Manipulating the Gut Microbiome Study

Urea Cycle Disorder Clinical Trial

Official title: Manipulating the Gut Microbiome Study

Status Terminated

Clinical Trial Summary

The objective is to determine if acetohydroxamic acid (AHA) can prevent hydrolysis of urea by inhibiting the bacterial urease of gut flora of both healthy control adults as well as adults with urea cycle disorders

Clinical Trial Description

This project will study the efficacy and safety of the pharmacologic blockade of urease in the nitrogen salvage pathway of intestinal microbes in subjects with partial urea cycle disorders. Additional trapping of ammonia as excretable urea may result in improved nitrogen excretion and reduced ammonia levels.

Urea cycle disorders (UCDs) are a group of disorders resulting from a complete or partial deficiency of one of the 6 enzymes or 2 transporters that comprise the urea cycle, the essential biochemical pathway which converts toxic ammonia into urea. These disorders have as a common feature, a reduced or complete inability to convert ammonia into urea, thereby resulting in high ammonia levels, or hyperammonemia. If untreated, hyperammonemia may result acutely in lethargy and coma, and chronically in intellectual disability. Current treatment for hyperammonemia is suboptimal, thus the search for new treatments is critical.

The urease inhibitor, acetohydroxamic acid (AHA, Lithostat®, Mission Pharmacal), is an FDA-approved product for another indication- the treatment of struvite nephrolithiasis in chronic urinary tract infections in both adults and children.

It is known that many urea-splitting bacteria also exist in the gut, and that in healthy individuals, approximately 15-30% of blood urea is degraded via gut bacteria into ammonia3, which returns to the liver via the portal vein, only to be recycled into urea. This percentage of degraded urea may even be greater in patients with urea cycle disorders, who are on a low protein-diet4 and whose gastrointestinal contents thus likely have lower nitrogen content, promoting bacterial recycling of nitrogen from available urea. Additionally, urea hydrolysis has been shown to be greatest in infants5, precisely the age at which hyperammonemic episodes are the most frequent in UCD patients.

We intend to study if AHA can inhibit gut bacteria degradation of urea, thereby reducing the quantity of ammonia returning to the liver. We intend to investigate this by studying subjects on two occasions at least 3 days apart:

On the first occasion, subjects will receive an intravenous dose of 13C-urea. Following the intravenous bolus of 13C-urea, over the subsequent 4 hours, we will collect several sequential measurements of blood and urine biomarkers from an IV catheter placed in the other arm. The intent is to obtain baseline 13CO2 kinetics in the subject.

On the second occasion, subjects will first receive an oral dose of AHA approximately 1 hour prior to the intravenous 13C-urea dose. Similar sequential measurements of blood and urine biomarkers will be performed. The intent is to observe a reduction in 13CO2 when AHA is administered.

We intend to initially study a cohort of unaffected adult subjects. If successful, we will study adults with partial urea cycle disorders.

This study will be conducted in the Clinical Research Center (CRC) of the Clinical and Translational Research Institute (CTSI) of Children's National Medical Center (CNMC). ;

Related Conditions & MeSH terms

• Urea Cycle Disorder
• Urea Cycle Disorders, Inborn

• NCT number: NCT03181828
• Study type: Interventional
• Source: Children's National Research Institute
• Status: Terminated
• Phase: Phase 1/Phase 2
• Start date: March 24, 2017
• Completion date: June 5, 2018