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Plant diversity increases with the strength of negative density dependence at the global scale (2017)

La; Manna, J. A., Mangan, S. A., Alonso, A., Bourg, N. A., Brockelman, W. Y., Bunyavejchewin, S., Chang, L.-W., Chiang, J.-M., Chuyong, G. B., Clay, K., Condit, R., Cordell, S., Davies, S. J., Furniss, T. J., Giardina, C. P., Gunatilleke, I. A. U. N., Gunatilleke, C. V. S., He, F., Howe, R. W., Hubbell, S. P., Hsieh, C.-F., Inman-Narahari, F. M., Janik, D., Johnson, D. J., Kenfack, D., Korte, L., Kral, K., Larson, A. J., Lutz, J. A., McMahon, S. M., McShea, W. J., Memiaghe, H. R., Nathalang, A., Novotny, V., Ong, P. S., Orwig, D. A., Ostertag, R., Parker, G. G., Phillips, R. P., Sack, L., Sun, I.-F., Tello, J. S., Thomas, D. W., Turner, B. L., Vela Diaz, D. M., Vrska, T., Weiblen, G. D., Wolf, A., Yap, S., Myers, J. A.

American Association for the Advancement of Science (AAAS)

In: Science

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Publication Date: 2017-06-30

Description: Theory predicts that higher biodiversity in the tropics is maintained by specialized interactions among plants and their natural enemies that result in conspecific negative density dependence (CNDD). By using more than 3000 species and nearly 2.4 million trees across 24 forest plots worldwide, we show that global patterns in tree species diversity reflect not only stronger CNDD at tropical versus temperate latitudes but also a latitudinal shift in the relationship between CNDD and species abundance. CNDD was stronger for rare species at tropical versus temperate latitudes, potentially causing the persistence of greater numbers of rare species in the tropics. Our study reveals fundamental differences in the nature of local-scale biotic interactions that contribute to the maintenance of species diversity across temperate and tropical communities.

Keywords: Ecology

Print ISSN: 0036-8075

Electronic ISSN: 1095-9203

Topics: Biology , Chemistry and Pharmacology , Geosciences , Computer Science , Medicine , Natural Sciences in General , Physics

Published by American Association for the Advancement of Science (AAAS)

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4-twist helix snake to maintain polarization in multi-GeV proton rings (2017)

F. Antoulinakis, Y. Chen, A. Dutton, E. Rossi De La Fuente, S. Haupert, E. A. Ljungman, P. D. Myers, J. K. Thompson, A. Tai, C. A. Aidala, E. D. Courant, A. D. Krisch, M. A. Leonova, W. Lorenzon, R. S. Raymond, D. W. Sivers, V. K. Wong, T. Yang, Y. S. Derbenev, V. S. Morozov, and A. M. Kondratenko

American Physical Society (APS)

In: Physical Review Special Topics - Accelerators and Beams

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Publication Date: 2017-09-28

Description: Author(s): F. Antoulinakis, Y. Chen, A. Dutton, E. Rossi De La Fuente, S. Haupert, E. A. Ljungman, P. D. Myers, J. K. Thompson, A. Tai, C. A. Aidala, E. D. Courant, A. D. Krisch, M. A. Leonova, W. Lorenzon, R. S. Raymond, D. W. Sivers, V. K. Wong, T. Yang, Y. S. Derbenev, V. S. Morozov, and A. M. Kondratenko Solenoid Siberian snakes have successfully maintained polarization in particle rings below 1 GeV, but never in multi-GeV rings, because the spin rotation by a solenoid is inversely proportional to the beam momentum. High energy rings, such as Brookhaven’s 255 GeV Relativistic Heavy Ion Collider (RHI... [Phys. Rev. Accel. Beams 20, 091003] Published Wed Sep 27, 2017

Keywords: High-Energy Accelerators and Colliders

Electronic ISSN: 1098-4402

Topics: Physics

Published by American Physical Society (APS)

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Tudor-SN-mediated endonucleolytic decay of human cell microRNAs promotes G1/S phase transition (2017)

Elbarbary, R. A., Miyoshi, K., Myers, J. R., Du, P., Ashton, J. M., Tian, B., Maquat, L. E.

American Association for the Advancement of Science (AAAS)

In: Science

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Publication Date: 2017-05-26

Description: MicroRNAs (miRNAs) are small noncoding RNAs that regulate gene expression. The pathways that mediate mature miRNA decay are less well understood than those that mediate miRNA biogenesis. We found that functional miRNAs are degraded in human cells by the endonuclease Tudor-SN (TSN). In vitro, recombinant TSN initiated the decay of both protein-free and Argonaute 2–loaded miRNAs via endonucleolytic cleavage at CA and UA dinucleotides, preferentially at scissile bonds located more than five nucleotides away from miRNA ends. Cellular targets of TSN-mediated decay defined using microRNA sequencing followed this rule. Inhibiting TSN-mediated miRNA decay by CRISPR-Cas9 knockout of TSN inhibited cell cycle progression by up-regulating a cohort of miRNAs that down-regulates mRNAs that encode proteins critical for the G 1 -to-S phase transition. Our study indicates that targeting TSN nuclease activity could inhibit pathological cell proliferation.

