Overview of SHOT hardware capabilities and range of cell biology experiment designs.

Cell science hardware is currently available for lease or production by SHOT(R). The SHOT Avian Development Facility (ADF) is a single middeck locker experiment containing two carousels capable of rotating at variable g. Each carousel accommodates 18 40-ml vessels that can be adapted for the cultivation of avian or reptilian eggs, small invertebrates, zebra fish, small plants, seeds, spores, cells or tissues. Cellcult Cassettes contain a small (20-50 ml) rotating cylindrical culture vessel with feed media reservoir, pumps, waste bag and sample collection bags. Cultures can be rotated, perfused, fed, aerated and sampled automatically or on remote command. Fluid Processing Cassettes contain a flexible combination of feed, culture and fixative bags with valves and pumps programmable for various feeding and fixing protocols. Dynacult Cassettes contain a cylindrical bioreactor with differentially rotating walls, pumps and valves for feeding and sampling, and pH and oxygen measurement. All cassettes are doubly contained and are accommodated by a computerized, thermally controlled processing facility, the Advanced Space Experiment Processor, which processes three cassettes, or the Biotechnology Thermal Environment Carrier, which holds up to six cassettes.

Sliding-cavity fluid contactors in low-gravity fluids, materials, and biotechnology research.

The well-known method of sliding-cavity fluid contactors used by Gosting for diffusion measurements and by Tiselius in electrophoresis has found considerable use in low-gravity research. To date, sliding-cavity contactors have been used in liquid diffusion experiments, interfacial transport experiments, biomolecular crystal growth, biphasic extraction, multistage extraction, microencapsulation, seed germination, invertebrate development, and thin-film casting. Sliding-cavity technology has several advantages for spaceflight: it is simple, it accommodates small samples, samples can be fully enclosed, phases can be combined, multiple samples can be processed at high sample density, real-time observations can be made, and mixed and diffused samples can be compared. An analysis of the transport phenomena that govern the sliding-cavity method is offered. During sliding of one liquid over another flow rates between 0.001 and 0.1m/sec are developed, giving Reynolds numbers in the range 0.1-100. Assuming no slip at liquid-solid boundaries shear rates are of the order 1sec(-1). The measured consequence is the transfer of 2-5% of the content of a cavity to the opposite cavity. In the absence of gravity, buoyancy-driven transport is assumed absent. Transport processes are limited to (1) molecular diffusion, in which reactants diffuse toward one another at rates that depend on their diffusion coefficient and concentration gradient (Fick's second law), (2) solutocapillary (Marangoni) flow driven by surface-tension gradients, (3) capillary flow (drop spreading) at liquid-solid three-phase lines leading to immiscible phase demixing, and (4) vapor-phase diffusive mass transfer in evaporative processes. Quantitative treatment of these phenomena has been accomplished over the past few years in low-gravity research in space and on aircraft.