Your search keyword '"Sams, Clarence"' showing total 10 results

1. Mechanistic Clues to Overcome Spaceflight-Induced Immune Dysregulation.

Author

Makedonas, George, Chouker, Alexander, Mehta, Satish, Simpson, Richard, Stowe, Raymond, Sams, Clarence, Pierson, Duane, and Crucian, Brian

Published

2018

2. Flow Cytometry Methods to Monitor Immune Dysregulation Associated with Spaceflight.

Author

Crucian, Brian and Sams, Clarence

Published

2012

3. Adaptive Immunity and Spaceflight.

Author

Crucian, Brian and Sams, Clarence

Published

2012

4. Immunologic Concerns.

Author

Barratt, Michael R., Pool, Sam L., Sams, Clarence F., and Pierson, Duane L.

Abstract

The human immune system is composed of a complex set of specialized cells, chemicals, and organ systems that interact to protect the host from pathogenic challenge and aberrant tissue growth. The immune system consists of two major elements: innate immunity and acquired immunity. The innate or nonspecific immunity includes the phagocytes and natural killer cells as well as chemical factors (lysozyme, complement, etc.) that act to control extra-cellular pathogens. Resistance of this system to pathogenic entities is not adaptive and is not increased by repeated exposure. The acquired immune system itself consists of two functional components: humoral immunity and cell-mediated immunity. These elements adapt and become more responsive with repeated exposure to pathogens. Simplistically, the humoral immune system encompasses protein factors (antibodies) that bind and neutralize their antigen targets and the specific cells (B cells) that produce the antibodies. The cell-mediated immune system includes the T cells which regulate many aspects of overall immune response and directly provide self vs. non-self discrimination. This system is critical to the control of intracellular pathogens (such as viruses) and the containment and elimination of malignant cells. These elements interact to protect the host from a broad range of medical threats. Defects in immune function can result in three distinct failure modes: (1) immunodeficiency, where the immune system fails to contain infections, (2) autoimmunity, an inappropriate response to self antigens that damages the host, and (3) hypersensitivity, an over-reaction of the immune system to innocuous foreign antigens. Any of these failures can have a significant medical impact on crewmembers during space flight. Precise regulation of immune function is critical because an overly active immune system can be just as damaging as an unresponsive one. Finally, the interplay of immune changes and environmental exposures in space flight (e.g., radiation, chemical exposures) can also induce long-term health risks for the crewmember. [ABSTRACT FROM AUTHOR]

Published

2008

5. Artificial Gravity And The Immune System Function.

Author

Wertz, James R., Doré, Roland, Larson, Wiley J., Logsdon, Tom, Markley, Landis, Melton, Robert G., Ninomiya, Keiken, Pocha, Jehangir J., Shuster, Malcolm D., Squibb, Gael, Sweeting, Martin, Clément, Gilles, Bukley, Angie, Mehta, Satish, Crucian, Brian, Pierson, Duane, Sams, Clarence, and Stowe, Raymond

Published

2007

6. Immune System Dysregulation Occurs During Short Duration Spaceflight On Board the Space Shuttle.

Author

Crucian, Brian, Stowe, Raymond, Mehta, Satish, Uchakin, Peter, Quiriarte, Heather, Pierson, Duane, and Sams, Clarence

Subjects

IMMUNOLOGIC diseases, SPACE shuttles, PHYSIOLOGICAL stress, BLOOD testing, T cells, CELL-mediated cytotoxicity

Abstract

Background: Post-flight data suggests immunity is dysregulated immediately following spaceflight, however this data may be influenced by the stress effects of high-G entry and readaptation to terrestrial gravity. It is unknown if immunity is altered during spaceflight. Methods: Blood samples were collected from 19 US Astronauts onboard the Space Shuttle ~24 h prior to landing and returned for terrestrial analysis. Assays consisted of leukocyte distribution, T cell blastogenesis and cytokine production profiles. Results: Most bulk leukocyte subsets (WBC, differential, lymphocyte subsets) were unaltered during spaceflight, but were altered following landing. CD8+ T cell subsets, including cytotoxic, central memory and senescent were altered during spaceflight. T cell early blastogenesis varied by culture mitogen. Functional responses to staphylococcal enterotoxin were reduced during and following spaceflight, whereas response to anti-CD3/28 antibodies was elevated post-flight. The level of virus specific T cells were generally unaltered, however virus specific T cell function was depressed both during and following flight. Plasma levels of IFNα, IFNγ, IL-1β, IL-4, IL-10, IL-12, and TNFα were significantly elevated in-flight, while IL-6 was significantly elevated at R + 0. Cytokine production profiles following mitogenic stimulation were significantly altered both during, and following spaceflight. Specifically, production of IFNγ, IL-17 and IL-10 were reduced, but production of TNFα and IL-8 were elevated during spaceflight. Conclusions: This study indicates that specific parameters among leukocyte distribution, T cell function and cytokine production profiles are altered during flight. These findings distinguish in-flight dysregulation from stress-related alterations observed immediately following landing. [ABSTRACT FROM AUTHOR]

Published

2013

7. Latent virus reactivation in astronauts on the international space station.

Author

Mehta, Satish K., Laudenslager, Mark L., Stowe, Raymond P., Crucian, Brian E., Feiveson, Alan H., Sams, Clarence F., and Pierson, Duane L.

