Control of red blood cell mass during spaceflight

Data are reviewed from twenty-two astronauts from seven space missions in a study of red blood cell mass. The data show that decreased red cell mass in all astronauts exposed to space for more than nine days, although the actual dynamics of mass changes varies with flight duration. Possible mechanisms for these changes, including alterations in erythropoietin levels, are discussed.     

Antibiotic efficacy and microbial virulence during space flight

Human space flight is a complex undertaking that entails numerous technological and biomedical challenges. Engineers and scientists endeavor, to the extent possible, to identify and mitigate the ensuing risks. The potential for an outbreak of an infectious disease in a spacecraft presents one such concern, which is compounded by several components unique to an extraterrestrial environment. Various factors associated with the space flight environment have been shown to potentially compromise the immune system of astronauts, increase microbial proliferation and microflora exchange, alter virulence and decrease antibiotic effectiveness. An acceptable resolution of the above concerns must be achieved to ensure safe and efficient space habitation. To help bring this about, scientists are employing advances in biotechnology to better characterize the relevant variables and establish appropriate solutions. Because many of these clinical concerns are also relevant in terrestrial society, this research will have reciprocal benefits back on Earth.     

Space radiation does not induce a significant increase of intrachromosomal exchanges in astronauts’ lymphocytes

Chromosome aberration analysis in astronauts has been used to provide direct, biologically motivated estimates of equivalent doses and risk associated to cosmic radiation exposure during space flight. However, the past studies concentrated on measurements of dicentrics and translocations, while chromosome intrachanges (inversions) have never been measured in astronauts’ samples. Recent data reported in the literature suggest that densely ionizing radiation can induce a large fraction of intrachanges, thus leading to the suspicion that interchanges grossly underestimate the cosmic radiation-induced cytogenetic damage in astronauts. We have analyzed peripheral blood lymphocytes from 11 astronauts involved in short- or long-term space flights in low-Earth orbit using high-resolution multicolor banding to assess the frequency of intrachromosomal exchanges in both pre- and post-flight samples. We did not detect any inversions in chromosome 5 from a total of 2800 cells in astronauts’ blood. In addition, no complex type exchanges were found in a total of 3590 astronauts’ lymphocytes analyzed by multifluor fluorescence in situ hybridisation. We conclude that, within the statistical power of this study, the analysis of interchanges for biological dosimetry in astronauts does not significantly underestimate the space radiation-induced cytogenetic damage, and complex-type exchanges or intrachanges have limited practical use for biodosimetry at very low doses.     

Is Autonomic Modulation Different between European and Chinese Astronauts?

Purpose

The objective was to investigate autonomic control in groups of European and Chinese astronauts and to identify similarities and differences.

Methods

Beat-to-beat heart rate and finger blood pressure, brachial blood pressure, and respiratory frequency were measured from 10 astronauts (five European taking part in three different space missions and five Chinese astronauts taking part in two different space missions). Data recording was performed in the supine and standing positions at least 10 days before launch, and 1, 3, and 10 days after return. Cross-correlation analysis of heart rate and systolic pressure was used to assess cardiac baroreflex modulation. A fixed breathing protocol was performed to measure respiratory sinus arrhythmia and low-frequency power of systolic blood pressure variability.

Results

Although baseline cardiovascular parameters before spaceflight were similar in all astronauts in the supine position, a significant increase in sympathetic activity and a decrease in vagal modulation occurred in the European astronauts when standing; spaceflight resulted in a remarkable vagal decrease in European astronauts only. Similar baseline supine and standing values for heart rate, mean arterial pressure, and respiratory frequency were shown in both groups. Standing autonomic control was based on a balance of higher vagal and sympathetic modulation in European astronauts.

Conclusion

Post-spaceflight orthostatic tachycardia was observed in all European astronauts, whereas post-spaceflight orthostatic tachycardia was significantly reduced in Chinese astronauts. The basis for orthostatic intolerance is not apparent; however, many possibilities can be considered and need to be further investigated, such as genetic diversities between races, astronaut selection, training, and nutrition, etc.     