Keywords: Molecular Biology

Print ISSN: 0036-8075

Electronic ISSN: 1095-9203

Topics: Biology , Chemistry and Pharmacology , Geosciences , Computer Science , Medicine , Natural Sciences in General , Physics

Published by American Association for the Advancement of Science (AAAS)

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Computational Modeling of Space Physiology for Informing Spaceflight Countermeasure Design and Predictions of Efficacy (2017)

Nelson, E. S. ; Perusek, G. P. ; Nall, M. M. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: MOTIVATION: Spaceflight countermeasures mitigate the harmful effects of the space environment on astronaut health and performance. Exercise has historically been used as a countermeasure to physical deconditioning, and additional countermeasures including lower body negative pressure, blood flow occlusion and artificial gravity are being researched as countermeasures to spaceflight-induced fluid shifts. The NASA Digital Astronaut Project uses computational models of physiological systems to inform countermeasure design and to predict countermeasure efficacy.OVERVIEW: Computational modeling supports the development of the exercise devices that will be flown on NASAs new exploration crew vehicles. Biomechanical modeling is used to inform design requirements to ensure that exercises can be properly performed within the volume allocated for exercise and to determine whether the limited mass, volume and power requirements of the devices will affect biomechanical outcomes. Models of muscle atrophy and bone remodeling can predict device efficacy for protecting musculoskeletal health during long-duration missions. A lumped-parameter whole-body model of the fluids within the body, which includes the blood within the cardiovascular system, the cerebral spinal fluid, interstitial fluid and lymphatic system fluid, estimates compartmental changes in pressure and volume due to gravitational changes. These models simulate fluid shift countermeasure effects and predict the associated changes in tissue strain in areas of physiological interest to aid in predicting countermeasure effectiveness. SIGNIFICANCE: Development and testing of spaceflight countermeasure prototypes are resource-intensive efforts. Computational modeling can supplement this process by performing simulations that reduce the amount of necessary experimental testing. Outcomes of the simulations are often important for the definition of design requirements and the identification of factors essential in ensuring countermeasure efficacy.

Keywords: Aerospace Medicine

Type: GRC-E-DAA-TN41999 , Aerospace Medical Association Annual Scientific Meeting; Apr 29, 2017 - May 04, 2017; Denver, CO; United States

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Integrated Model of the Eye/Optic Nerve Head Biomechanical Environment (2017)

Samuels, B. ; Myers, J. G. ; Nelson, E. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: Visual Impairment and Intracranial Pressure (VIIP) syndrome is a concern for long-duration space flight. Previously, it has been suggested that ocular changes observed in VIIP syndrome are related to the cephalad fluid shift that results in altered fluid pressures [1]. We are investigating the impact of changes in intracranial pressure (ICP) using a combination of numerical models, which simulate the effects of various environment conditions, including finite element (FE) models of the posterior eye. The specific interest is to understand how altered pressures due to gravitational changes affect the biomechanical environment of tissues of the posterior eye and optic nerve sheath. METHODS: Additional description of the numerical modeling is provided in the IWS abstract by Nelson et al. In brief, to simulate the effects of a cephalad fluid shift on the cardiovascular and ocular systems, we utilized a lumped-parameter compartment model of these systems. The outputs of this lumped-parameter model then inform boundary conditions (pressures) for a finite element model of the optic nerve head (Figure 1). As an example, we show here a simulation of postural change from supine to 15 degree head-down tilt (HDT), with primary outcomes being the predicted change in strains at the optic nerve head (ONH) region, specifically in the lamina cribrosa (LC), retrolaminar optic nerve, and prelaminar neural tissue (PLNT). The strain field can be decomposed into three orthogonal components, denoted as the first, second and third principal strains. We compare the peak tensile (first principal) and compressive (third principal) strains, since elevated strain alters cell phenotype and induces tissue remodeling. RESULTS AND CONCLUSIONS: Our lumped-parameter model predicted an IOP increase of c. 7 mmHg after 21 minutes of 15 degree HDT, which agreed with previous reports of IOP in HDT [1]. The corresponding FEM simulations predicted a relative increase in the magnitudes of the peak tensile and compressive strains in the lamina cribrosa of 42 and 43, respectively (Fig. 2). The corresponding changes in the optic nerve strains were 17 and 39, while in the PLNT they were 47 and 43. These magnitudes of relative elevations in peak strains may induce a phenotypic response in resident mechano-responsive resident cells [2]. This approach may be expanded to investigate other environmental changes (e.g. parabolic flight). Through our VIIP SCHOLAR project, we will validate and improve these integrated models by measuring patient-specific changes in optic nerve sheath geometry in patients with idiopathic intracranial hypertension before and after lumbar puncture and CSF removal.