Abstract

Reactivation of latent herpes viruses was measured in 23 astronauts (18 male and 5 female) before, during, and after long-duration (up to 180 days) spaceflight onboard the international space station. Twenty age-matched and sex-matched healthy ground-based subjects were included as a control group. Blood, urine, and saliva samples were collected before, during, and after spaceflight. Saliva was analyzed for Epstein–Barr virus, varicella-zoster virus, and herpes simplex virus type 1. Urine was analyzed for cytomegalovirus. One astronaut did not shed any targeted virus in samples collected during the three mission phases. Shedding of Epstein–Barr virus, varicella-zoster virus, and cytomegalovirus was detected in 8 of the 23 astronauts. These viruses reactivated independently of each other. Reactivation of Epstein–Barr virus, varicella-zoster virus, and cytomegalovirus increased in frequency, duration, and amplitude (viral copy numbers) when compared to short duration (10 to 16 days) space shuttle missions. No evidence of reactivation of herpes simplex virus type 1, herpes simplex virus type 2, or human herpes virus 6 was found. The mean diurnal trajectory of salivary cortisol changed significantly during flight as compared to before flight (P = 0.010). There was no statistically significant difference in levels of plasma cortisol or dehydoepiandosterone concentrations among time points before, during, and after flight for these international space station crew members, although observed cortisol levels were lower at the mid and late-flight time points. The data confirm that astronauts undertaking long-duration spaceflight experience both increased latent viral reactivation and changes in diurnal trajectory of salivary cortisol concentrations. Virus reactivation in long-duration spaceflight: Long-duration spaceflight increases the reactivation of latent herpes viruses in astronauts and is accompanied by a rise in stress hormone levels. This study shows that the frequency and viral loads of reactivation of Epstein-Barr virus, varicella-zoster virus, and cytomegalovirus were even greater in blood, urine, and saliva samples from astronauts staying 60 to 180 days onboard the International Space Station than has previously been observed for short-duration (10–16 days) missions. Changes in viral reactivation were also found to be associated with changes in the daily trajectory of salivary cortisol during these long-duration missions. These results indicate that the effects of the microgravity environment on the immune system are increased with prolonged exposure and highlight the potential increased risk of infection among crewmembers. [ABSTRACT FROM AUTHOR]

Published

2017

8. Three-dimensional organotypic co-culture model of intestinal epithelial cells and macrophages to study Salmonella enterica colonization patterns.

Author

Barrila, Jennifer, Yang, Jiseon, Crabbé, Aurélie, Sarker, Shameema F., Liu, Yulong, Ott, C. Mark, Nelman-Gonzalez, Mayra A., Clemett, Simon J., Nydam, Seth D., Forsyth, Rebecca J., Davis, Richard R., Crucian, Brian E., Quiriarte, Heather, Roland, Kenneth L., Brenneman, Karen, Sams, Clarence, Loscher, Christine, and Nickerson, Cheryl A.

Abstract

Three-dimensional models of human intestinal epithelium mimic the differentiated form and function of parental tissues often not exhibited by two-dimensional monolayers and respond to Salmonella in key ways that reflect in vivo infections. To further enhance the physiological relevance of three-dimensional models to more closely approximate in vivo intestinal microenvironments encountered by Salmonella, we developed and validated a novel three-dimensional co-culture infection model of colonic epithelial cells and macrophages using the NASA Rotating Wall Vessel bioreactor. First, U937 cells were activated upon collagen-coated scaffolds. HT-29 epithelial cells were then added and the three-dimensional model was cultured in the bioreactor until optimal differentiation was reached, as assessed by immunohistochemical profiling and bead uptake assays. The new co-culture model exhibited in vivo-like structural and phenotypic characteristics, including three-dimensional architecture, apical-basolateral polarity, well-formed tight/adherens junctions, mucin, multiple epithelial cell types, and functional macrophages. Phagocytic activity of macrophages was confirmed by uptake of inert, bacteria-sized beads. Contribution of macrophages to infection was assessed by colonization studies of Salmonella pathovars with different host adaptations and disease phenotypes (Typhimurium ST19 strain SL1344 and ST313 strain D23580; Typhi Ty2). In addition, Salmonella were cultured aerobically or microaerobically, recapitulating environments encountered prior to and during intestinal infection, respectively. All Salmonella strains exhibited decreased colonization in co-culture (HT-29-U937) relative to epithelial (HT-29) models, indicating antimicrobial function of macrophages. Interestingly, D23580 exhibited enhanced replication/survival in both models following invasion. Pathovar-specific differences in colonization and intracellular co-localization patterns were observed. These findings emphasize the power of incorporating a series of related three-dimensional models within a study to identify microenvironmental factors important for regulating infection. Modeling intestinal infection with NASA biotechnology: A new 3-D intestinal co-culture model with macrophages to study enteric infection Using spaceflight analog bioreactor technology, Cheryl Nickerson at Arizona State University and collaborators developed and validated a new three-dimensional (3-D) intestinal co-culture model containing multiple differentiated epithelial cell types and phagocytic macrophages with antibacterial function to study infection by multiple pathovars of Salmonella. This study is the first to show that these pathovars (known to possess different host adaptations, antibiotic resistance profiles and disease phenotypes), display markedly different colonization and intracellular co-localization patterns using this physiologically relevant new 3-D intestinal co-culture model. This advanced model, that integrates a key immune cell type important for Salmonella infection, offers a powerful new tool in understanding enteric pathogenesis and may lead to unexpected pathogenesis mechanisms and therapeutic targets that have been previously unobserved or unappreciated using other intestinal cell culture models. [ABSTRACT FROM AUTHOR]

