Pharmacokinetics of Pantoprazole and CYP2C19 Activity in Children and Adolescents With GERD: A Pilot Study

Phase 1

Completed

Conditions: Obesity
GERD

Interventions: Drug: Pantoprazole

Registration Number: NCT01887743

Lead Sponsor: Children's Mercy Hospital Kansas City

Brief Summary: The World Health Organization has declared childhood obesity to be "one of the most serious public health challenges of the 21st century," (http://www.who.int/dietphysicalactivity/childhood). Given that obese children are generally excluded from clinical trials, little to no information exists regarding the impact of obesity on drug disposition and drug action, creating a gap in physicians' knowledge on how to appropriately select the dose of many critical medications (e.g., anticancer agents), so as to prevent toxicity associated with overdosing, while avoiding the harms of under-treatment. The proposed study will examine the effect of obesity on the metabolism of a commonly used medication, the proton pump inhibitor pantoprazole, by exploring the relationships between age, obesity, basal metabolic rate and genetic control of the enzyme primarily responsible for pantoprazole metabolism. We will also validate a simple breath test that can be used to predict pantoprazole dose requirement for obese children.

The study is designed to test the following experimental hypotheses:\[13C\]-pantoprazole pharmacokinetic parameters are not different between non-obese and obese children and adolescents, collectively (both age groups combined) or stratified by age group (SA 1) \[13C\]-pantoprazole pharmacokinetic parameters or DOB values (and thus, CYP2C19 activity) are not different between males and females (SA 1 \& 2) \[13C\]-pantoprazole pharmacokinetic parameters and DOB (Delta over baseline) values (and thus, CYP2C19 activity) are independent of age over the age range of 6 to 17 years (SA 1 \& 2) Obesity does not alter the relative contributions of CYP2C19-dependent and non-CYP2C19-dependent (i.e., CYP3A4) metabolism of pantoprazole, as measured by the urinary ratio of 4-hydroxy-pantoprazole to pantoprazole sulfone (SA 1 \& 2) The \[13C\]-pantoprazole breath test, by determining DOB at discrete time point(s), is a non-invasive measure of CYP2C19 phenotype (SA 2) Clearance of pantoprazole (surrogate for CYP2C19 activity) is a function of REE in obese and non-obese children and adolescents (SA 3) Pantoprazole clearance (surrogate for CYP2C19 activity) is associated with fat distribution, as determined by waist-to-hip ratios (SA 3)

Detailed Description: As the pediatric obesity epidemic continues to rise, obesity-associated pathologic conditions, such as type II diabetes, hypertension and gastroesophageal reflux disease (GERD), become more prevalent, which, in turn, creates a need for a better understanding of the impact of obesity on drug disposition and response in pediatric patients with obesity. The following proposal is designed to address the hypothesis that obesity per se has significant effects on the pharmacokinetics of CYP2C19 substrates in children and adolescents. Pantoprazole, a proton pump inhibitor (PPI) frequently used in the treatment of GERD and related conditions, is ideally suited for such a study, given the predominant role of CYP2C19(Cytochrome P450 subtype 2C19) in its metabolism and its favorable safety and efficacy profile in pediatric medicine. The study of obesity on the activity of CYP2C19 is relevant, as it has not been previously studied in pediatrics and the enzyme catalyzes the biotransformation of over 20 drugs frequently used in pediatrics (eg., PPIs, selective serotonin re-uptake inhibitors). Moreover, knowledge of the CYP2C19 genotype and phenotype can be used to individualize drug treatment, making treatment safer and more effective for children. The primary objective of the proposed investigation is to evaluate the effect of obesity on the pharmacokinetics of pantoprazole in children and adolescents. The secondary objective is to assess the utility of the \[13C\]-pantoprazole breath test, a novel, non-invasive, in-vivo technique, as a surrogate biomarker of CYP2C19 activity in pediatric patients. In addition, the impact of non-genetic variables, such as resting energy expenditure (REE), on CYP2C19 activity will be investigated. The proposed research objectives will be achieved by administration of a single dose of oral \[13C\]-pantoprazole, a safe and stable non-radioactive isotope, to 100 patients (both male and female), including 50 obese (as defined by BMI \>95th percentile) and 50 non-obese patients, between the ages of 6-17 years. Breath samples will be collected before, and for 8 hours after, \[13C\]-pantoprazole administration to quantify 13CO2(Carbon 13 dioxide)/12CO2(Carbon 12 dioxide) by infrared spectrometry. Simultaneously, repeated blood sampling will be used to measure pantoprazole, and its primary CYP2C19 catalyzed metabolite. Pantoprazole disposition will then be characterized from both breath sample and plasma level data and examined in association with important covariates (e.g., age, hip:waist ratio, BMI, REE, parent drug:metabolite ratio and CYP2C19 genotype) to test the experimental hypothesis. Data will be collected and analyzed by a team of highly experienced investigators representing the fields of gastroenterology, pediatric clinical pharmacology and the evolving field of obesity medicine.

