航天飞行后心血管失调的外周效应器机制假说

作者及其同事曾用尾部悬吊大鼠模型模拟失重时的血液头向转移和重新分布变化,较系统地研究了模拟失重下心肌与动脉血管结构和功能的适应性改变。联系２０世纪９０年代空间研究与地面模拟研究最新进展,多们认为,除血量减少因素外,心血管系统的两个主要效应器－心肌和动脉血管平滑肌,在失重时发生的适应性结构和功能改变可能是导致航天飞行后心血管失调的重要原因之一。     

The water-salt balance and renal function in space flights and in model experiments

Study of a condition of mineral and water-electrolyte metabolism, function of kidneys, and their hormonal regulation during model experiments (hypokinesia, bed rest, immersion etc.), and also in space flights and in readaptation period, has shown a major role of water-electrolyte homeostasis during general adaptation of humans and animals to new conditions of life and to conditions of weightlessness in particular. The change in regulation of volumes of fluid milieu in an initial period of weightlessness was shown to be the consequence of redistribution of blood and hemodynamics of the shifts resulting in change of production of volume-regulation hormones, formation of negative water balance, and redistribution of fluid in the organism among various fluid compartments. At later stages of flight or long-term hypokinesia, a change of water-electrolyte homeostasis occurs with a decrease in the kidneys excretion of sodium, and diuresis, but with an increased excretion of calcium and production of ADH and RAAS hormones. Following returning to earth gravitation, the majority of astronauts have adaptive reactions, compensating for the loss extracellular fluid and mineral substances and formation of "earth" water-electrolyte homeostasis. For estimation of water-electrolyte homeostasis and the functions of kidneys in astronauts, various functional loading tests have been developed. The developed system of preventive maintenance is successfully used for abolition of adverse changes at various stages of space flight and in readaptation period.     

Cardiovascular changes in prolonged space flights

In prolonged manned space flights, the cardiovascular function was examined at rest and during provocative tests. As compared to the preflight data the following changes were seen: higher heart rate at rest and during LBNP tests, decrease of stroke volume at rest and during LBNP test and a less marked increase (or decrease) during exercise tests, symptoms of a greater heart load which transformed to the syndrome of myocardial hypodynamics (preload) during LBNP tests or to the syndrome of myocardial hyperdynamics (afterload) during exercise tests (with other than preflight ratios of systolic and diastolic time intervals). The above cardiovascular changes did not, as a rule, aggravate with flight time and can be viewed as adaptive reactions to microgravity. The above cardiovascular changes were primarily produced by fluid redistribution in the cranial direction, diminished participation of the muscle system in circulation, and involvement of unloading reflexes from the cardiopulmonary receptor zones.     

Alterations in glomerular and tubular dynamics at 1 and 14 days simulated microgravity and after acute return to orthostasis

Head-down tilt (HDT) is utilized to simulate microgravity and produces a cephalad fluid shift, which results in alterations in fluid and electrolyte balance. These changes in volume homeostasis are due, in part, to alterations in multiple volume control mechanisms in which renal function is a major participant. We have previously demonstrated that glomerular filtration rate increases early in HDT and eventually returns to values not different from non-tilt measurements. This early increase in glomerular filtration rate was also demonstrated during days 2 and 8 of the SLS-1 mission. However, urine flow and electrolyte excretion does not parallel the alterations in glomerular filtration rate and the site of this change in nephron fluid reabsorption pattern has not been previously examined. Through determination of the location of alterations in tubular fluid reabsorption within the nephron, a more detailed hypothesis can be forwarded as to which specific neuro-humoral agents participating in control of renal function in microgravity conditions. The importance of this type of examination is that measurements in circulating neuro-humoral agents and urinary excretion patterns alone are not accurate predictors of how renal functional response may alter to head-down tilt or other models of simulated weightlessness. To examine this issue, renal micropuncture techniques were utilized in Munich-Wistar rats submitted 24 hours and 14 day head-down tilt, measuring all the determinants of glomerular ultrafiltration and obtaining data regarding segmental tubular fluid reabsorption. Following these measurements, the rats were returned to an orthostatic position and after 60 min, the measurements were repeated.     