Published

2017

9. Evaluation of techniques for performing cellular isolation and preservation during microgravity conditions.

Author

Rizzardi LF, Kunz H, Rubins K, Chouker A, Quiriarte H, Sams C, Crucian BE, and Feinberg AP

Abstract

Genomic and epigenomic studies require the precise transfer of microliter volumes among different types of tubes in order to purify DNA, RNA, or protein from biological samples and subsequently perform analyses of DNA methylation, RNA expression, and chromatin modifications on a genome-wide scale. Epigenomic and transcriptional analyses of human blood cells, for example, require separation of purified cell types to avoid confounding contributions of altered cellular proportions, and long-term preservation of these cells requires their isolation and transfer into appropriate freezing media. There are currently no protocols for these cellular isolation procedures on the International Space Station (ISS). Currently human blood samples are either frozen as mixed cell populations (within the CPT collection tubes) with poor yield of viable cells required for cell-type isolations, or returned under ambient conditions, which requires timing with Soyuz missions. Here we evaluate the feasibility of translating terrestrial cell purification techniques to the ISS. Our evaluations were performed in microgravity conditions during parabolic atmospheric flight. The pipetting of open liquids in microgravity was evaluated using analog-blood fluids and several types of pipette hardware. The best-performing pipettors were used to evaluate the pipetting steps required for peripheral blood mononuclear cell (PBMC) isolation following terrestrial density-gradient centrifugation. Evaluation of actual blood products was performed for both the overlay of diluted blood, and the transfer of isolated PBMCs. We also validated magnetic purification of cells. We found that positive-displacement pipettors avoided air bubbles, and the tips allowed the strong surface tension of water, glycerol, and blood to maintain a patent meniscus and withstand robust pipetting in microgravity. These procedures will greatly increase the breadth of research that can be performed on board the ISS, and allow improvised experimentation by astronauts on extraterrestrial missions., Competing Interests: The authors declare no conflict of interest.

Published

2016

10. Alterations in adaptive immunity persist during long-duration spaceflight.

Author

Crucian B, Stowe RP, Mehta S, Quiriarte H, Pierson D, and Sams C

Abstract

Background: It is currently unknown whether immune system alterations persist during long-duration spaceflight. In this study various adaptive immune parameters were assessed in astronauts at three intervals during 6-month spaceflight on board the International Space Station (ISS)., Aims: To assess phenotypic and functional immune system alterations in astronauts participating in 6-month orbital spaceflight., Methods: Blood was collected before, during, and after flight from 23 astronauts participating in 6-month ISS expeditions. In-flight samples were returned to Earth within 48 h of collection for immediate analysis. Assays included peripheral leukocyte distribution, T-cell function, virus-specific immunity, and mitogen-stimulated cytokine production profiles., Results: Redistribution of leukocyte subsets occurred during flight, including an elevated white blood cell (WBC) count and alterations in CD8 + T-cell maturation. A reduction in general T-cell function (both CD4 + and CD8 + ) persisted for the duration of the 6-month spaceflights, with differential responses between mitogens suggesting an activation threshold shift. The percentage of CD4 + T cells capable of producing IL-2 was depressed after landing. Significant reductions in mitogen-stimulated production of IFNγ, IL-10, IL-5, TNFα, and IL-6 persisted during spaceflight. Following lipopolysaccharide (LPS) stimulation, production of IL-10 was reduced, whereas IL-8 production was increased during flight., Conclusions: The data indicated that immune alterations persist during long-duration spaceflight. This phenomenon, in the absence of appropriate countermeasures, has the potential to increase specific clinical risks for crewmembers during exploration-class deep space missions., Competing Interests: DP is a NASA Virologist and CS and BC are NASA Immunologists. All remaining authors possess positions (contractor scientist) at, or are funded by, NASA. The remaining authors declare no conflict of interest.

Published

2015