Keywords: Life Sciences (General); Aerospace Medicine

Type: GRC-E-DAA-TN38847 , 2017 NASA Human Research Program Investigators'' Workshop (HRP IWS 2017); Jan 23, 2017 - Jan 26, 2017; Galveston, TX; United States

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The Integrated Medical Model: Outcomes from Independent Review (2017)

Myers, J. ; Goodenow, D. A. ; Saile, L. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: No abstract available

Keywords: Statistics and Probability

Type: JSC-CN-38519 , 2017 NASA Human Research Program Investigators'' Workshop (HRP IWS 2017) Annual Meeting; Jan 23, 2017 - Jan 26, 2017; Galveston, TX; United States

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Modeling Microgravity Induced Fluid Redistribution Autoregulatory and Hydrostatic Enhancements (2017)

Samuels, B. ; Nelson, E. S. ; Raykin, J. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: Space flight induces a marked cephalad (headward) redistribution of blood and interstitial fluid potentially resulting in a loss of venous tone and reduction in heart muscle efficiency upon introduction into the microgravity environment. Using various types of computational models, we are investigating how this fluid redistribution may induce intracranial pressure changes, relevant to reported reductions in astronaut visual acuity, part of the Visual Impairment and Intracranial Pressure (VIIP) syndrome. Methods: We utilize a lumped parameter cardiovascular system (CVS) model, augmented by compartments comprising the cerebral spinal fluid (CSF) space, as the primary tool to describe how microgravity, and the associated lack of hydrostatic gradient, impacts fluid redistribution. Models of ocular fluid pressures and biomechanics then accept the output of the above model as boundary condition input to allow more detailed, local analysis (see IWS Abstract by Ethier et al.). Recently, we enhanced the capabilities our previously reported CVS model through the implementation of robust autoregulatory mechanisms and a more fundamental approach to the implementation of hydrostatic mechanisms. Modifying the approach of Blanco et al., we implemented auto-regulation in a quasi-static manner, as an averaged effect across the span of one heartbeat. This approach reduced the higher frequency perturbations from the regulatory mechanism and was intended to allow longer simulation times (days) than models that implement within-beat regulatory mechanisms (minutes). A more fundamental approach to hydrostatics was implemented by a quasi-1D approach, in which compartment descriptions include compartment length, orientation and relative position, allowed for modeling of body orientation, relative body positioning and, in the future, alternative gravity environments. At this time the inclusion of hydrostatic mechanisms supplies additional capabilities to train and validate the CVS model with terrestrial data. Results and Conclusions: With the implementation of auto-regulation and hydrostatic modeling capabilities, the model performs as expected in the maintaining the CA (Central Artery) compartment pressure when simulating orientations ranging from supine to standing. The model appears to generally overpredict heart rate and thus cardiac output, possibly indicating sensitivity to the nominal heart rate, which is used as an initial set point of the regulation mechanisms. Despite this sensitivity, the model performs consistently for many hours of simulation time, indicating the success of our quasi-static implementation approach.

Keywords: Aerospace Medicine

Type: GRC-E-DAA-TN38845 , NASA Human Research Program Investigators Workshop (HRP IWS 2017); Jan 23, 2017 - Jan 26, 2017; Galveston, TX; United States

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The Integrated Medical Model: Outcomes from Independent Review (2017)

Arellano, J. ; Walton, M. ; Young, M. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: In 2016, the Integrated Medical Model (IMM) v4.0 underwent an extensive external review in preparation for transition to an operational status. In order to insure impartiality of the review process, the Exploration Medical Capabilities Element of NASA's Human Research Program convened the review through the Systems Review Office at NASA Goddard Space Flight Center (GSFC). The review board convened by GSFC consisted of persons from both NASA and academia with expertise in the fields of statistics, epidemiology, modeling, software development, aerospace medicine, and project management (see Figure 1). The board reviewed software and code standards, as well as evidence pedigree associated with both the input and outcomes information. The board also assesses the models verification, validation, sensitivity to parameters and ability to answer operational questions. This talk will discuss the processes for designing the review, how the review progressed and the findings from the board, as well as summarize the IMM project responses to those findings. Overall, the board found that the IMM is scientifically sound, represents a necessary, comprehensive approach to identifying medical and environmental risks facing astronauts in long duration missions and is an excellent tool for communication between engineers and physicians. The board also found IMM and its customer(s) should convene an additional review of the IMM data sources and to develop a sustainable approach to augment, peer review, and maintain the information utilized in the IMM. The board found this is critically important because medical knowledge continues to evolve. Delivery of IMM v4.0 to the Crew Health and Safety (CHS) Program will occur in the 2017. Once delivered for operational decision support, IMM v4.0 will provide CHS with additional quantitative capability in to assess astronaut medical risks and required medical capabilities to help drive down overall mission risks.

Keywords: Statistics and Probability

Type: GRC-E-DAA-TN38711 , 2017 NASA Human Research Program Investigators'' Workshop (HRP IWS 2016); Jan 23, 2017 - Jan 26, 2017; Galveston, TX; United States

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