Weightlessness simulations for cardiovascular and muscle systems: validity of rat models

Animal models are widely used to evoke responses comparable to those obtained during weightlessness. Two models are reviewed; one examines cardiovascular responses and cephalad fluid shifts in head down tilting (HDT), and the other examines atrophy in load bearing muscles by unloading the hind limbs. Cephalad fluid shifts result in diuresis, natriuresis, and kaliuresis. Reversals are rapid, within one week. Reports of cardiovascular responses are not similar among various laboratories, probably due to variations in protocols. Blood pressures (MAP, SP and DP) and heart rates measured with direct aorta cannulations become elevated as early as one and three days of HDT; recovery occurs within several hours; the response is a transient hypertension. The role of central and peripheral sympathetic nervous activity in flight and suspended rats is examined. Rats show little or no evidence of cardiac deconditioning. Direct blood pressures have not been made in flight rats, precluding direct comparisons with earth side experiments. Muscle atrophy and load bearing (slow twitch fibers) and non-load bearing (fast twitch fibers) muscle responses with hind limb unloading and recovery are compared with flight animal responses. Soleus muscle in response to whole body suspension (WBS), tail suspension (TS) or flight exposure consistently shows significant weight loss. In contrast, the extensor digitorum longus and vastus medialis show less marked responses. More specifically, slow twitch fibers in all these muscles show the greatest loss in mass (e.g. cross sectional areas). The conclusion is that both WBS or TS systems are useful in predicting and comparing changes due to weightless flight.     

Morphological and biochemical examination of Cosmos 1887 rat heart tissue: Part I--Ultrastructure

Morphological changes were observed in the left ventricle of rat heart tissue from animals flown on the Cosmos 1887 biosatellite for 12.5 days. These tissues were compared to the synchronous and vivarium control hearts. While many normal myofibrils were observed, others exhibited ultrastructural alterations, i.e., damaged and irregular-shaped mitochondria and generalized myofibrillar edema. Analysis of variance (ANOVA) of the volume density data revealed a statistically significant increase in glycogen and a significant decrease in mitochondria compared to the synchronous and vivarium controls. Point counting indicated an increase in lipid and myeloid bodies and a decrease in microtubules, but these changes were not statistically significant. In addition, the flight animals exhibited some patchy loss of protofibrils (actin and myosin filaments) and some abnormal supercontracted myofibrils that were not seen in the controls. This study was undertaken to gain insight into the mechanistic aspects of cardiac changes in both animals and human beings as a consequence of space travel (1). Cardiac hypotrophy and fluid shifts have been observed after actual or simulated weightlessness and raise concerns about the functioning of the heart and circulatory system during and after travel in space (2-4).     

Effect of weightlessness and artificial gravitation on thyroid gland morphology]

The investigation of the thyroid gland was carried out in Wistar rats, SPF colony 4.5--13 h and 25 days after a 18.5 days flight on board the space biosatellite "Cosmos-936". In animals subjected to weightlessness, moderate symptoms of the thyroid hypofunction were observed, statistically significant decrease in number and volume of the nuclei in calcitonin-secreting cells (C-cells) was especially pronounced during 4.5--9 h after landing. Similar but less pronounced changes were observed in C-cells of the rats subjected to artificial conditions of space flight, besides weightlessness. The similarity of the changes in the animals of both groups made it possible to connect the increasing amount of C-cells and the morphological symptoms of their functional inhibition with the effect of weightlessness and hypokinesia. During the space flight, the animals were kept under the conditions of artificial gravitation on board the biosatellite and therefore morphological peculiarities specific for the earth conditions were preserved in C-cells and the thyroid gland. Thus, it was concluded that artificial gravitation prevented the development of the thyroid changes which appeared under the influence of weightlessness.     

模拟失重大鼠肠系膜小动脉平滑肌细胞电压依赖性钙离子通道电流的改变

本工作旨在探讨短、中期模拟失重下人鼠肠系膜小动脉血管平滑肌细胞(vascular smooth muscle cells,VSMCs)电压依赖性钙离子通道(voltage-dependent calcium channels,VDC)功能的改变。以尾部悬吊大鼠模型模拟失重对不同部位血管的影响。采用全细胞膜片钳实验技术,以Ba^2 作为载流子,测定1周及4周模拟失重人鼠肠系膜小动脉VSMCs的VDC电流密度、稳态激活与失活曲线及有关参数,并与对照组结果进行比较。研究表明,本实验所记录到的内向电流主要为钡离子通过长时程VDC(L-VDC)所形成的电流。与对照组相比,1周模拟失重大鼠肠系膜小动脉VSMCs的L-VDc电流密度仪呈降低趋势;但4周模拟失重人鼠肠系膜小动脉VSMCs的L-VDC电流密度则已显著降低。此外,与对照组相比,1、4周模拟失重大鼠肠系膜小动脉VSMCs的膜电容、翻转电位与L-VDC的一些动力学特征值,如通道的开放与关闭速率,通道电流稳态激活与火活曲线及其特征拟合参数V0.5与K的值,均末见有显著改变。结果提示：模拟失重下后身小动脉VSMCs的VDC功能降低可能是模拟失重引起人鼠后身动脉收缩反应性降低及适应性萎缩变化的电生理机制之一。     

