Results 181 to 190 of about 2,871,670 (306)

Hydrogel Confinement Strategies for 3D Cell Culture in Microfluidic Systems

Advanced Materials Technologies, EarlyView.
Hydrogel confinement structures are key to organizing 3D cell cultures in microfluidic devices. This review classifies five structural strategies (micropillar, phaseguide, porous membrane, stepped‐height, and support‐free) and examines their trade‐offs alongside fabrication methods.
Soohyun Kim, Min Seok Lee, Sung Kyun Lee
wiley   +1 more source

Design and Implementation of a High-Throughput Digital Microfluidic System Based on Optimized YOLOv8 Object Detection [PDF]

Ming Cao, Weihao Duan, Zhihao Huang, Huihong Liang, Fanrong Ai, Xianming Liu   +5 more
openalex   +1 more source

End‐to‐End Sensing Systems for Breast Cancer: From Wearables for Early Detection to Lab‐Based Diagnosis Chips

Advanced Materials Technologies, EarlyView.
This review explores advances in wearable and lab‐on‐chip technologies for breast cancer detection. Covering tactile, thermal, ultrasound, microwave, electrical impedance tomography, electrochemical, microelectromechanical, and optical systems, it highlights innovations in flexible electronics, nanomaterials, and machine learning.
Neshika Wijewardhane, Lyn I. Jones, Richard M. Martin, Helen Winter, Faezeh Arab Hassani   +4 more
wiley   +1 more source

Digital Microfluidics Chips for the Execution and Real-Time Monitoring of Multiple Ribozymatic Cleavage Reactions. [PDF]

ACS Omega, 2021
Davis AN, Samlali K, Kapadia JB, Perreault J, Shih SCC, Kharma N.   +5 more
europepmc   +1 more source

Hydrogel discs for digital microfluidics [PDF]

, 2012
Lindsey K. Fiddes, Vivienne N. Luk, Sam H. Au, Alphonsus H. C. Ng, Victoria Luk, Eugenia Kumacheva, Aaron R. Wheeler   +6 more
openalex   +1 more source

Ultra‐Thin Soft Pneumatic Actuation for Minimally Invasive Neural Interfacing

Advanced Materials Technologies, EarlyView.
Parylene C is a common polymer in bioelectronics, favored for its biological and chemical inertness. However, this makes bonding layers of Parylene C together very challenging. Here it is a laser to selectively weld layers of Parylene C to create high‐pressure fluidic actuation devices.
Lawrence Coles, Joe G. Troughton, Alejandro Carnicer‐Lombarte, George G. Malliaras, Christopher M. Proctor   +4 more
wiley   +1 more source

Orchestrating Self-Replication in Artificial Cells with Digital Microfluidics. [PDF]

Small
Zhai G, Dimitriou P, Sengel J, Wallace MI.   +3 more
europepmc   +1 more source

Droplet jumping by electrowetting and its application to the three-dimensional digital microfluidics

, 2012
Seung Jun Lee, Sanghyun Lee, Kwan Hyoung Kang   +2 more
openalex   +2 more sources

Nitroxide‐Mediated Photo‐Polymerization: A Swiss Army Knife for Microfluidic Design

Advanced Materials Technologies, EarlyView.
This article illustrates the application of NMP2 to the rapid (less than 1 h) photostructuring and sealing of model structures intended for microfluidic applications. Remarkably, the careful design of resin composition allows completing these steps by simply spreading bare monomer (i.e., no added photoinitiator) on top of the bottom layer embedding ...
Carlo Gonzato, Sandip Wadhai, Jean‐Louis Clement, Florent Malloggi, Yohann Guillaneuf, Olivier Soppera   +5 more
wiley   +1 more source

High density DNA data storage library via dehydration with digital microfluidic retrieval [PDF]

, 2019
Sharon Newman, Ashley Stephenson, Max Willsey, Bichlien H. Nguyen, Christopher N. Takahashi, Karin Strauß, Luís Ceze   +6 more
openalex   +1 more source