Design and development of a polymer patch clamping device

Wilson, Sandra

January 2010

Patch clamping is considered the gold standard in measuring the bioelectrical activity of a cell. It is used to detect and measure ion transport through ion channels located throughout a cell membrane. Ion movement is crucial to cell viability and cell-to-cell communication. Pharmaceutical companies increasingly target ion channels because of their significance in disease and to help design better targeted drugs. However, the traditional method of patch clamping is cumbersome and is being replaced by planar high throughput screening (HTS) systems. These systems are reaching their limits due to materials and cost of processing; cell handling methods and small varieties of applicable cell types are also issues to be addressed. In this work, the core components of a new kind of planar patch clamping device have been designed and developed, after analysis of currently available HTS systems. This design approaches patch clamping using polymers to overcome some of the limitations in current systems, specifically cell handling and positioning, by using a simple modification technique to provide distinct attractive areas for cell binding. This uniquely allows the culture of both single cells and cell networks to increase the range of cell types that can be measured and circumvents challenges from using suction to pull cells onto measurement holes. The components of the design are a 10 x 10 array of small holes drilled in a polymer then aligned modifications for precise cell placement are added and a planar electrode array for individual addressing of each cell. A study of methods to produce a leak-tight seal required between microfluidic chambers was done. Cell adhesion parameters for the modification techniques were established. The principle viability of this approach was confirmed using the modification technique to culture cells over holes and measure their resistance using a rig developed for this work.

Design, Fabrication, and Implementation of a Single-Cell Capture Chamber for a Microfluidic Impedance Sensor

Fadriquela, Joshua-Jed Doria

01 June 2009

A microfluidic device was created for single-cell capture and analysis using polydimethylsiloxane (PDMS) channels and a glass substrate to develop a microfluidic single-cell impedance sensor for cell diagnostics. The device was fabricated using photolithography to create a master mold which in turn will use soft lithography to create the PDMS components for constant device production. The commercial software, COMSOLTM Multiphysics, was used to quantify the fluid dynamics in shallow micro-channels. The device will be able to capture a cell and sequester it long enough to enable measurement of the impedance spectra that can characterize cell. The proposed device will be designed to capture a single cell and permit back-flow to flush out excess cells in the chamber. The device will be designed to use syringe pumps and the syringe-controlled channel will also be used to capture and release the cell to ensure cell control and device reusability. We hypothesize that these characteristics along with other proposed design factors will result in a unique microfluidic cell-capture device that will enable single-cell impedance sensing and characterization.

Single-cell analysis

BioMEMS

Microfluidics

COMSOL CFD

Biomedical Devices and Instrumentation

Development of novel micro-embossing methods and microfluidic designs for biomedical applications

Lu, Chunmeng,

January 2006

Thesis (Ph. D.)--Ohio State University, 2006. / Title from first page of PDF file. Includes bibliographical references (p. 178-197).

Flexible Microfluidic Systems for Cellular Analysis Using Low Cost Fabrication Technologies

Moss, Eileen Devra

07 July 2006

This dissertation presents the design, fabrication, and testing of a microfluidic system to be used for whole-cell analysis. The study of cellular function and structure is essential for disease diagnosis and treatment. Microsystems developed to perform these bioanalyses add benefits such as requiring smaller samples and reagents, testing multiple samples in parallel, and supporting point-of-care testing, all of which increases throughput and reduces cost-per-analysis. Traditional methods for designing a microsystem use standard materials and techniques such as silicon, glass, photolithography, and wet and dry etching. This research is focused on utilizing materials and techniques that require less infrastructure, allow for a faster design-to-prototype cycle, and can integrate electrical and fluidic functionality to address a variety of possible applications. The microfluidic system presented in this thesis is comprised of multiple layers of Kapton, a polyimide available from DuPont. Kapton provides a biocompatible substrate that is flexible while maintaining structural stability and can be used in high temperature and other harsh environments. Microchannels with widths of 400 m and thru-hole fluidic vias less than 5 m in diameter are laser ablated through the flexible polyimide sheets using excimer and CO2 lasers. Electrical traces and contact pads are defined on the substrate by vapor deposition through reusable microstencils rather than with photolithography. The patterned layers are bonded using heat staking and then packaged with the addition of wires and a fluidic interface. Validation of the system for whole-cell analysis was first performed with impedance spectroscopy measurements collected on air, DI water, phosphate buffered saline, clusters of human cancer cells, and human cancer tissue samples. This was followed by testing the ability to use the device to control the movement and position of 10 m diameter microbeads and dissociated cells. As a whole, this research demonstrates the realization of a microfluidic system for whole-cell analysis based on non-standard fabrication materials and techniques.