模拟失重大鼠心肌与血管组织的热应激诱导HSP70表达

为研究模拟失重是否可以引起大鼠心肌与血管组织HSP70的诱导表达发生改变,用尾部悬吊大鼠模型模拟失重,以研究失重对生理的影响,用Northern杂交与Western印迹分析检测4周模拟失重大鼠热应激后并在室温下恢复1h(SUS-H1)或2h(SUS-H2_心肌,血管组织HSP70表达的变化,结果表明,热应激后,各组大鼠心肌组织的HSP72 mRNA表达的均显著增加,但SUS－H2大鼠心肌组织的表达显著低于CON－H2组;各组大鼠心肌组织HSP72表达也均显著增加,但SUS－H1与SUS－H2大鼠的表达与相应对照组相比,则仅呈降低趋势,其底动脉血管组织的HSP72 mRNA与HSP72诱导表达均显著增高,而在股动脉则两者仅呈降低趋势,上述结果提示,模拟失重可导致大鼠心肌发生类似衰老的心肌改变;身体前,后部血管组织HSP70的诱导表达变化可能与血管的分化性适应方向一致。     

Effects of changes in left ventricular contractility on indexes of contractility in mice

Measurement of left ventricular (LV) function is often overlooked in murine studies, which have been used to analyze the effects of genetic manipulation on cardiac phenotype. The goal of this study was to address the effects of changes in LV contractility on indexes of contractility in mice. LV function was assessed in vivo in closed-chest mice by echocardiography and by LV catheterization using a conductance pressure-volume (P-V) catheter with three different interventions that alter contractility by 1) atrial pacing to increase inotropy by augmentation of the force-frequency relation (modest increment of inotropy), 2) dobutamine to maximize inotropy, and 3) esmolol infusion to decrease contractility. Load-independent parameters derived from P-V relations, such as slope of end-systolic P-V relations (ESPVR) and slope of the first maximal pressure derivative over time (dP/dt(max))-end-diastolic volume relation (dP/dt-EDV), and standard echocardiographic parameters were measured. The dP/dt-EDV changed the most among parameters after atrial pacing and dobutamine infusion (percent change, 162.8 +/- 95.9% and 271.0 +/- 44.0%, respectively). ESPVR was the most affected by a decrease in LV contractility during esmolol infusion (percent change, -49.8 +/- 8.3%). However, fractional shortening failed to detect changes in contractility during atrial pacing and esmolol infusion and its percent change was <20%. This study demonstrated that contractile parameters derived from P-V relations change the most during a change in LV contractility and should therefore best detect a small change in contractility in mice. Heart rate has a modest but significant effect on P-V relationship-derived indexes and must be considered in the evaluation of murine cardiac physiology.     

Heat shock protein 70 expression in myocardium is blunted with simulated weightlessness

Exposure of cardiac cells to a mild thermal or ischaemic stress, sufficient to induce HSP expression, protects them against a subsequent exposure to a more severe ischaemic stress. Over expression of HSPs by transfection of herpes simplex virus vectors in vitro or in transgenic animal in vivo can protect primary cardiac cells from subsequent exposure to severe thermal or hypoxic stress. The increases in myocardial and liver HSP70 accumulation in response to nonexertional heat stress are attenuated with senescence, and hearts from aged animals exhibit an impaired ability to produce the protective HSP. In our previous work, peculiar changes associated with aging, like lipofuscin accumulation and collagen deposition were shown in the myocardial tissue of long-term simulated weightless rats. We therefore designed the present study to examine whether the heat-stress induced HSP70 accumulation in myocardial tissue may decline with simulated weightlessness.     

Preserved contractile function despite atrophic remodeling in unloaded rat hearts

The present study was designed to determine whether myocardial atrophy is necessarily associated with changes in cardiac contractility. Myocardial unloading of normal hearts was produced via heterotopic transplantation in rats. Contractions of isolated myocytes (1.2 mM Ca2+; 37 degrees C) were assessed during field stimulation (0.5, 1.0, and 2.0 Hz), and papillary muscle contractions were assessed during direct stimulation (2.0 mM Ca2+; 37 degrees C; 0.5 Hz). Hemodynamic unloading was associated with a 41% decrease in median myocyte volume and proportional decreases in myocyte length and width. Nevertheless, atrophic myocytes had normal fractional shortening, time to peak contraction, and relaxation times. Despite decreases in absolute maximal force generation (F(max)), there were no differences in F(max)/ area in papillary muscles isolated from unloaded transplanted hearts. Therefore, atrophic remodeling after unloading is associated with intact contractile function in isolated myocytes and papillary muscles when contractile indexes are normalized to account for reductions in cell length and cross-sectional area, respectively. Nevertheless, in the absence of compensatory increases in contractile function, reductions in myocardial mass will lead to impaired overall work capacity.     

