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To stain a specimen slide, one or more liquid reagents are injected via the dispenser into the slide staining device via a syringe port. The volume of a given reagent is determined by adjustable settings on the dispenser, so that when connected to the staining device, initiates a thin film over the slide. The dispensing device uses only a fraction of the reagents typically used in non-sealed environments. Medical grade polyvinyl alcohol sponges have been incorporated into the dispenser to provide additional fluid containment and retention during the staining procedure. Furthermore, the dispenser can recall excess reagent, minimizing reagent use until refill. The slide staining device is composed of an upper and lower section held together and aligned by use of Nd magnets. With the device open, a specimen slide is positioned upon a silicone gasket that sits within a recess in the lower section. When the device is closed, the silicone gasket in the upper section applies a seal to the slide forming a cavity that allows the slide to be exposed to reagents injected from the connected dispenser creating a stain through the use of capillary forces. Although originally designed for use in microgravity, the slide staining system also works in gravity environments. Numerous applications may exist for this technology, particularly in hematology and cellular biology. Other applications could be considered for academic research, veterinary field use, military, disaster stricken and remote environments or where fine control of fluid delivery, removal, and management is desired. The slide staining system is at technology readiness level (TRL) 8 (actual system completed and "flight qualified" through test and demonstration), and are now available to license. Please note that NASA does not manufacture products itself for commercial sale.

NASA’s integrated, portable FPM device combines advanced optical microscopy with AI in a compact form factor. At its core, the system uses a Raspberry Pi camera module equipped with an 8-megapixel sensor and a 3-mm focal-length lens, achieving approximately 1.5× magnification. Illumination is provided by a Unicorn HAT HD LED array positioned 65mm below the sample stage, creating a synthetic numerical aperture of 0.55. All these components are controlled by an NVIDIA Jetson Nano board, which serves as the system's embedded AI computing platform. NASA’s portable FPM device can be integrated with a microfluidic system for sub-micron imaging of liquid samples. In addition to its portability, what sets NASA’s integrated FPM device apart is its integration of deep learning capabilities. The invention has two modes – normal mode and deep learning mode. In its normal mode, the system captures data and performs intensity and 3D phase analysis using traditional FPM methods. The deep learning mode enhances this base functionality by employing neural networks for image reconstruction and system optimization. The AI system automatically detects when samples are out of focus and can either mechanically or digitally adjust to the correct focal plane. To achieve near real-time monitoring, deep learning models significantly reduce data acquisition time by selectively using only a portion of the LED array and provide fast reconstruction capabilities leveraging training on specific sample types. While originally designed for imaging biosignature motility in liquid samples for spaceflight applications, this NASA innovation can image many different types of samples, and is not limited to biological specimens. The ability to operate this system in the field further broadens use-cases.