor ECG and calcium concentrations closely during IV calcium and digoxin administration.
Chlorothiazide: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Chlorthalidone: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Ciprofloxacin: (Moderate) Administer oral ciprofloxacin at least 2 hours before or 6 hours after oral products that contain calcium. Ciprofloxacin absorption may be reduced as quinolone antibiotics can chelate with divalent or trivalent cations. Examples of compounds that may interfere with quinolone bioavailability include antacids and multivitamins that contain calcium.
Cisatracurium: (Moderate) Concomitant use of neuromuscular blockers and calcium may result in resistance to neuromuscular blockade. Calcium antagonizes the potentiating effect of magnesium on neuromuscular blockade. Also, calcium triggers acetylcholine release, and therefore, may both reduce the sensitivity to neuromuscular blockers and decrease the duration of neuromuscular blockade.
Clevidipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Cod Liver Oil: (Minor) Doses in excess of 1,500 to 2,000 mcg per day of Vitamin A may lead to bone loss and will counteract the effects of supplementation with calcium salts.
Colesevelam: (Moderate) It is not known if colesevelam can reduce the absorption of oral vitamin supplements including fat soluble vitamins A, D, E, and K. To minimize potential interactions, administer vitamins at least 4 hours before colesevelam.
Conjugated Estrogens: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Conjugated Estrogens; Bazedoxifene: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Conjugated Estrogens; Medroxyprogesterone: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Cycloserine: (Moderate) Cycloserine can either interfere with the actions of pyridoxine, vitamin B6 or increase its clearance, which may result in a secondary niacin deficiency. It may be necessary to administer pyridoxine to patients receiving prolonged therapy with cycloserine to prevent the development of anemia or peripheral neuritis.
Delafloxacin: (Major) Administer oral delafloxacin at least 2 hours before or 6 hours after oral products that contain calcium. Delafloxacin absorption may be reduced as quinolone antibiotics can chelate with divalent or trivalent cations. Examples of compounds that may interfere with fluoroquinolone bioavailability include antacids and multivitamins that contain calcium.
Demeclocycline: (Moderate) Divalent or trivalent cations readily chelate with tetracycline antibiotics, forming insoluble compounds. The oral absorption of these antibiotics will be significantly reduced by other orally administered compounds that contain calcium salts, particularly if the time of administration is within 60 minutes of each other. Calcium salts and tetracyclines should not be administered within 1 to 2 hours of each other, although doxycycline chelates less with calcium than other tetracyclines.
Desogestrel; Ethinyl Estradiol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Dichlorphenamide: (Moderate) Use dichlorphenamide and pyridoxine, vitamin B6 together with caution. Metabolic acidosis is associated with the use of dichlorphenamide and has been reported with the rapid infusion of large pyridoxine doses. Concurrent use may increase the severity of metabolic acidosis. Measure sodium bicarbonate concentrations at baseline and periodically during dichlorphenamide treatment. If metabolic acidosis occurs or persists, consider reducing the dose or discontinuing dichlorphenamide therapy.
Dienogest; Estradiol valerate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Digoxin: (Moderate) Monitor for signs and symptoms of digoxin toxicity during concomitant calcium use. Hypercalcemia may predispose persons to digoxin toxicity. If IV calcium is administered rapidly in a person receiving digoxin, serious arrhythmias may occur. Monitor ECG and calcium concentrations closely during IV calcium and digoxin administration.
Diltiazem: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Dolutegravir: (Moderate) Administer dolutegravir 2 hours before or 6 hours after taking supplements containing calcium if given under fasting conditions. When taken with food, dolutegravir and supplements containing calcium can be taken at the same time. Simultaneous administration under fasted conditions may result in reduced bioavailability of dolutegravir.
Dolutegravir; Lamivudine: (Moderate) Administer dolutegravir 2 hours before or 6 hours after taking supplements containing calcium if given under fasting conditions. When taken with food, dolutegravir and supplements containing calcium can be taken at the same time. Simultaneous administration under fasted conditions may result in reduced bioavailability of dolutegravir.
