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11

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Exposed high-voltage source effect on the potential of an ionospheric satellite (1988)

Murphy, G. B. ; D&apos;Angelo, N. ; Steinberg, J. T. ; [et al.]

In: Other Sources

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Publication Date: 2019-07-12

Description: A pulsed, high-voltage source, which is able to draw a current from the surrounding plasma, is seen to induce large changes in the potential of an ionospheric satellite (the Iowa Plasma Diagnostics Package flown on Space Shuttle flight STS-51F). This, in turn, may affect the operation of other instruments that use the chassis of the satellite as a ground for electrical circuits. The magnitude of the change in satellite potential is dependent upon both the orientation of the high-voltage source, relative to the plasma flow, and the characteristics of the high-voltage source. When the satellite is grounded to the Shuttle Orbiter, this effect is sufficient to change the potential of the Orbiter by a small, but noticeable, amount.

Keywords: PLASMA PHYSICS

Type: Journal of Spacecraft and Rockets (ISSN 0022-4650); 25; 64-69

Format: text

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12

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Effect of Artificial Gravity: Central Nervous System Neurochemical Studies (1997)

Fox, Robert A. ; D&apos;Amelio, Fernando ; Eng, Lawrence F.

In: CASI

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Publication Date: 2019-08-15

Description: The major objective of this project was to assess chemical and morphological modifications occurring in muscle receptors and the central nervous system of animals subjected to altered gravity (2 x Earth gravity produced by centrifugation and simulated micro gravity produced by hindlimb suspension). The underlying hypothesis for the studies was that afferent (sensory) information sent to the central nervous system by muscle receptors would be changed in conditions of altered gravity and that these changes, in turn, would instigate a process of adaptation involving altered chemical activity of neurons and glial cells of the projection areas of the cerebral cortex that are related to inputs from those muscle receptors (e.g., cells in the limb projection areas). The central objective of this research was to expand understanding of how chronic exposure to altered gravity, through effects on the vestibular system, influences neuromuscular systems that control posture and gait. The project used an approach in which molecular changes in the neuromuscular system were related to the development of effective motor control by characterizing neurochemical changes in sensory and motor systems and relating those changes to motor behavior as animals adapted to altered gravity. Thus, the objective was to identify changes in central and peripheral neuromuscular mechanisms that are associated with the re-establishment of motor control which is disrupted by chronic exposure to altered gravity.

Keywords: Aerospace Medicine

Type: NASA-CR-205046 , NAS 1.26:205046

Format: application/pdf

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13

Unknown

Long-Duration Space Flight Provokes Pathologic Q-Tc Interval Prolongation (2002)

Dougherty, Anne H. ; DeBlock, Heidi F. ; D&apos;Aunno, DOminick S. ; [et al.]

In: CASI

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Publication Date: 2019-07-12

Description: Space flight has a profound influence on the cardiovascular and autonomic nervous systems. Alterations in baroreflex function, plasma catecholamine concentrations, and arterial pressure regulation have been observed. Changes in autonomic regulation of cardiac function may lead to serious rhythm disturbances. In fact, ventricular tachycardia has been reported during long-duration space flight. The study aim was to determine the effects of space flight on cardiac conduction. Methods and Results: Electrocardiograms (ECGs) and serum electrolytes were obtained before and after short-duration (SD) (4-16 days) and long-duration (LD) (4-6 months) missions. Holter recordings were obtained from 3 different subjects before, during and after a 4-month mission. P-R, R-R, and Q-T intervals were measured manually in a random, blinded fashion and Bazzet's formula used to correct the Q-T interval (Q-Tc). Space flight had no clinically significant effect on electrolyte concentrations. P-R and RR intervals were decreased after SD flight (p〈0.05) and recovered 3 days after landing. In the same subjects, P-R and Q-Tc intervals were prolonged after LD flight (p〈0.01). Clinically significant Q-Tc prolongation (〉0.44 sec) occurred during the first month of flight and persisted until 3 days after landing (p〈0.01). Conclusions - Space flight alters cardiac conduction with more ominous changes seen with LD missions. Alterations in autonomic tone may explain ECG changes associated with space flight. Primary cardiac changes may also contribute to the conduction changes with LD flight. Q-Tc prolongation may predispose astronauts to ventricular arrhythmias during and after long-duration space flight.