Effects of long-term microgravity exposure in space on circadian rhythms of heart rate variability

We evaluated their circadian rhythms using data from electrocardiographic records and examined the change in circadian period related to normal RR intervals for astronauts who completed a long-term (≥6-month) mission in space. The examinees were seven astronauts, five men and two women, from 2009 to 2010. Their mean?±?SD age was 52.0?±?4.2 years (47–59?yr). Each stayed in space for more than 160 days; their average length of stay was 172.6?±?14.6 days (163–199 days). We conducted a 24-h Holter electrocardiography before launch (Pre), at one month after launch (DF1), at two months after launch (DF2), at two weeks before return (DF3), and at three months after landing (Post), comparing each index of frequency-domain analysis and 24-h biological rhythms of the NN intervals (normal RR intervals). Results show that the mean period of Normal Sinus (NN) intervals was within 24?±?4?h at each examination. Inter-individual variability differed among the stages, being significantly smaller at DF3 (Pre versus DF1 versus DF3 versus Post?=?22.36?±?2.50 versus 25.46?±?4.37 versus 22.46?±?1.75 versus 26.16?±?7.18?h, p?<?0.0001). The HF component increased in 2 of 7 astronauts, whereas it decreased in 3 of 7 astronauts and 1 was remained almost unchanged at DF1. During DF3, about 6 months after their stay in space, the HF component of 5 of 7 astronauts recovered from the decrease after launch, with prominent improvement to over 20% in 3 astronauts. Although autonomic nervous functions and circadian rhythms were disturbed until one month had passed in space, well-scheduled sleep and wake rhythms and meal times served as synchronizers.     

Physiological analysis of the possible causes of hypoxemia under conditions of weightlessness

It was found that the partial oxygen tension in the capillary blood in astronauts during a space flight was 12–30% lower than that before the space flight. Analysis of the possible causes and mechanisms of hypoxemia was performed, which made it possible to conclude that an increase in the venous blood flow that passes through the lungs and does not undergo complete gas exchange in the pulmonary capillaries is most likely to be the main cause of the decrease in the oxygen tension in the blood in astronauts under conditions of weightlessness.     

Effect of microgravity on plasma catecholamine responses to stressors during space flight

The effect of microgravity on the sympathicoadrenal system (SAS) activity in humans and animals has not yet been clarified. Our previous studies suggested that the SAS activity, evaluated by circulating and/or urinary catecholamine (CA) levels in astronauts during space flights, was found to be rather unchanged. However, CA levels were measured in astronauts only at rest conditions. The aim of the present study was to investigate effect of microgravity during space flight and post-flight readaptation on responsiveness of the SAS to somatic and psychic stressors evaluated by levels of catecholamines and their metabolite in the blood of the Slovak cosmonaut during his stay on board the space station Mir.     

Relationship between stroke volume and sympathetic nerve activity: new insights about autonomic mechanisms of syncope

Head-up tilt table experiments conducted in astronauts prior to and immediately after the NASA Neurolab Space Mission (STS-90) revealed that a reduction in stroke volume induced by moving from the supine to upright posture was associated with increased muscle sympathetic nerve activity (MSNA). Although this finding was not unexpected, lower average stroke volume and greater average MSNA measured after space flight in both supine and upright postures were positioned in a linear fashion on the same stroke volume-MSNA stimulus-response relationship as the average pre-flight stroke volume and MSNA responses. Since all astronauts who participated in the Neurolab orthostatic experiments completed the 10-min tilt table tests, these observations supported the notion that sympathetic reflex responses were not altered but functioned adequately after space flight in non-presyncopal subjects. In contrast to the Neurolab results, development of orthostatic hypotension and presyncopal events reported in astronauts during standing after space flight have been accompanied by attenuated peripheral vasoconstriction and less elevation in plasma concentrations of norepinephrine. The association between circulating norepinephrine (NE) and peripheral vascular resistance in presyncopal astronauts after space flight led to the conclusion that postflight presyncope can be attributed to a combination of inherently low-resistance responses, a strong dependence on volume status, and relative hypoadrenergic function. In the present investigation, we used graded levels of lower body negative pressure (LBNP) to produce linear reductions in stroke volume and performed direct measurements of MSNA to test the hypotheses that (1) elevations in MSNA during central hypovolemia are proportional (i.e., linear) with reductions in stroke volume and; (2) that the slope of the stroke volume-MSNA relationship will be reduced in presyncopal subjects.     

