Abstract: Payload systems for processing chemical substances under various gravity levels, such as hypergravity and/or microgravity. The payload systems may include a hypergravity thermal payload system configured to enable melt or cooling of a sample under hypergravity. Alternatively, or in addition, the payload systems may include a gravity-independent thermal payload system for enabling melt or cooling of a sample under various gravity levels, such as microgravity. Alternatively, or in addition, the payload systems may include a hypergravity crystallization payload system configured to enable crystallization of a chemical substance under hypergravity. Alternatively, or in addition, the payload systems may include a gravity-independent crystallization system configured to enable crystallization of a chemical substance in various gravity levels, such as microgravity.

Abstract: Payload systems for processing chemical substances under various gravity levels, such as hypergravity and/or microgravity. The payload systems may include a hypergravity thermal payload system configured to enable melt or cooling of a sample under hypergravity. Alternatively, or in addition, the payload systems may include a gravity-independent thermal payload system for enabling melt or cooling of a sample under various gravity levels, such as microgravity. Alternatively, or in addition, the payload systems may include a hypergravity crystallization payload system configured to enable crystallization of a chemical substance under hypergravity. Alternatively, or in addition, the payload systems may include a gravity-independent crystallization system configured to enable crystallization of a chemical substance in various gravity levels, such as microgravity.

Abstract: Payload systems for processing chemical substances under various gravity levels, such as hypergravity and/or microgravity. The payload systems may include a hypergravity thermal payload system configured to enable melt or cooling of a sample under hypergravity. Alternatively, or in addition, the payload systems may include a gravity-independent thermal payload system for enabling melt or cooling of a sample under various gravity levels, such as microgravity. Alternatively, or in addition, the payload systems may include a hypergravity crystallization payload system configured to enable crystallization of a chemical substance under hypergravity. Alternatively, or in addition, the payload systems may include a gravity-independent crystallization system configured to enable crystallization of a chemical substance in various gravity levels, such as microgravity.

Abstract: Payload systems for processing chemical substances under various gravity levels, such as hypergravity and/or microgravity. The payload systems may include a hypergravity thermal payload system configured to enable melt or cooling of a sample under hypergravity. Alternatively, or in addition, the payload systems may include a gravity-independent thermal payload system for enabling melt or cooling of a sample under various gravity levels, such as microgravity. Alternatively, or in addition, the payload systems may include a hypergravity crystallization payload system configured to enable crystallization of a chemical substance under hypergravity. Alternatively, or in addition, the payload systems may include a gravity-independent crystallization system configured to enable crystallization of a chemical substance in various gravity levels, such as microgravity.

Abstract: The present disclosure discloses systems and methods for measuring the bladder volume of a patient. An ultrasound transducer array may be used to transmit electrical pulses and receive the backscattered pulses that can be analyzed to develop a representation of the patients bladder. The backscattered ultrasound signals may be amplified, converted, and processed by circuitry and computer software to develop an axial position of the anterior and posterior bladder walls. Bladder volume measurements derived from the patients bladder may then be wirelessly transmitted to a display device for assessment by a healthcare provider. The ultrasound transducer array portion of the device may be held in place between the patients peritoneum and pubis by an elastic strap or a belt to ensure proper positioning.

Abstract: Vibration sources are applied to a body or other object to image a region of interest. The mechanical vibrations introduced by the sources interfere in the region of interest to produce a crawling wave, which is detected by an ultrasound probe A relationship between crawling wave phase derivatives and local shear wave velocity is derived with phase derivatives estimated using either one-dimensional (1D) or two-dimensional (2D) autocorrelation-based techniques to image the region of interest.

Abstract: Vibration sources are applied to a body or other object to image a region of interest. The mechanical vibrations introduced by the sources interfere in the region of interest to produce a crawling wave, which is detected by an ultrasound probe A relationship between crawling wave phase derivatives and local shear wave velocity is derived with phase derivatives estimated using either one-dimensional (1D) or two-dimensional (2D) autocorrelation-based techniques to image the region of interest.

Abstract: The invention relates to methods of using fragmented RNA, such as RNA obtained from archived fixed paraffin-embedded tissue material (FPET RNA) or other clinically biopsied tissue specimens for universal gene expression profiling.

Abstract: The present invention relates to compositions and methods for enhanced cytokine production in human cell culture, particularly under conditions where apoptotic cell death is suppressed by expression of CrmA.