Effects of insulin perfusion and altered glucose concentrations on heart function in 3-day and 6-week diabetic rats

Diabetes is known to result in depression of myocardial function, whereas hearts from insulin-treated diabetic rats exhibit functional characteristics similar to controls. In the present study, we have studied the effect of insulin perfusion on cardiac performance of 3-day and 6-week streptozotocin (STZ) diabetic rats. Three days of diabetes did not result in depressed cardiac performance when the hearts were isolated and perfused in the working heart mode. Increasing the concentration of glucose from 5 to 10 mM in the perfusion fluid did not alter the function in either control or in diabetic rat hearts. However, when regular insulin or glucagon-free insulin (Humulin) (5 mU/mL) was included in the perfusion medium, the ventricular function of hearts from control rats was significantly enhanced, while diabetic myocardial function remained unaffected. When the study was repeated on hearts from 6-week diabetic animals, cardiac function of diabetic rats was significantly depressed as compared with controls. As in the 3-day study, contractility was not affected in either group by increasing glucose concentration in the perfusion medium. Again, inclusion of insulin in the medium enhanced cardiac contractility only in control hearts. These results suggest that diabetes results in a loss of myocardial sensitivity to insulin which seems to occur as early as 3 days after induction of diabetes with STZ. The study also demonstrates that the beneficial effects of in vivo insulin treatment on myocardial alterations induced by diabetes are not due to its direct myocardial effects.     

卧床前后压力感受性反射机能变化的研究

许多数据表明长期失重以后立位耐力降低可能与压力感受性反射功能的改变有关。本文比较了两组被试者15天低动力卧床前后的立位耐力。以血压调节模型为基础分析了两种不同方式卧床前后单纯立位和下身负压加立位时压力感受性反射功能的改变,并用颈部加压及下身负压对中枢调节功能改变进行了观察。结果表明严格的头低位卧床后,立位耐力下降及压力感受性反射功能改变明显大于半日平卧半日倚坐者。而压力感受性反射功能的改变,特别是中枢神经系统调节功能的紊乱,是卧床后立位耐力降低的主要原因。从这种考虑为基础,作者提出了改变失重或模拟失重状态下的血液分布,调整对压力感受器的刺激,可能是预防心血管失调的有效方法。     

Modulation of {beta}-adrenoceptor signaling in the hearts of 4-wk simulated weightlessness rats.

The modulation of beta-adrenoceptor signaling in the hearts of hindlimb unweighting (HU) simulated weightlessness rats has not been reported. In the present study, we adopted the rat tail suspension for 4 wk to simulate weightlessness; then the effects of simulated microgravity on beta-adrenoceptor signaling were studied. Mean arterial blood pressure (ABP), left ventricular pressure (LVP), systolic function (+dP/dtmax), and diastolic function (-dP/dtmax) were monitored in the course of the in vivo experiment. Single rat ventricular myocyte was obtained by the enzymatic dissociation method. Hemodynamics, myocyte contraction, and cAMP production in response to beta-adrenoceptor stimulation with isoproterenol or adenylyl cyclase stimulation with forskolin were measured, and Gs protein was also determined. Compared with the control group, no significant changes were found in heart weight, body weight and ABP, while LVP and +/-dP/dtmax were significantly reduced. The ABP decrease, LVP increase, and +/-dP/dtmax in response to isoproterenol administration were significantly attenuated in the HU group. The effects of isoproterenol on electrically induced single-cell contraction and cAMP production in myocytes of ventricles in the HU rats were significantly attenuated. The biologically active isoform, Gsalpha (45 kDa) in the heart, was unchanged. Both the increased electrically induced contraction and cAMP production in response to forskolin were also significantly attenuated in the simulated weightlessness rats. Above results indicated that impaired function of adenylyl cyclase causes beta-adrenoceptor desensitization, which may be partly responsible for the depression of cardiac function.     

