Shape memory-based gastric motility 3D mapping

Authors

Neil Zixun Jia, MIT School of Engineering
Qiyun Gao, MIT School of Engineering
Vítor Sencadas, CICECO – Instituto de Materiais de Aveiro
Michelle Zong, MIT School of Engineering
Jesse George-Akpenyi, MIT School of Engineering
Sylvia E. Waft, MIT School of Engineering
Johannes L.P. Kuosmanen, MIT School of Engineering
Josh Jenkins, MIT School of Engineering
Keiko Ishida, Massachusetts Institute of Technology
Alison M. Hayward, MIT School of Engineering
Wiam Abdalla Mohammed Madani, Massachusetts Institute of Technology
Niora Fabian, MIT School of Engineering
George Selsing, MIT School of Engineering
Stephanie Owyang, MIT School of Engineering
Khalil B. Ramadi, MIT School of Engineering
Ziliang Kang, MIT School of Engineering
Hen Wei Huang, MIT School of Engineering
Giovanni Traverso, MIT School of Engineering

Publication Name

Device

Abstract

Gastrointestinal (GI) dysmotility, caused by impaired muscular contractions in the GI tract, affects 15%–20% of the population. Current clinical evaluations are limited. Here we report a motility-mapping platform that maps three-dimensional (3D) pressure distribution in the stomach, addressing gaps in existing techniques, such as high-resolution manometry. We validated the platform's measurements against existing techniques in the esophagus and rectum. A sensor probe, designed to conform to specific anatomical environments, uses body-temperature-triggered shape memory alloy to adapt to the stomach. We tested the platform's motility mapping in swine stomachs, esophagi, and rectums, both ex vivo and in vivo. This 3D in vivo characterization could transform our understanding, diagnosis, and treatment of complex GI conditions, such as functional dyspepsia.

Open Access Status

This publication may be available as open access

Volume

1

Issue

1

Article Number

100010

Funding Sponsor

Department of Mechanical Engineering, College of Engineering, Michigan State University