Erik C. Jensen

Micropneumatic Digital Logic Structures for Integrated Microdevice Computation and Control

It is shown that microfabricated polydimethylsiloxane membrane valve structures can be configured to function as transistors in pneumatic digital logic circuits. Using the analogy with metal-oxide-semiconductor field-effect transistor circuits, networks of pneumatically actuated microvalves are designed to produce pneumatic digital logic gates (AND, OR, NOT, NAND, and XOR). These logic gates are combined to form 4- and 8-bit ripple-carry adders as a demonstration of their universal pneumatic computing capabilities. Signal propagation through these pneumatic circuits is characterized, and an amplifier circuit is demonstrated for improved signal transduction. Propagation of pneumatic carry information through the 8-bit adder is complete within 1.1 s, demonstrating the feasibility of integrated temporal control of pneumatic actuation systems. Integrated pneumatic logical systems reduce the number of off-chip controllers required for lab-on-a-chip and microelectromechanical system devices, allowing greater complexity and portability. This technology also enables the development of digital pneumatic computing and logic systems that are immune to electromagnetic interference.

Universal Microfluidic Automaton for Autonomous Sample Processing: Application to the Mars Organic Analyzer

A fully integrated multilayer microfluidic chemical analyzer for automated sample processing and labeling, as well as analysis using capillary zone electrophoresis is developed and characterized. Using lifting gate microfluidic control valve technology, a microfluidic automaton consisting of a two-dimensional microvalve cellular array is fabricated with soft lithography in a format that enables facile integration with a microfluidic capillary electrophoresis device. The programmable sample processor performs precise mixing, metering, and routing operations that can be combined to achieve automation of complex and diverse assay protocols. Sample labeling protocols for amino acid, aldehyde/ketone and carboxylic acid analysis are performed automatically followed by automated transfer and analysis by the integrated microfluidic capillary electrophoresis chip. Equivalent performance to off-chip sample processing is demonstrated for each compound class; the automated analysis resulted in a limit of detection of ~16 nM for amino acids. Our microfluidic automaton provides a fully automated, portable microfluidic analysis system capable of autonomous analysis of diverse compound classes in challenging environments.

Microvalve Enabled Digital Microfluidic Systems for High-Performance Biochemical and Genetic Analysis

Microfluidic devices offer unparalleled capability for digital microfluidic automation of sample processing and complex assay protocols in medical diagnostic and research applications. In our own work, monolithic membrane valves have enabled the creation of two platforms that precisely manipulate discrete, nanoliter-scale volumes of sample. The digital microfluidic automaton uses two-dimensional microvalve arrays to combinatorially process nanoliter-scale sample volumes. This programmable system enables rapid integration of diverse assay protocols using a universal processing architecture. Microfluidic emulsion generator array (MEGA) devices integrate actively controlled three microvalve pumps to enable on-demand generation of uniform droplets for statistical encapsulation of microbeads and cells. A MEGA device containing 96 channels confers the capability of generating up to 3.4 × 106-nL volume droplets per hour for ultrahigh-throughput detection of rare mutations in a vast background of normal genotypes. These novel digital microfluidic platforms offer significant enhancements in throughput, sensitivity, and programmability for automated sample processing and analysis.

Microfabricated linear hydrogel microarray for single-nucleotide polymorphism detection.

A platform is developed for rapid, multiplexed detection of single-nucleotide polymorphisms using gels copolymerized with oligonucleotide capture probes in a linear microchannel array. DNA samples are analyzed by electrophoresis through the linear array of gels, each containing 20-40 μM of a unique oligonucleotide capture probe. Electrophoresis of target DNA through the capture sites and the high concentration of capture probes within the gels enables significantly shorter incubation times than standard surface DNA microarrays. These factors also result in a significant concentration of target within the gels, enabling precise analysis of as little as 0.6 femtomoles of DNA target. Differential melting of perfectly matched and mismatched targets from capture probes as a function of electric field and temperature enables rapid, unambiguous identification of single-nucleotide polymorphisms.

Fabrication of PDMS Nanocomposite Materials and Nanostructures for Biomedical Nanosystems

Recent applications of PDMS nanocomposite materials and nanostructures have dramatically increased in biomedical fields due to optical, mechanical and electrical properties that are controllable by nanoengineering fabrication processes. These applications include biomedical imaging, biosensing, and cellular bioengineering studies using PDMS engineered structures with nanoparticles, nanopillars and functional nanoporous membranes. This article reviews the recent progress of PDMS nanocomposite materials and nanostructures and provides descriptions of various fabrication techniques. Together with these fabrication techniques, we discuss how these nanocomposite PDMS biomedical devices are revolutionizing biomedical science and engineering fields.