Dolutegravir; Rilpivirine: (Moderate) Administer dolutegravir 2 hours before or 6 hours after taking supplements containing calcium if given under fasting conditions. When taken with food, dolutegravir and supplements containing calcium can be taken at the same time. Simultaneous administration under fasted conditions may result in reduced bioavailability of dolutegravir.
Doxercalciferol: (Moderate) Monitor serum calcium concentrations during concomitant use of high doses of calcium and vitamin D analogs; a dosage adjustment of the vitamin D analog may be needed. Hypercalcemia may be exacerbated by concomitant administration.
Doxycycline: (Moderate) Divalent or trivalent cations readily chelate with tetracycline antibiotics, forming insoluble compounds. The oral absorption of these antibiotics will be significantly reduced by other orally administered compounds that contain calcium salts, particularly if the time of administration is within 60 minutes of each other. Calcium salts and tetracyclines should not be administered within 1 to 2 hours of each other, although doxycycline chelates less with calcium than other tetracyclines.
Drospirenone; Estetrol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Drospirenone; Estradiol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Drospirenone; Ethinyl Estradiol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Drospirenone; Ethinyl Estradiol; Levomefolate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Edetate Calcium Disodium, Calcium EDTA: (Major) Because edetate disodium chelates and lowers serum calcium, oral or parenteral calcium salts should not be administered concomitantly.
Elagolix; Estradiol; Norethindrone acetate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Eltrombopag: (Major) Eltrombopag chelates polyvalent cations (e.g., calcium, aluminum, and magnesium) in food, mineral supplements, and antacids. In a clinical study, systemic exposure to eltrombopag was decreased by 70% when it was administered with a polyvalent cation-containing antacid. Administer eltrombopag at least 2 hours before or 4 hours after any oral products containing polyvalent cations, such as aluminum salts, (like aluminum hydroxide), calcium salts, (including calcium carbonate), and magnesium salts.
Elvitegravir; Cobicistat; Emtricitabine; Tenofovir Alafenamide: (Moderate) Separate administration of elvitegravir and calcium by at least 2 hours. Due to the formation of ionic complexes in the gastrointestinal tract, simultaneous administration results in lower elvitegravir plasma concentrations.
Elvitegravir; Cobicistat; Emtricitabine; Tenofovir Disoproxil Fumarate: (Moderate) Separate administration of elvitegravir and calcium by at least 2 hours. Due to the formation of ionic complexes in the gastrointestinal tract, simultaneous administration results in lower elvitegravir plasma concentrations.
Enalapril; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Eprosartan; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Esterified Estrogens: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Esterified Estrogens; Methyltestosterone: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Estradiol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Estradiol; Levonorgestrel: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Estradiol; Norethindrone: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Estradiol; Norgestimate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Estradiol; Progesterone: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Estramustine: (Major) Administration of estramustine with calcium impairs the oral absorption of estramustine significantly, due to formation of a calcium-phosphate complex. Calcium-containing drugs must not be taken simultaneously with estramustine. Patients should be instructed to take estramustine with water at least 1 hour before or 2 hours after calcium supplements.
Estrogens: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Estropipate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Ethinyl Estradiol; Norelgestromin: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Ethinyl Estradiol; Norethindrone Acetate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Ethinyl Estradiol; Norgestrel: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Ethotoin: (Major) Oral absorption of phenytoin can be reduced by calcium salts. Calcium salts can form complexes that are nonabsorbable. Separating the administration of phenytoin and calcium salts by at least 2 hours to help avoid this interaction. A similar interaction may occur with ethotoin.
Ethynodiol Diacetate; Ethinyl Estradiol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Etidronate: (Moderate) Separate administration of oral etidronate and calcium-containing supplements by at least 2 hours. Calcium will interfere with the absorption of oral etidronate.
Etonogestrel; Ethinyl Estradiol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Felodipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Fosinopril; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Fosphenytoin: (Minor) In a limited case report, the administration of pyridoxine, vitamin B6 (range of 80 to 400 mg PO) once daily for 2-4 weeks, resulted in approximate 35% (range 17 to 70%) reductions in serum phenytoin concentrations. The authors postulated that pyridoxine increased the metabolism of phenytoin anticonvulsants. The evidence for the interaction is limited, and there is no data to suggest that lower supplemental doses would result in alterations in the pharmacokinetics of phenytoin or fosphenytoin. The clinical significance of this potential interaction is questionable. If a patient is using large doses of pyridoxine, then the clinician should be alert to possible alterations.
Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Hydrochlorothiazide, HCTZ; Moexipril: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Ibandronate: (Moderate) Separate administration of oral ibandronate and calcium-containing supplements by at least 1 hour. Calcium will interfere with the absorption of oral ibandronate.
Ibritumomab Tiuxetan: (Moderate) The oral absorption of phosphorus is reduced by ingestion of pharmacologic doses of calcium carbonate or other phosphate-lowering calcium salts (e.g., calcium acetate). There is, however, no significant interference with phosphorus absorption by oral dietary calcium at intakes within the typical adult range. If the patient requires multiple calcium supplements or a calcium-containing antacid, it may be wise to separate the administration of phosphorus salts from calcium-containing products. In some instances the administration of calcium salts or calcium carbonate is used therapeutically (e.g., uremia) to decrease serum phosphorus levels, so the administration of phosphorus supplements would dynamically counteract the intended use of calcium in these settings, assuming hypophosphatemia is not present. Appropriate calcium-phosphorus ratios in vivo are important for proper calcium homeostasis in tissues and bone; if the serum ionized calcium concentration is elevated, the concomitant use of calcium salts and phosphorus salts may increase the risk of calcium deposition in soft tissue.
Irbesartan; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Isradipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Levamlodipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Levodopa: (Moderate) Monitor for reduced levodopa efficacy during concomitant use of pyridoxine (vitamin B6). Pyridoxine, in doses as low as 10 mg/day, may reverse the effects of levodopa by increasing the rate of aromatic amino acid decarboxylation. Carbidopa inhibits this action of pyridoxine.
Levofloxacin: (Moderate) Administer oral products that contain calcium at least 2 hours before or 2 hours after orally administered levofloxacin. Levofloxacin absorption may be reduced as quinolone antibiotics can chelate with divalent or trivalent cations. Chelation of divalent cations with levofloxacin is less than with other quinolones. Examples of compounds that may interfere with quinolone bioavailability include antacids and multivitamins that contain calcium.
Levonorgestrel; Ethinyl Estradiol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Levonorgestrel; Ethinyl Estradiol; Ferrous Bisglycinate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Levonorgestrel; Ethinyl Estradiol; Ferrous Fumarate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Levothyroxine: (Moderate) Thyroid hormones should be administered at least 4 hours before or after the ingestion of oral calcium supplements. Calcium salts have been reported to chelate oral thyroid hormones within the GI tract when administered simultaneously, leading to decreased thyroid hormone absorption. Some case reports have described clinical hypothyroidism resulting from coadministration of thyroid hormones with oral calcium supplements.
Levothyroxine; Liothyronine (Porcine): (Moderate) Thyroid hormones should be administered at least 4 hours before or after the ingestion of oral calcium supplements. Calcium salts have been reported to chelate oral thyroid hormones within the GI tract when administered simultaneously, leading to decreased thyroid hormone absorption. Some case reports have described clinical hypothyroidism resulting from coadministration of thyroid hormones with oral calcium supplements.
Levothyroxine; Liothyronine (Synthetic): (Moderate) Thyroid hormones should be administered at least 4 hours before or after the ingestion of oral calcium supplements. Calcium salts have been reported to chelate oral thyroid hormones within the GI tract when administered simultaneously, leading to decreased thyroid hormone absorption. Some case reports have described clinical hypothyroidism resulting from coadministration of thyroid hormones with oral calcium supplements.
Liothyronine: (Moderate) Thyroid hormones should be administered at least 4 hours before or after the ingestion of oral calcium supplements. Calcium salts have been reported to chelate oral thyroid hormones within the GI tract when administered simultaneously, leading to decreased thyroid hormone absorption. Some case reports have described clinical hypothyroidism resulting from coadministration of thyroid hormones with oral calcium supplements.
Lisinopril; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Lithium: (Moderate) Monitor serum calcium concentrations closely if concomitant use of calcium and lithium is necessary. Concomitant use may increase the risk of hypercalcemia.