Laser ablation

Microstenciling

Polymers

Whole-cell analysis

BioMEMS

Microfabrication

Microfabricated Multi-Analysis System for Electrophysiological Studies of Single Cells

Han, Arum

14 July 2005

A micro-electrophysiological analysis system (-EPAS) using various microfabrication techniques for single cell study was developed. Conventional microfabrication techniques combined with plastic and polymer microfabrication techniques have been used to realize the system. The system is capable of performing patch clamp recording and whole cell electrical impedance spectroscopy (EIS) on a single cell. Methodologies for single cell manipulation were developed. The ion channel activities of primary cultured bovine chromaffin cells were measured in both the patch clamping mode and the whole cell EIS mode. Membrane capacitance of the chromaffin cell was calculated from these measurements. Increases in the capacitances were observed when certain ion channels were blocked using toxins. The dielectric properties of human breast cancer cell lines from different pathological stages were measured and compared to a normal human breast cell line in the whole cell EIS mode. The measured properties were correlated to the pathological stages of the breast cancer cell lines. Decreases in the membrane capacitances were observed for the more pathologically progressed cancer cell lines.

Single cell analysis

Lab on a chip

Breast cancer

Biomems

Impedance spectroscopy

A prototype multifunction differential pressure-flow sensor for medical and industrial applications

Shakir, Ali M.

January 2009

Thesis (Ph. D.)--State University of New York at Binghamton, Thomas J. Watson School of Engineering and Applied Science, Department of Systems Science and Industrial Engineering, 2009.. / Includes bibliographical references.

Application of Alkylsilane Self-Assembled Monolayers for Cell Patterning and Development of Biolocial Microelectromechanical Systems

Wilson, Kerry

01 January 2009

Advances in microfabrication and surface chemistry techniques have provided a new paradigm for the creation of in vitro systems for studying problems in biology and medicine in ways that were previously not practical. The ability to create devices with micro- to nano-scale dimensions provides the opportunity to non-invasively interrogate and monitor biological cells and tissue in large arrays and in a high-throughput manner. These systems hold the potential to, in time, revolutionize the way problems in biology and medicine are studied in the form of point-of-care devices, lab-on-chip devices, and biological microelectromechanical systems (BioMEMS). With new in vitro models, it will be possible to reduce the overall cost of medical and biological research by performing high-throughput experiments while maintaining control over a wide variety of experimental variables. A critical aspect of developing these sorts of systems, however, is controlling the device/tissue interface. The surface chemistry of cell-biomaterial and protein-biomaterial interactions is critical for long-term efficacy and function of such devices. The work presented here is focused on the application of surface and analytical chemistry techniques for better understanding the interface of biological elements with silica substrates and the development a novel Bio-MEMS device for studying muscle and neuromuscular biology. A novel surface patterning technique based on the use of a polyethylene glycol (PEG) silane self-assembled monolayer (SAM) as a cytophobic surface and the amine-terminated silane diethyeletriamine (DETA) as a cytophilic surface was developed for patterning a variety of cell types (e.g. skeletal muscle, and neural cells) over long periods of time (over 40 days) with high fidelity to the patterns. This method was then used to pattern embryonic rat skeletal muscle and motor neurons onto microfabricated silicon cantilevers creating a novel biological microelectromechanical system (BioMEMS) for studying muscle and the neuromuscular junction. This device was then used to study the effect of exogenously applied substances such as growth factors and toxins. Furthermore, a whispering-gallery mode (WGM) biosensor was developed for measuring the adsorption of various proteins onto glass microspheres coated with selected silane SAMS commonly used in BioMEMS system. With this biosensor it was possible to measure the kinetics of protein adsorption onto alkylsilane SAMS, in a real-time and label-free manner.

Silane

BioMEMS

Self-assembled monolayers

whispering gallery mode

photolithography

Chemistry

A BIOPARTICLE SEPARATION TECHNIQUE THROUGH MICROCHANNELS USING SEQUENTIAL PRESSURE PULSES

JAIN, ALOK

02 July 2004

No description available.

Bioparticle separation

magnetic bead separation

blood separation

pressure pulses

biomems

ON-CHIP PASSIVE FLUIDIC MICROMIXER AND PRESSURE GENERATOR FOR DISPOSABLE LAB-ON-A-CHIPS

HONG, CHIEN-CHONG

January 2004

No description available.

Disposable Lab-on-a-chip

Microfluidics

BioMEMS

Polymer MEMS

Clinical Diagnostics

DESIGN AND FABRICATION OF POLYMER-BASED MICROFLUIDIC PLATFORMS FOR BIOMEMS APPLICATIONS

Lai, Siyi

29 January 2003

No description available.

Engineering, Chemical

Microfluidic

BioMEMS

polymer microfabrication

biochip

bonding

ELISA