Effects of a Closed Space Environment on Gene Expression in Hair Follicles of Astronauts in the International Space Station

Adaptation to the space environment can sometimes pose physiological problems to International Space Station (ISS) astronauts after their return to earth. Therefore, it is important to develop healthcare technologies for astronauts. In this study, we examined the feasibility of using hair follicles, a readily obtained sample, to assess gene expression changes in response to spaceflight adaptation. In order to investigate the gene expression changes in human hair follicles during spaceflight, hair follicles of 10 astronauts were analyzed by microarray and real time qPCR analyses. We found that spaceflight alters human hair follicle gene expression. The degree of changes in gene expression was found to vary among individuals. In some astronauts, genes related to hair growth such as FGF18, ANGPTL7 and COMP were upregulated during flight, suggesting that spaceflight inhibits cell proliferation in hair follicles.     

Effect of Microgravity on Fungistatic Activity of an α-Aminophosphonate Chitosan Derivative against Aspergillus niger

Biocontamination within the international space station is ever increasing mainly due to human activity. Control of microorganisms such as fungi and bacteria are important to maintain the well-being of the astronauts during long-term stay in space since the immune functions of astronauts are compromised under microgravity. For the first time control of the growth of an opportunistic pathogen, Aspergillus niger, under microgravity is studied in the presence of α-aminophosphonate chitosan. A low-shear modelled microgravity was used to mimic the conditions similar to space. The results indicated that the α-aminophosphonate chitosan inhibited the fungal growth significantly under microgravity. In addition, the inhibition mechanism of the modified chitosan was studied by UV-Visible spectroscopy and cyclic voltammetry. This work highlighted the role of a bio-based chitosan derivative to act as a disinfectant in space stations to remove fungal contaminants.     

Lipid peroxidation rate and the antioxidant protection system during the readaptation period after long-term space flights on board the International Space Station

The content of lipid peroxidation (LPO) products (diene conjugates (DC), malondialdehyde (MDA), Schiff bases (SB), and tocopherol (TP, a main lipid antioxidant) were measured in blood serum of 17 astronauts taking part in long-term (125–217 days) missions on board the International Space Station (ISS) during the preflight period, on the day of the landing, and on the 7th and 14th days after landing (the rehabilitation period, RP). A decrease in the DC and MDA levels against a background of an increase in TP has been found in a group of eight astronauts after landing on board the Space Shuttle spacecraft and a group of eight astronauts after a space flight on board the Soyuz TM in the course of RP. The changes in measured indices were more pronounced in the group of astronauts after the space flight on board the Space Shuttle spacecraft. Inhibition of LPO during RP was regarded as an adequate response to readaptation stress to the conditions on earth. The possible mechanisms of differences in the efficiency of LPO inhibition between groups are discussed: the changes in the biomembrane phase state under the conditions of deceleration load during disorbiting and the stressful reaction to landing on board different spacecrafts.     

Radiation exposure limits for Japanese astronauts

Starting in 2001, Japanese astronauts will live aboard the International Space Station (ISS) for 3 to 6 months a year. For astronauts, space radiation is primarily hazardous. Therefore, the National Space Development Agency of Japan (NASDA) is developing a system for Space Radiation Safety Operations. This report describes our overall image of Space Radiation Safety Operations aboard the ISS, especially our proceedings in drafting the "Space Radiation Exposure Limits for Japanese ISS Astronauts."     

Bone markers during a 6-month space flight: effects of vitamin K supplementation

Rapid bone loss is a serious health problem for astronauts during long lasting missions in space. We have recorded the changes of biochemical markers for bone metabolism in one of the astronauts during the 6-month space flight of the EUROMIR-95 mission. Immediately after launch both bone resorption markers and urinary calcium excretion increased about two fold, whereas bone formation markers remained unchanged. After 12 1/2 weeks the astronaut received vitamin K1 (10 mg/day for 6 weeks). Vitamin K is known to be involved in the formation of gamma-carboxyglutamate (Gla) in proteins, such as the calcium-binding bone Gla-proteins osteocalcin and matrix Gla-protein. Concomitant with the start of vitamin K treatment, the calcium-binding capacity of osteocalcin increased, and so did the urinary excretion of free Gla. This is suggestive for a subclinical vitamin K-deficiency in the astronaut before vitamin K-supplementation. During periods of high vitamin K status markers for bone formation (osteocalcin and bone alkaline phosphatase) had increased as compared to the first part of the flight. The mean increases were 14 and 23%, respectively. Our data suggest that increased intake of vitamin K may contribute to counteracting microgravity-induced loss of bone mass during long lasting space missions, but need confirmation in more astronauts.     

