Ultra-soft and highly stretchable tissue-adhesive hydrogel based multifunctional implantable sensor for monitoring of overactive bladder

A highly stretchable and tissue-adhesive multifunctional sensor based on structurally engineered islets embedded in ultra-soft hydrogel is reported for monitoring of bladder activity in overactive bladder (OAB) induced rat and anesthetized pig. The use of hydrogel yielded a much lower sensor modulus...

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Published in:Biosensors & bioelectronics 2023-04, Vol.225, p.115060-115060, Article 115060
Main Authors: Oh, Byungkook, Lim, Young-Soo, Ko, Kun Woo, Seo, Hyeonyeob, Kim, Dong Jun, Kong, Dukyoo, You, Jae Min, Kim, Hansoul, Kim, Taek-Soo, Park, Seongjun, Kwon, Dong-Soo, Na, Joon Chae, Han, Woong Kyu, Park, Sung-Min, Park, Steve
Format: Article
Language:English
Subjects:
Animals
Biosensing Techniques
EMG sensors
Hydrogels
In-vivo measuring of overactive bladder models of rat
Rats
Reproducibility of Results
Soft-Rigid hybrid structures
Strain sensors
Swine
Tissue Adhesives
Urinary Bladder, Overactive - complications
Urinary Bladder, Overactive - diagnosis
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Summary:A highly stretchable and tissue-adhesive multifunctional sensor based on structurally engineered islets embedded in ultra-soft hydrogel is reported for monitoring of bladder activity in overactive bladder (OAB) induced rat and anesthetized pig. The use of hydrogel yielded a much lower sensor modulus (1 kPa) compared to that of the bladder (300 kPa), while the strong adhesiveness of the hydrogel (adhesive strength: 260.86 N/m) allowed firm attachment onto the bladder. The change in resistance of printed liquid metal particle thin-film lines under strain were used to detect bladder inflation and deflation; due to the high stretchability and reliability of the lines, surface strains of 200% could be measured repeatedly. Au electrodes coated with Platinum black were used to detect electromyography (EMG). These electrodes were placed on structurally engineered rigid islets so that no interfacial fracture occurs under high strains associated with bladder expansion. On the OAB induced rat, stronger signals (change in resistance and EMG root-mean-square) were detected near intra-bladder pressure maxima, thus showing correlation to bladder activity. Moreover, using robot-assisted laparoscopic surgery, the sensor was placed onto the bladder of an anesthetized pig. Under voiding and filling, bladder strain and EMG were once again monitored. These results confirm that our proposed sensor is a highly feasible, clinically relevant implantable device for continuous monitoring OAB for diagnosis and treatment.
ISSN:0956-5663
1873-4235
DOI:10.1016/j.bios.2023.115060