Biocompatible Heterogeneous Packaging and Laser-Assisted Fluid Interface Control for In Situ Sensor in Organ-on-a-Chip

The development of bionic organ-on-a-chip technology relies heavily on advancements in in situ sensors and biochip packaging. By integrating precise biological and fluid condition sensing with microfluidics and electronic components, long-term dynamic closed-loop culture systems can be achieved. Thi...

Full description

Saved in:
Bibliographic Details
Published in:Micromachines (Basel) 2024-12, Vol.16 (1), p.46
Main Authors: Lin, Yu-Hsuan, Lau, Shing-Fung, Lu, Yen-Pei, Huang, Kuo-Cheng, Ding, Chien-Fang, Tang, Yu-Hsiang, Tsai, Hsin-Yi
Format: Article
Language:English
Subjects:
Biochips
Biocompatibility
biocompatible heterogeneous packaging
Biomedical materials
Bionics
Cell culture
Chemical vapor deposition
Circuit boards
Closed loops
Contact angle
Contact pressure
Control methods
Electronic components
Electronic packaging
Encapsulation
Fluid dynamics
Fluids
Hydrophobic surfaces
Hypertension
Laser processing
laser surface modification
Lasers
Manufacturing
Mass production
Metabolism
Metabolites
Microfluidics
organ twin
organ-on-a-chip (OoC)
Physiology
Pressure sensors
Process parameters
Production costs
Sensors
Toxicity
Ultraviolet lasers
Wettability
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The development of bionic organ-on-a-chip technology relies heavily on advancements in in situ sensors and biochip packaging. By integrating precise biological and fluid condition sensing with microfluidics and electronic components, long-term dynamic closed-loop culture systems can be achieved. This study aims to develop biocompatible heterogeneous packaging and laser surface modification techniques to enable the encapsulation of electronic components while minimizing their impact on fluid dynamics. Using a kidney-on-a-chip as a case study, a non-toxic packaging process and fluid interface control methods have been successfully developed. Experimentally, miniature pressure sensors and control circuit boards were encapsulated using parylene-C, a biocompatible material, to isolate biochemical fluids from electronic components. Ultraviolet laser processing was employed to fabricate structures on parylene-C. The results demonstrate that through precise control of processing parameters, the wettability of the material can be tuned freely within a contact angle range of 60° to 110°. Morphological observations and MTT assays confirmed that the material and the processing methods do not induce cytotoxicity. This technology will facilitate the packaging of various miniature electronic components and biochips in the future. Furthermore, laser processing enables rapid and precise control of interface conditions across different regions within the chip, demonstrating a high potential for customized mass production of biochips. The proposed innovations provide a solution for in situ sensing in organ-on-a-chip systems and advanced biochip packaging. We believe that the development of this technology is a critical step toward realizing the concept of "organ twin".
ISSN:2072-666X
2072-666X
DOI:10.3390/mi16010046