Recruitment & Eligibility

Status: COMPLETED

Sex: All

Target Recruitment: 71

Inclusion Criteria

Not provided

Exclusion Criteria

Not provided

Study & Design

Study Type: INTERVENTIONAL

Study Design: SINGLE_GROUP

Arm && Interventions

Group	Intervention	Description
Pantoprazole	Pantoprazole	This will be a single dose study where participants will receive 1.2mg/kg or no more than 100mg total one time dose as a liquid containing Carbon 13 labeled Pantoprazole with a final concentration of 4.0mg/mL.

Primary Outcome Measures

Name	Time	Method
Pantoprazole Apparent Oral Clearance	8 hours	Pantoprazole apparent oral drug clearance (CL/F) adjusted for weight for children with the most common CYP2C19 genotypes (i.e., \1/1, \1/17, \1/2, \2/17). Only children with evaluable plasma samples (i.e., at least 85% of planned plasma samples collected) were included in this analysis (n=57).
Unadjusted Pantoprazole Apparent Oral Clearance	8 hours	Pantoprazole apparent oral drug clearance (CL/F), not adjusted for weight, for children with the most common CYP2C19 genotypes (i.e., \1/1, \1/17, \1/2, \2/17). Only children with evaluable plasma samples (i.e., at least 85% of planned plasma samples collected) were included in this analysis (n=57).

Secondary Outcome Measures

Name	Time	Method
Precision of Breath Test to Discriminate the CYP2C19 Extensive Metabolizer (EM) From Intermediate Metabolizer (IM) Phenotype	3 hours	Children with common CYP2C19 genotypes (\1/\1, \1\17, \1/\2, \2/\17) who had evaluable breath test data (n=59) were included to evaluate the breath test's precision in discriminating the CYP2C19 Extensive Metabolizer (EM; \1/\1, \1\17) from the Intermediate Metabolizer (IM; \1/\2, \2/\17) phenotype in the first 3 hrs after study drug administration. A 3-hour window was chosen for convenience. A predictive model using breath test features (change in ratio of C12-to-C13 in exhaled CO2) was build and validated to predictphenotype for each child. We drew bootstrap samples, each stratified to preserve the observed prevalence of EM/IMs in the original cohort (n=59). Sampling with replacement left out 38% of the original sample to use as a test dataset to validate model performance. For each bootstrap sample, a 500-tree Extremely randomized Extra-Tree Forest was constructed after seeding. Using phenotypes predicted by the forest, predictive accuracy was assessed by computing precision.
Recall of Breath Test to Discriminate the CYP2C19 Extensive Metabolizer (EM) From Intermediate Metabolizer (IM) Phenotype	3 hours	Children with common CYP2C19 genotypes (\1/\1, \1\17, \1/\2, \2/\17) who had evaluable breath test data (n=59) were included to evaluate the breath test's precision in discriminating the CYP2C19 Extensive Metabolizer (EM; \1/\1, \1\17) from the Intermediate Metabolizer (IM; \1/\2, \2/\17) phenotype in the first 3 hrs after study drug administration. A 3-hour window was chosen for convenience. A predictive model using breath test features (change in ratio of C12-to-C13 in exhaled CO2) was build and validated to predictphenotype for each child. We drew bootstrap samples, each stratified to preserve the observed prevalence of EM/IMs in the original cohort (n=59). Sampling with replacement left out 38% of the original sample to use as a test dataset to validate model performance. For each bootstrap sample, a 500-tree Extremely randomized Extra-Tree Forest was constructed after seeding. Using phenotypes predicted by the forest, predictive accuracy was assessed by computing recall.
Harmonic Mean of Precision and Recall (F1) of the Breath Test to Discriminate the CYP2C19 Extensive Metabolizer (EM) From Intermediate Metabolizer (IM) Phenotype	3 hours	Children with common CYP2C19 genotypes (\1/\1, \1\17, \1/\2, \2/\17) who had evaluable breath test data (n=59) were included to evaluate the breath test's precision in discriminating the CYP2C19 Extensive Metabolizer (EM; \1/\1, \1\17) from the Intermediate Metabolizer (IM; \1/\2, \2/\17) phenotype in the first 3 hrs after study drug administration. A 3-hour window was chosen for convenience. A predictive model using breath test features (change in ratio of C12-to-C13 in exhaled CO2) was build and validated to predictphenotype for each child. We drew bootstrap samples, each stratified to preserve the observed prevalence of EM/IMs in the original cohort (n=59). Sampling with replacement left out 38% of the original sample to use as a test dataset to validate model performance. For each bootstrap sample, a 500-tree Extremely randomized Extra-Tree Forest was constructed after seeding. Using phenotypes predicted by the forest, predictive accuracy was assessed by computing the F1.