Losartan; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Metolazone: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Metoprolol; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Minocycline: (Moderate) Divalent or trivalent cations readily chelate with tetracycline antibiotics, forming insoluble compounds. The oral absorption of these antibiotics will be significantly reduced by other orally administered compounds that contain calcium salts, particularly if the time of administration is within 60 minutes of each other. Calcium salts and tetracyclines should not be administered within 1 to 2 hours of each other, although doxycycline chelates less with calcium than other tetracyclines.
Moxifloxacin: (Major) Administer oral moxifloxacin at least 4 hours before or 8 hours after oral products that contain calcium. Moxifloxacin absorption may be reduced as quinolone antibiotics can chelate with divalent or trivalent cations. Examples of compounds that may interfere with quinolone bioavailability include antacids and multivitamins that contain calcium.
Neuromuscular blockers: (Moderate) Concomitant use of neuromuscular blockers and calcium may result in resistance to neuromuscular blockade. Calcium antagonizes the potentiating effect of magnesium on neuromuscular blockade. Also, calcium triggers acetylcholine release, and therefore, may both reduce the sensitivity to neuromuscular blockers and decrease the duration of neuromuscular blockade.
Nicardipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
NIFEdipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Nimodipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Nisoldipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Norethindrone Acetate; Ethinyl Estradiol; Ferrous fumarate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Norethindrone; Ethinyl Estradiol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Norethindrone; Ethinyl Estradiol; Ferrous fumarate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Norgestimate; Ethinyl Estradiol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Ofloxacin: (Moderate) Administer oral products that contain calcium at least 2 hours before or 2 hours after ofloxacin. Ofloxacin absorption may be reduced as quinolone antibiotics can chelate with divalent or trivalent cations. Examples of compounds that may interfere with quinolone bioavailability include antacids and multivitamins that contain calcium.
Olmesartan; Amlodipine; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium. (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Olmesartan; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Omadacycline: (Moderate) Divalent or trivalent cations readily chelate with tetracycline antibiotics, forming insoluble compounds. The oral absorption of these antibiotics will be significantly reduced by other orally administered compounds that contain calcium salts, particularly if the time of administration is within 60 minutes of each other. Calcium salts and tetracyclines should not be administered within 1 to 2 hours of each other, although doxycycline chelates less with calcium than other tetracyclines.
Pancuronium: (Moderate) Concomitant use of neuromuscular blockers and calcium may result in resistance to neuromuscular blockade. Calcium antagonizes the potentiating effect of magnesium on neuromuscular blockade. Also, calcium triggers acetylcholine release, and therefore, may both reduce the sensitivity to neuromuscular blockers and decrease the duration of neuromuscular blockade.
Parathyroid Hormone: (Moderate) Monitor serum calcium concentrations closely if concomitant use of calcium and parathyroid hormone is necessary. Concomitant use may increase the risk of hypercalcemia.
Paricalcitol: (Moderate) Monitor serum calcium concentrations during concomitant use of high doses of calcium and vitamin D analogs; a dosage adjustment of the vitamin D analog may be needed. Hypercalcemia may be exacerbated by concomitant administration.
Penicillamine: (Moderate) Pyridoxine, vitamin B6 excretion can be increased during the administration of penicillamine, possibly causing anemia or peripheral neuritis. Pyridoxine dosages may need to be increased during concomitant administration of penicillamine.
Perindopril; Amlodipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Phenobarbital: (Minor) In a limited case report, the administration of pyridoxine, vitamin B6 (200 mg once daily x 4 weeks) resulted in reduced serum phenobarbital concentrations in 5 patients with epilepsy; the reductions approached 50%. The evidence for the interaction is limited, and there is no data to suggest that lower supplemental doses would result in alterations in the pharmacokinetics of phenobarbital. The clinical significance of this potential interaction is questionable. If a patient is using large doses of pyridoxine, then the clinician should be alert to possible alterations.