Pharmacologic Protection in Distant Space: Current View

Biology Bulletin - The radiation risk for astronauts in long space flights depends on the impact of low-intensity galactic and solar radiation on the spaceship. There is a small possibility of high...     

A sustained hyper-g load as a tool to simulate space sickness

In April 1989 the three European scientist astronauts of the D1 Spacelab Mission were exposed to a 1.5 hours +3G centrifuge run in supine position, resulting in a linear acceleration along the subjects' x-axis. Afterwards, severe motion sickness symptoms were provoked by head movements (Sickness Induced by Centrifugation: SIC). The astronauts mentioned close similarities with what they experienced in space during the D1-Spacelab Mission in 1985, where head movements also provoked motion sickness symptoms (Space Adaptation Syndrome: SAS). Moreover, the astronauts agreed that the rank order of their susceptibility to SAS was the same as for SIC. It was therefore postulated that with this method SAS could be simulated on earth. Additionally, in otolith function tests following the centrifuge run, changes in visual-vestibular interaction were observed, which replicated objective findings obtained with the same astronauts immediately after the D1 Spacelab Mission. During the last couple of years a series of experiments has been carried out to determine the nature of the stimulus causing SIC, the incidence of SIC, and the underlying cardio-vascular and/or vestibular mechanisms. These experiments were carried out on several astronauts and some 50 'normal' healthy subjects. In the next sections the main findings of all these experiments and the implications are summarized.     

空间环境下肠道菌群失调的研究进展

空间环境中的特殊因素会导致航天员肠道菌群及其代谢产物的失调，对机体会产生系统性的生理影响。本文综述了近年来太空飞行/模拟空间环境对肠道菌群及其代谢产物影响的研究进展。太空飞行/模拟空间环境（space flight/simulated space environment，SF/SPE）可导致侵袭性致病菌的增多及有益菌的减少，肠道炎症加剧与通透性增加，也会引起菌群的有益代谢物减少或有害代谢物增加，进而导致机体内代谢的紊乱，或可诱发其他系统的损伤，从而不利于航天员的健康与工作效率。总结太空飞行/模拟空间环境对肠道菌群产生的影响，可为该领域的后续研究与航天员的在轨健康防护提供科学依据。     

Autoflora in the upper respiratory tract of Apollo astronauts.

The typical microbial inhabitants of the oral and nasal cavities of Apollo astronauts were identified before space flight and generally found to be similar to those previously reported for healthy male adults. Additional analyses of samples collected immediately after return of the Apollo 13, 14, 15, and 16 crew members to earth were performed to evaluate the effects of space travel on the microbial bioburden of the upper respiratory tract. In-flight cross-contamination and buildup of pathogens such as Staphylococcus aureus were noted, although significant increases in nonpathogenic species were absent. Other proposed alterations, such as dysbacteriosis (flooding of the mouth with a single species) and simplification of the autoflora, did not occur. Generally, the incidence and quantitation of each species after flight was within the preflight range, although the number of viable Haemophilus cells recovered from the mouth decreased significantly after space flight. Except for those minor alterations listed above, the aerobic and anaerobic bacterial components of the upper respiratory autoflora of Apollo astronauts was found to be stable after space flight of up to 295 h.     

Frustrated by lack of job opportunities in Canada,MD moves to US space-medicine program

A Canadian physician-engineer who had difficulty finding suitable work in Canada is now employed by an American company that is helping develop the medical systems that will serve astronauts. Dr. Douglas Hamilton thinks research in space medicine will have applications on earth.     

亚磁场及其生物响应机制

根据亚磁生物学的研究历史和空间亚磁环境的实际情况,本文定义磁感应强度总量在“0<|B|≤5 μT”区间内的静态弱磁场为亚磁场．亚磁场能对生命活动的多个方面,特别是中枢神经系统产生负面影响．随着月球与火星航天计划的开展,航天员将长期暴露于亚磁空间中．这可能对宇航员的身心健康带来潜在的危害．亚磁场生物学效应及其机制的研究,将为相关载人航天的空间防护提供理论基础,已成为空间生物科学以及航天医学等相关领域的新热点．