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A Simplified Production of Organic Compounds Containing High Enantiomer Excesses

NASA has developed a novel approach for producing sugars and sugar acids enriched with one of the two enantiomers of individual compounds. This approach can also be adapted for other compounds, such as amino acids. All objects, including chemical compounds, have mirror images, some of which cannot be superimposed. In the case of chemical compounds, these non-superimposable mirror images are called enantiomers and are widely used in biological processes. NASA’s method produces high enantiomer excesses from simple and relatively inexpensive precursors (formaldehyde and simple salts) and hardware components without the need and expense of using (at some stage) biological sources. Unlike the commercial production of most rare enantiomers, this innovation employs conditions that are extremely common, non-biological, and relatively inexpensive to set up.

Posted in: Briefs, Medical

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Generation of High-Pressure Oxygen Via Electrochemical Pumping in a Multi-Stage Electrolysis Stack

Innovators at NASA’s Glenn Research Center have developed a method for producing pure high-pressure oxygen via an electrochemical pumping process through a solid oxide electrolysis (SOE) cell stack. Glenn’s device can either concentrate the oxygen in the ambient atmosphere or extract the oxygen via the chemical reduction of carbon dioxide, water, or any combination of these substances. This solid-state device does not use any moving parts or any extra separation processes to purify the delivered oxygen. Instead, Glenn’s technology relies on a multi-stage stack design and an SOE process that includes an oxygen-ion-conducting ceramic membrane to generate high-pressure oxygen within a compact, noiseless device. This process has great potential for use in medical, industrial, and recreational applications.

Posted in: Briefs, Medical

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Tension Distribution in Tendon-Driven Fingers

The technology can be used in telemedicine, surgical robotics, home medical service robotics, medical rehabilitation, and hospital service robotics. Researchers at the NASA Johnson Space Center (JSC), in collaboration with General Motors and Oceaneering, have designed a state-of-the-art, highly dexterous, humanoid robot called Robonaut 2 (R2). R2 is made up of multiple component technologies and systems encompassing nearly 50 patented and patent-pending technologies with the potential to be game-changers in multiple industries, including the medical industry. R2 technologies can aid in a variety of medical applications, ranging from telemedicine to handling the logistics of medical procedures. These activities can be done in autonomous mode or in teleoperation mode, where the robot is controlled by a technician or physician. This type of operation would be advantageous in situations where a biomedical hazard poses risks to humans, such as a contagious outbreak or a combat situation. For more routine daily use, R2 could function as an assistant to the hospital staff.

Posted in: Briefs, Medical

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Rapid Polymer Sequencer

Solid-state nanopore-based analysis of nucleic acid polymers is revolutionary. No other technique can determine information content in single molecules of genetic material at speeds of 1 subunit per microsecond. Since individual molecules are counted, the output is intrinsically quantitative. The nanopore approach is more generalized than any other method and may be used to analyze any polymer molecule, applying nanofabrication, nanoelectronic components, and high-speed signal acquisition. Geometry of the solid-state nanopore (less than 5 nm in length and 5 nm in diameter) will enable 1-5 nucleotide resolution measurements. This means that maximum resolution will be improved by 100-fold compared to biological ion-channel measurements. The solid-state nanopore sensor will permit sequencing DNA at a much faster rate, along with analyzing electronic properties of individual subunits of DNA or RNA, to obtain linear composition of each genetic polymer molecule.

Posted in: Briefs, Medical

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Computer-Controlled Solid-State Lighting Assembly to Emulate Diurnal Cycle and Improve Circadian Rhythm Control

John F. Kennedy Space Center, Florida The Lighting System to Improve Circadian Rhythm Control was designed and built to help regulate the sleep cycles of astronauts working on the International Space Station (ISS) and during long-duration spaceflight. In space, the lack of a true diurnal cycle of sunlight, encompassing the same range of color temperatures and intensities of sunlight experienced on Earth, is one of the potential causes of sleep disorders among the crew aboard ISS. The production of melatonin, a hormone that helps regulate sleep cycles, can be inhibited by light, especially cool white light (with its large blue light component). To help regulate sleep cycles and improve the quality of sleep for the crew, control of the melatonin production cycle through the use of light is key. On Earth, this technology can be used to help treat many sleep disorders, including jet lag, shift work sleep disorder, delayed sleep phase syndrome, advance sleep phase syndrome, and non-24-hour sleep/wake disorder (frequently affects those who are totally blind since the circadian clock is set by the light-dark cycle over a 24-hour period).

Posted in: Briefs, Medical

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Capillary Driven Microorganism Cultivation Platform for Human Life Support

SABR is a novel microbial cell cultivation platform that mimics the way vascular plants use transpiration to deliver nutrients to their cells. Ames Research Center, Moffett Field, California The high water-to-biomass ratio characteristic of conventional algae cultivation systems requires large energy inputs for pumping and mixing the culture during cultivation, as well as for dewatering and harvesting the resultant biomass. In light of this challenge, the Surface- Adhering BioReactor (SABR) cultivates micro-organisms as densely packed biofilms rather than in suspension, leading to an approximately 100-fold reduction in the water-to-biomass ratio of the system. Moreover, the mechanism of nutrient delivery to the cells is completely passive, eliminating the need for a pump. This mechanism is also independent of gravitational and inertial forces, making it an ideal candidate for human life support in space. The SABR is ideally suited for cultivating shear-sensitive cells, which can be product-secreting candidates due to their potential lack of cell walls. It reduces the number of steps in the cascade of cultivation, harvesting, dewatering, and extraction, favorably impacting the energetic and economic sustainability.

Posted in: Briefs, Medical

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Device and Method for Healing Wounds

The electroactive bandage is a slim, self-contained alternative to electrical stimulation devices. Langley Research Center, Hampton, Virginia This technology is a device that uses electrical activity to facilitate the wound healing process while protecting the wound. The bandage is made of an electroactive material (see figure) that is stimulated by the heat of the body and the pressure of cell growth, thus no external power source is required.

Posted in: Briefs, Medical

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