Phenobarbital; Hyoscyamine; Atropine; Scopolamine: (Minor) In a limited case report, the administration of pyridoxine, vitamin B6 (200 mg once daily x 4 weeks) resulted in reduced serum phenobarbital concentrations in 5 patients with epilepsy; the reductions approached 50%. The evidence for the interaction is limited, and there is no data to suggest that lower supplemental doses would result in alterations in the pharmacokinetics of phenobarbital. The clinical significance of this potential interaction is questionable. If a patient is using large doses of pyridoxine, then the clinician should be alert to possible alterations.
Phenytoin: (Minor) Limited data suggests that large doses (greater than 80 mg per day) of pyridoxine, vitamin B6 may result in reduced serum phenytoin concentrations. Regular doses, such as in multivitamins, probably will have little effect. Monitor for reduced serum phenytoin concentrations or changes in seizure control if large doses of pyridoxine, vitamin B6 are coadminsitered.
Phosphorated Carbohydrate Solution: (Moderate) The oral absorption of phosphorus is reduced by ingestion of pharmacologic doses of calcium carbonate or other phosphate-lowering calcium salts (e.g., calcium acetate). There is, however, no significant interference with phosphorus absorption by oral dietary calcium at intakes within the typical adult range. If the patient requires multiple calcium supplements or a calcium-containing antacid, it may be wise to separate the administration of phosphorus salts from calcium-containing products. In some instances the administration of calcium salts or calcium carbonate is used therapeutically (e.g., uremia) to decrease serum phosphorus levels, so the administration of phosphorus supplements would dynamically counteract the intended use of calcium in these settings, assuming hypophosphatemia is not present. Appropriate calcium-phosphorus ratios in vivo are important for proper calcium homeostasis in tissues and bone; if the serum ionized calcium concentration is elevated, the concomitant use of calcium salts and phosphorus salts may increase the risk of calcium deposition in soft tissue.
Phosphorus: (Moderate) The oral absorption of phosphorus is reduced by ingestion of pharmacologic doses of calcium carbonate or other phosphate-lowering calcium salts (e.g., calcium acetate). There is, however, no significant interference with phosphorus absorption by oral dietary calcium at intakes within the typical adult range. If the patient requires multiple calcium supplements or a calcium-containing antacid, it may be wise to separate the administration of phosphorus salts from calcium-containing products. In some instances the administration of calcium salts or calcium carbonate is used therapeutically (e.g., uremia) to decrease serum phosphorus levels, so the administration of phosphorus supplements would dynamically counteract the intended use of calcium in these settings, assuming hypophosphatemia is not present. Appropriate calcium-phosphorus ratios in vivo are important for proper calcium homeostasis in tissues and bone; if the serum ionized calcium concentration is elevated, the concomitant use of calcium salts and phosphorus salts may increase the risk of calcium deposition in soft tissue.
Potassium Phosphate: (Moderate) The oral absorption of phosphorus is reduced by ingestion of pharmacologic doses of calcium carbonate or other phosphate-lowering calcium salts (e.g., calcium acetate). There is, however, no significant interference with phosphorus absorption by oral dietary calcium at intakes within the typical adult range. If the patient requires multiple calcium supplements or a calcium-containing antacid, it may be wise to separate the administration of phosphorus salts from calcium-containing products. In some instances the administration of calcium salts or calcium carbonate is used therapeutically (e.g., uremia) to decrease serum phosphorus levels, so the administration of phosphorus supplements would dynamically counteract the intended use of calcium in these settings, assuming hypophosphatemia is not present. Appropriate calcium-phosphorus ratios in vivo are important for proper calcium homeostasis in tissues and bone; if the serum ionized calcium concentration is elevated, the concomitant use of calcium salts and phosphorus salts may increase the risk of calcium deposition in soft tissue.
Potassium Phosphate; Sodium Phosphate: (Moderate) The oral absorption of phosphorus is reduced by ingestion of pharmacologic doses of calcium carbonate or other phosphate-lowering calcium salts (e.g., calcium acetate). There is, however, no significant interference with phosphorus absorption by oral dietary calcium at intakes within the typical adult range. If the patient requires multiple calcium supplements or a calcium-containing antacid, it may be wise to separate the administration of phosphorus salts from calcium-containing products. In some instances the administration of calcium salts or calcium carbonate is used therapeutically (e.g., uremia) to decrease serum phosphorus levels, so the administration of phosphorus supplements would dynamically counteract the intended use of calcium in these settings, assuming hypophosphatemia is not present. Appropriate calcium-phosphorus ratios in vivo are important for proper calcium homeostasis in tissues and bone; if the serum ionized calcium concentration is elevated, the concomitant use of calcium salts and phosphorus salts may increase the risk of calcium deposition in soft tissue.
