Tissue-engineered microenvironment systems for modeling human vasculature.

The high attrition rate of drug candidates late in the development process has led to an increasing demand for test assays that predict clinical outcome better than conventional 2D cell culture systems and animal models. Government agencies, the military, and the pharmaceutical industry have started initiatives for the development of novel in-vitro systems that recapitulate functional units of human tissues and organs. There is growing evidence that 3D cell arrangement, co-culture of different cell types, and physico-chemical cues lead to improved predictive power.

Innovations in preclinical biology: ex vivo engineering of a human kidney tissue microperfusion system.

Kidney disease is a public health problem that affects more than 20 million people in the US adult population, yet little is understood about the impact of kidney disease on drug disposition. Consequently there is a critical need to be able to model the human kidney and other organ systems, to improve our understanding of drug efficacy, safety, and toxicity, especially during drug development. The kidneys in general, and the proximal tubule specifically, play a central role in the elimination of xenobiotics.

Extensive adipogenic and osteogenic differentiation of patterned human mesenchymal stem cells in a microfluidic device.

Microtechnology offers great prospects for cellular research by enabling controlled experimental conditions that cannot be achieved by traditional methods. This study demonstrates the use of a microfluidic platform for long-term cultivation (3 weeks) of human mesenchymal stem-like cells (MSCs), a cell population of high interest for tissue engineering. The typical high motility of the MSCs required a strategy for preventing cells from inhabiting the feeding channels and thus interfere with a steady perfusion of medium to the cell cultivation chamber.

Dual-modal three-dimensional imaging of single cells with isometric high resolution using an optical projection tomography microscope.

The practice of clinical cytology relies on bright-field microscopy using absorption dyes like hematoxylin and eosin in the transmission mode, while the practice of research microscopy relies on fluorescence microscopy in the epi-illumination mode. The optical projection tomography microscope is an optical microscope that can generate 3-D images of single cells with isometric high resolution both in absorption and fluorescence mode. Although the depth of field of the microscope objective is in the submicron range, it can be extended by scanning the objective's focal plane.

Localized acetylcholine receptor clustering dynamics in response to microfluidic focal stimulation with agrin.

Agrin is a proteoglycan secreted by the motor neuron's growing axon terminal upon contact with the muscle during embryonic development. It was long thought that agrin's role was to trigger the clustering of acetylcholine receptors (AChRs) to nascent synapse sites. However, agrin-predating, protosynaptic AChR clusters are present well before innervation in the embryo and in myotube cultures, yet no role has been conclusively ascribed to agrin.

Long-term microfluidic cultures of myotube microarrays for high-throughput focal stimulation.

We have developed a microfluidic cell culture method that allows for the formation of linear isolated myotubes organized in a parallel microarray. Attachment and spreading of cells are confined within microtracks of cell-adherent proteins separated by a protein-repellent coating. Signaling molecules or other molecules of interest can be focally delivered to the myotubes using heterogeneous microfluidic streams.

Long-term micropatterned cell cultures in heterogeneous microfluidic environments.

Microfluidic poly(dimethylsiloxane) (PDMS) devices were constructed and used as long-term cell culture platforms for skeletal muscle cell differentiation and for dynamic application of chemical stimuli to the cells. The devices featured two orthogonal fluidic networks: one for long-term cell perfusion at minimal rates and the other one for short-term selective cell treatment and stimulation with biologically relevant molecules. The cells were micropatterned within the microfluidic channels using surface modification techniques, cultured under continuous flow, and allowed to fuse into polynucleated myotubes (a major milestone in muscle cell differentiation).

A nanofabricated planar aperture as a mimic of the nerve-muscle contact during synaptogenesis.

The release of synaptogenic factors by the nerve terminal plays a central role in the aggregation of neurotransmitter receptors at the postsynaptic membrane, a precisely timed and localized process that is essential for the correct formation and functioning of the synapse. This process has been difficult to re-capitulate in cell culture because present cell stimulation methods do not have sufficient spatiotemporal control of the delivery of soluble signals. We cultured myotubes atop nanofabricated planar apertures (2-8 microm diameter) to focally stimulate the muscle cell membrane with neural agrin, a synaptogenic factor released by motor neurons during development.

Local induction of acetylcholine receptor clustering in myotube cultures using microfluidic application of agrin.

During neuromuscular synaptogenesis, the exchange of spatially localized signals between nerve and muscle initiates the coordinated focal accumulation of the acetylcholine (ACh) release machinery and the ACh receptors (AChRs). One of the key first steps is the release of the proteoglycan agrin focalized at the axon tip, which induces the clustering of AChRs on the postsynaptic membrane at the neuromuscular junction. The lack of a suitable method for focal application of agrin in myotube cultures has limited the majority of in vitro studies to the application of agrin baths.

Differentiation-on-a-chip: a microfluidic platform for long-term cell culture studies.

Here we demonstrate a microfluidic perfusion system suitable for a long-term (>2 week) culture of muscle cells spanning the whole process of differentiation from myoblasts to myotubes. Cell-adhesive surface microdomains alternating with a robust cell-repellent coating mimic in vivo spatial cues for muscle cell assembly and allow for confining the fusion of myoblasts into aligned, isolated multinucleated myotubes. The microfluidic system provides accurate control of the perfusion rates and biochemical composition of the environment surrounding the cells.

Biology on a chip: microfabrication for studying the behavior of cultured cells.

The ability to culture cells in vitro has revolutionized hypothesis testing in basic cell and molecular biology research and has become a standard methodology in drug screening and toxicology assays. However, the traditional cell culture methodology--consisting essentially of the immersion of a large population of cells in a homogeneous fluid medium--has become increasingly limiting, both from a fundamental point of view (cells in vivo are surrounded by complex spatiotemporal microenvironments) and from a practical perspective (scaling up the number of fluid handling steps and cell manipulations for high-throughput studies in vitro is prohibitively expensive). Microfabrication technologies have enabled researchers to design, with micrometer control, the biochemical composition and topology of the substrate, the medium composition, as well as the type of neighboring cells surrounding the microenvironment of the cell.