Bioresorbable shape-adaptive structures for ultrasonic monitoring of deep-tissue homeostasis

Jiaqi Liu(Northwestern University), Naijia Liu(Northwestern University), Yameng Xu(Washington University in St. Louis), Mingzheng Wu(Northwestern University), Haohui Zhang(Northwestern University), Yue Wang(Northwestern University), Yan Yan(Washington University in St. Louis), Angela Hill(Washington University in St. Louis), Ruihao Song(Northwestern University), Zijie Xu(Northwestern University), Minsu Park(Dankook University), Yunyun Wu(Northwestern University), Joanna L. Ciatti(Northwestern University), Jianyu Gu(Northwestern University), Haiwen Luan(Northwestern University), Yamin Zhang(Northwestern University), Tianyu Yang(Northwestern University), Hak‐Young Ahn(Northwestern University), Shupeng Li(Northwestern University), Wilson Z. Ray(Washington University in St. Louis), Colin K. Franz(Northwestern University), Matthew R. MacEwan(Washington University in St. Louis), Yonggang Huang(Northwestern University), Chet W. Hammill(Washington University in St. Louis), Heling Wang(Jiaxing University), John A. Rogers(Northwestern University)
Science
March 7, 2024
10.1126/science.adk9880
Cited by 81

Abstract

Monitoring homeostasis is an essential aspect of obtaining pathophysiological insights for treating patients. Accurate, timely assessments of homeostatic dysregulation in deep tissues typically require expensive imaging techniques or invasive biopsies. We introduce a bioresorbable shape-adaptive materials structure that enables real-time monitoring of deep-tissue homeostasis using conventional ultrasound instruments. Collections of small bioresorbable metal disks distributed within thin, pH-responsive hydrogels, deployed by surgical implantation or syringe injection, allow ultrasound-based measurements of spatiotemporal changes in pH for early assessments of anastomotic leaks after gastrointestinal surgeries, and their bioresorption after a recovery period eliminates the need for surgical extraction. Demonstrations in small and large animal models illustrate capabilities in monitoring leakage from the small intestine, the stomach, and the pancreas.

Related Papers

A Physically Transient Form of Silicon Electronics
Suk‐Won Hwang, Hu Tao, Dae‐Hyeong Kim et al.|Science|2012|1.3k
Comb-type grafted hydrogels with rapid deswelling response to temperature changes
Ryo Yoshida, Katsumi Uchida, Yuzo Kaneko et al.|Nature|1995|1.2k
A theory of coupled diffusion and large deformation in polymeric gels
Wei Hong, Xuanhe Zhao, Jinxiong Zhou et al.|Journal of the Mechanics and Physics of Solids|2007|1k
Variable cytocompatibility of six cell lines with photoinitiators used for polymerizing hydrogels and cell encapsulation
Christopher G. Williams, Athar N. Malik, Tae Kyun Kim et al.|Biomaterials|2004|881
Surface area of the digestive tract – revisited
Herbert F. Helander, Lars Fändriks|Scandinavian Journal of Gastroenterology|2014|844