Quinapril; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Relugolix; Estradiol; Norethindrone acetate: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Risedronate: (Moderate) Separate administration of oral risedronate and calcium-containing supplements by at least 2 hours. Calcium will interfere with the absorption of oral risedronate.
Rocuronium: (Moderate) Concomitant use of neuromuscular blockers and calcium may result in resistance to neuromuscular blockade. Calcium antagonizes the potentiating effect of magnesium on neuromuscular blockade. Also, calcium triggers acetylcholine release, and therefore, may both reduce the sensitivity to neuromuscular blockers and decrease the duration of neuromuscular blockade.
Sarecycline: (Moderate) Divalent or trivalent cations readily chelate with tetracycline antibiotics, forming insoluble compounds. The oral absorption of these antibiotics will be significantly reduced by other orally administered compounds that contain calcium salts, particularly if the time of administration is within 60 minutes of each other. Calcium salts and tetracyclines should not be administered within 1 to 2 hours of each other, although doxycycline chelates less with calcium than other tetracyclines.
Segesterone Acetate; Ethinyl Estradiol: (Minor) Estrogens can increase calcium absorption. Use caution in patients predisposed to hypercalcemia or nephrolithiasis.
Sodium Fluoride: (Moderate) Absorption of sodium fluoride may be reduced by concomitant use of antacids that contain magnesium, aluminum, or calcium. An interval of at least 2 hours is advisable between administration of sodium fluoride and antacids.
Sodium Phosphate Monobasic Monohydrate; Sodium Phosphate Dibasic Anhydrous: (Moderate) The concomitant use of oral sodium phosphate monobasic monohydrate; sodium phosphate dibasic anhydrous preparations in conjunction with antacids containing calcium (e.g., calcium carbonate, calcium salts) may bind the phosphate in the stomach and reduce its absorption. If the patient requires multiple mineral supplements or concurrent use of antacids, it is prudent to separate the administration of sodium phosphate salts from calcium containing products by at least one hour.
Spironolactone; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Succinylcholine: (Moderate) Concomitant use of neuromuscular blockers and calcium may result in resistance to neuromuscular blockade. Calcium antagonizes the potentiating effect of magnesium on neuromuscular blockade. Also, calcium triggers acetylcholine release, and therefore, may both reduce the sensitivity to neuromuscular blockers and decrease the duration of neuromuscular blockade.
Sulfacetamide; Sulfur: (Major) Because edetate disodium chelates and lowers serum calcium, oral or parenteral calcium salts should not be administered concomitantly.
Telmisartan; Amlodipine: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Telmisartan; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Teriparatide: (Moderate) Monitor serum calcium concentrations closely if concomitant use of calcium and teriparatide is necessary. Concomitant use may increase the risk of hypercalcemia.
Tetracycline: (Moderate) Divalent or trivalent cations readily chelate with tetracycline antibiotics, forming insoluble compounds. The oral absorption of these antibiotics will be significantly reduced by other orally administered compounds that contain calcium salts, particularly if the time of administration is within 60 minutes of each other. Calcium salts and tetracyclines should not be administered within 1 to 2 hours of each other, although doxycycline chelates less with calcium than other tetracyclines.
Tetracyclines: (Moderate) Divalent or trivalent cations readily chelate with tetracycline antibiotics, forming insoluble compounds. The oral absorption of these antibiotics will be significantly reduced by other orally administered compounds that contain calcium salts, particularly if the time of administration is within 60 minutes of each other. Calcium salts and tetracyclines should not be administered within 1 to 2 hours of each other, although doxycycline chelates less with calcium than other tetracyclines.
