R41ES038048
Project Grant
Overview
Grant Description
Arsenic removal from the body through mechanism-guided gut microbiome modulation - Abstract
Environmental exposure to inorganic arsenic (IAS), a toxic heavy metal, is a significant public health risk, estimated to affect hundreds of millions of people globally.
The objective of this project is to develop novel microbiome-based solutions to reduce exposure to IAS, which is ubiquitously found in groundwater, food, soil, air, and other sources.
Chronic IAS exposure is associated with a range of serious health issues such as cardiovascular disease, neurological disorders, diabetes, and various types of cancers.
Current water filtration methods inadequately address IAS exposure due to limitations in efficacy, cost and performance, and they do not target other exposure routes, such as diet.
In fact, rice consumption alone is estimated to account for as much IAS exposure as drinking water in some U.S. populations.
Given the widespread nature of IAS exposure from multiple sources and the shortcomings of existing methods to remove IAS from water, there is a critical need for innovative strategies to reduce arsenic exposure in the body.
Our innovative approach leverages the gut microbiome's role in arsenic metabolism.
We propose a mechanism-guided strategy to engineer custom microbiomes that enhance IAS uptake, methylation, and efflux.
Preliminary studies have identified six bacterial strains that significantly reduce IAS body burden and tissue accumulation in mice.
This Phase I project aims to optimize human gut bacterial strains and evaluate their efficacy and safety in in vivo models, positioning us for further development of microbiome-based products to mitigate IAS toxicity.
Two specific aims will be pursued:
Aim 1 is to screen top bacterial strains for arsenic metabolism in vitro, identifying ≥10 candidates with substantial arsenic reduction/methylation capabilities;
Aim 2 is to evaluate the efficacy of these strains in germ-free and conventionally raised humanized mice, aiming for bacterial formulations that lead to significant reductions in urinary arsenic, liver bioaccumulation, and increased arsenic methylation, without adverse effects on health.
Successful completion of this project will yield a first-generation bacterial treatment to reduce IAS exposure, paving the way for Phase II development and broader application to other environmental toxicants.
Environmental exposure to inorganic arsenic (IAS), a toxic heavy metal, is a significant public health risk, estimated to affect hundreds of millions of people globally.
The objective of this project is to develop novel microbiome-based solutions to reduce exposure to IAS, which is ubiquitously found in groundwater, food, soil, air, and other sources.
Chronic IAS exposure is associated with a range of serious health issues such as cardiovascular disease, neurological disorders, diabetes, and various types of cancers.
Current water filtration methods inadequately address IAS exposure due to limitations in efficacy, cost and performance, and they do not target other exposure routes, such as diet.
In fact, rice consumption alone is estimated to account for as much IAS exposure as drinking water in some U.S. populations.
Given the widespread nature of IAS exposure from multiple sources and the shortcomings of existing methods to remove IAS from water, there is a critical need for innovative strategies to reduce arsenic exposure in the body.
Our innovative approach leverages the gut microbiome's role in arsenic metabolism.
We propose a mechanism-guided strategy to engineer custom microbiomes that enhance IAS uptake, methylation, and efflux.
Preliminary studies have identified six bacterial strains that significantly reduce IAS body burden and tissue accumulation in mice.
This Phase I project aims to optimize human gut bacterial strains and evaluate their efficacy and safety in in vivo models, positioning us for further development of microbiome-based products to mitigate IAS toxicity.
Two specific aims will be pursued:
Aim 1 is to screen top bacterial strains for arsenic metabolism in vitro, identifying ≥10 candidates with substantial arsenic reduction/methylation capabilities;
Aim 2 is to evaluate the efficacy of these strains in germ-free and conventionally raised humanized mice, aiming for bacterial formulations that lead to significant reductions in urinary arsenic, liver bioaccumulation, and increased arsenic methylation, without adverse effects on health.
Successful completion of this project will yield a first-generation bacterial treatment to reduce IAS exposure, paving the way for Phase II development and broader application to other environmental toxicants.
Awardee
Funding Goals
THE MISSION OF THE NATIONAL INSTITUTE OF ENVIRONMENTAL HEALTH SCIENCES (NIEHS) IS TO RESEARCH HOW THE ENVIRONMENT AFFECTS BIOLOGICAL SYSTEMS ACROSS THE LIFESPAN AND TO TRANSLATE THIS KNOWLEDGE TO REDUCE DISEASE AND PROMOTE HEALTH.
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Cary,
North Carolina
275132974
United States
Geographic Scope
Single Zip Code
Luxbiome was awarded
Project Grant R41ES038048
worth $306,374
from the National Institute of Environmental Health Sciences in September 2025 with work to be completed primarily in Cary North Carolina United States.
The grant
has a duration of 1 year and
was awarded through assistance program 93.113 Environmental Health.
The Project Grant was awarded through grant opportunity PHS 2024-2 Omnibus Solicitation of the NIH for Small Business Technology Transfer Grant Applications (Parent STTR [R41/R42] Clinical Trial Not Allowed).
Status
(Ongoing)
Last Modified 4/22/26
Period of Performance
9/12/25
Start Date
8/31/26
End Date
Funding Split
$306.4K
Federal Obligation
$0.0
Non-Federal Obligation
$306.4K
Total Obligated
Activity Timeline
Transaction History
Modifications to R41ES038048
Additional Detail
Award ID FAIN
R41ES038048
SAI Number
R41ES038048-659416210
Award ID URI
SAI UNAVAILABLE
Awardee Classifications
Small Business
Awarding Office
75NV00 NIH National Institute of Enviromental Health Sciences
Funding Office
75NV00 NIH National Institute of Enviromental Health Sciences
Awardee UEI
VLATTA57VMM5
Awardee CAGE
None
Performance District
NC-02
Senators
Thom Tillis
Ted Budd
Ted Budd
Modified: 4/22/26