Keywords: Aerospace Medicine

Type: JSC-CN-7371

Format: application/pdf

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14

Unknown

The effect of a magnetic field gradient on anode double layers (1992)

Merlino, R. L. ; Song, B. ; D&apos;Angelo, N.

In: Other Sources

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Publication Date: 2019-08-27

Description: In experiments on anode (ionization) double layers in nonuniform magnetic fields it has been noted that the magnetic field gradient seems to stabilize the double layer position. This effect is further investigated in a Q machine in which the magnetic field geometry could be varied. It is found that the position of the double layers, along the axis of the device, could be controlled by changing the magnetic geometry. This effect is accounted for in a physical model which takes into account the effect of ion reflection by the magnetic mirror force in the region of magnetic field nonuniformity. This model is also able to account for variation of the double layer position when the neutral gas pressure is varied.

Keywords: PLASMA PHYSICS

Type: Physica Scripta (ISSN 0031-8949); 45; 395-398

Format: text

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15

Unknown

On the stability of strong double layers (1992)

D&apos;Angelo, N. ; Song, Bin ; Merlino, R. L.

In: Other Sources

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Publication Date: 2019-08-27

Description: For a strong, stationary double layer to be maintained, the electron flux Phi(e) and the ion flux Phi(i) must satisfy the Langmuir condition Phi(e)/Phi(i) = sq rt m(i)/m(e). However, this condition alone does not determine whether or not the double layer will remain in stable equilibrium at a given position. A new stability condition is obtained, and the results of several laboratory double layer experiments are examined using this condition.

Keywords: PLASMA PHYSICS

Type: Physica Scripta (ISSN 0031-8949); 45; 391-394

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16

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Jumping in simulated and true microgravity: response to maximal efforts with three landing types (2005)

Perry, Julie ; Perusek, Gail P. ; Davis, Brian L. ; [et al.]

In: Other Sources

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Publication Date: 2019-07-13

Description: BACKGROUND: Exercise is a promising countermeasure to the physiological deconditioning experienced in microgravity, but has not proven effective in eliminating the ongoing loss of bone mineral, most likely due to the lack of high-impact forces and loading rates during in-flight activity. We wanted to determine lower-extremity response to high-impact jumping exercises in true and simulated microgravity and establish if 1-G force magnitudes can be achieved in a weightless environment. METHODS: Jumping experiments were performed in a ground-based zero-gravity simulator (ZGS) in 1 G, and during parabolic flight with a gravity-replacement system. There were 12 subjects who participated in the study, with 4 subjects common to both conditions. Force, loading rates, jump height, and kinematics were analyzed during jumps with three distinct landings: two-footed toe-heel, one-footed toe-heel, and flat-footed. Gravity replacement loads of 45%, 60%, 75%, and 100% bodyweight were used in the ZGS; because of time constraints, these loads were limited to 60% and 75% bodyweight in parabolic flight. RESULTS: Average peak ground-reaction forces during landing ranged between 1902+/-607 and 2631+/-663 N in the ZGS and between 1683+/-807 and 2683+/-1174 N in the KC-135. No significant differences were found between the simulated and true microgravity conditions, but neither condition achieved the magnitudes found in 1 G. CONCLUSION: Data support the hypothesis that jumping exercises can impart high-impact forces during weightlessness and that the custom-designed ZGS will replicate what is experienced in true microgravity.

Keywords: Aerospace Medicine

Type: Aviation, space, and environmental medicine (ISSN 0095-6562); 76; 5; 441-7

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