Thiazide diuretics: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Thyroid hormones: (Moderate) Thyroid hormones should be administered at least 4 hours before or after the ingestion of oral calcium supplements. Calcium salts have been reported to chelate oral thyroid hormones within the GI tract when administered simultaneously, leading to decreased thyroid hormone absorption. Some case reports have described clinical hypothyroidism resulting from coadministration of thyroid hormones with oral calcium supplements.
Trandolapril; Verapamil: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Triamterene; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Trientine: (Major) In general, oral mineral supplements should not be given since they may block the oral absorption of trientine. However, iron deficiency may develop, especially in children and menstruating or pregnant women, or as a result of the low copper diet recommended for Wilson's disease. If necessary, iron may be given in short courses, but since iron and trientine each inhibit oral absorption of the other, 2 hours should elapse between administration of trientine and iron doses.
Valsartan; Hydrochlorothiazide, HCTZ: (Moderate) Monitor serum calcium concentration during concomitant calcium and thiazide diuretic use due to the risk for hypercalcemia. Thiazide diuretics may decrease urinary calcium excretion and cause intermittent and slight increases in serum calcium.
Vecuronium: (Moderate) Concomitant use of neuromuscular blockers and calcium may result in resistance to neuromuscular blockade. Calcium antagonizes the potentiating effect of magnesium on neuromuscular blockade. Also, calcium triggers acetylcholine release, and therefore, may both reduce the sensitivity to neuromuscular blockers and decrease the duration of neuromuscular blockade.
Verapamil: (Minor) Monitor blood pressure during concurrent use of calcium and calcium-channel blockers. Concomitant use may reduce the response to calcium-channel blockers.
Vitamin A: (Minor) Doses in excess of 1,500 to 2,000 mcg per day of Vitamin A may lead to bone loss and will counteract the effects of supplementation with calcium salts.
Vitamin D analogs: (Moderate) Monitor serum calcium concentrations during concomitant use of high doses of calcium and vitamin D analogs; a dosage adjustment of the vitamin D analog may be needed. Hypercalcemia may be exacerbated by concomitant administration.
Vitamin B6 is composed of pyridoxine, pyridoxal, and pyridoxamine, and food usually contains all three forms. Pyridoxine is converted in erythrocytes to its active moiety, pyridoxal phosphate (requiring riboflavin for the conversion), while pyridoxamine is converted into pyridoxamine phosphate. These active forms act as coenzymes for no fewer than 60 metabolic processes including the metabolism of fat, protein, and carbohydrate. Their role in protein metabolism includes decarboxylation of amino acids, conversion of tryptophan to niacin or serotonin, deamination, and transamination of amino acids. In carbohydrate metabolism, it is necessary for the conversion of glycogen to glucose-1-phosphate. Pyridoxine is essential for synthesis of gamma aminobutyric acid (GABA) in the CNS and synthesis of heme.
Pyridoxine is administered orally and by intramuscular or intravenous injection. Vitamin B6 is stored in the liver, with small amounts in the brain and muscles. The total body storage for adults is between 16 to 27 mg. Pyridoxal crosses the placenta, with fetal concentrations five times that of maternal plasma concentrations. Pyridoxal and pyridoxal phosphate are the primary forms of vitamin B6 in the blood. Pyridoxal phosphate is 100% protein-bound. The half-life of pyridoxine is 15 to 20 days. Conversion of pyridoxine to pyridoxal phosphate and pyridoxamine to pyridoxamine phosphate takes place in erythrocytes. Pyridoxine is also phosphorylated in the liver. Pyridoxal is oxidized in the liver to produce 4-pyridoxic acid, which is excreted in the urine.
-Route-Specific Pharmacokinetics
Oral Route
Absorption of pyridoxine is rapid following oral administration. The extent of absorption is decreased following gastric resection or in patients with malabsorption syndromes.
Intravenous Route
After intravenous infusion of pyridoxine 100 mg over six hours in adult patients, pyridoxal phosphate (PLP) plasma and erythrocyte concentrations increased rapidly from 37 nmol/L to 2183 nmol/L in the plasma and undetectable to 5593 nmol/L in erythrocytes. Peak concentrations were achieved at the end of the infusion.