Endocrine, renal, and circulatory influences on fluid and electrolyte homeostasis during weightlessness: a joint Russian-U.S. project

Microgravity is known to have a substantial effect on fluid homeostasis. The research described here was planned as part of the first joint Russian-U.S. science program carried out during a Shuttle flight. The aim of the program was to study the nature of the changes in fluid homeostasis induced by microgravity, as well as to determine the possible mechanisms underlying the regulation of fluid balance under conditions of spaceflight. To determine the effects of spaceflight on the homeostasis of fluid and electrolytes, measurements were taken of total body water, extracellular fluid plasma volumes, levels of regulatory hormones, and nutrient consumption before, during, and after a nine-day flight. Changes in renal function were studied before and after the flight. In these 2 subjects, weightlessness was not associated with a decreased extracellular fluid volume. However, there were the characteristic decreases in plasma atrial natriuretic peptide concentrations, and increases in plasma and urinary cortisol. Results indicated decreased urine volume, even through the first 48 hours of flight. Fluid volumes and glomerular filtration rate were increased after landing, probably related to the saline-loading countermeasure used by Shuttle crewmembers. The information obtained as a result of this research will facilitate the development of future research programs, as well as preventive measures for future long-duration spaceflights.     

Oral glucose tolerance tests in man during a 150-day space flight (Salyut 7-Soyuz T9)

This study was conducted on the pilot specialist of the Salyut 7-Soyuz T9 complex during a 150 days space flight. Glucose tolerance tests were made 3 days before flight, on days 60 and 88 during flight and on days 25 and 55 after flight. The study confirms the decrease of fasting plasma glucose observed during the 3 Skylab missions and demonstrates blunted glucose tolerance curves. The changes were not found during ground based studies using bed rest to simulate weightlessness state. The origin of this abnormality is discussed.     

The volume of extracellular fluid under conditions of long-term space flights

The volume of extracellular fluid (the bromine space) was determined in 18 cosmonauts 30 days before the start of a space flight and on the first day after landing. The duration of space flights on the Mir orbital station was from 126 to 438 days. Moreover, the volume of extracellular fluid was determined in seven cosmonauts directly during long-term space flights approximately two weeks before landing. After long-term space flights, the volume of extracellular fluid was decreased in all cosmonauts studied. The bromine space volume was significantly decreased compared to its initial preflight value. A decrease in the volume of extracellular fluid was caused not only by the reduction in the dense mass of the body but also by its dehydration. These processes developed independently of the duration of weightlessness but are mainly determined by the individual features of human beings.     

Effects of 30 day simulated microgravity and recovery on fluid homeostasis and renal function in the rat

Transition from a normal gravitational environment to that of microgravity eventually results in decreased plasma and blood volumes, increasing with duration of exposure to microgravity. This loss of vascular fluid is presumably due to negative fluid and electrolyte balance and most likely contributes to the orthostatic intolerance associated with the return to gravity. The decrease in plasma volume is presumed to be a reflection of a concurrent decrease in extracellular fluid volume with maintenance of normal plasma-interstitial fluid balance. In addition, the specific alterations in renal function contributing to these changes in fluid and electrolyte homeostasis are potentially responding to neuro-humoral signals that are not consistent with systemic fluid volume status. We have previously demonstrated an early increase in both glomerular filtration rate and extracellular fluid volume and that this decreases towards control values by 7 days of simulated microgravity. However, longer duration studies relating these changes to plasma volume alterations and the response to return to orthostasis have not been fully addressed. Male Wistar rats were chronically cannulated, submitted to 30 days head-down tilt (HDT) and followed for 7 days after return to orthostasis from HDT. Measurements of renal function and extracellular and blood volumes were performed in the awake rat.     

REGULATION OF HAEMOPOIESIS IN ALTERED GRAVITY

(1) The aetiology of one of the most striking physiological changes occurring during space-flight, the loss of red blood cells, remains unknown, and its precise time-pattern in flight has not yet been studied. (2) It is suggested that the changes during space-flight responsible for loss of red blood cells in man are (a) loss of plasma volume resulting from disappearance of hydrostatic pressure in the circulation during weightlessness and (b) reduced energy expended in maintenance of form, posture and locomotion resulting from elimination of the usual gravitational load on the muscles. Quadrupeds, like rats, would be expected to suffer minimal blood shifts in weightlessness and therefore have an unchanged plasma volume. However, since in weightlessness the activity-related energy expenditure by the muscles is reduced, the accompanying reduced oxygen demand by the tissues would cause a reduction in erythropoietin levels and so in the production of red blood cells, and a progressive lowering of the total red blood cell mass toward a new steady-state level. (3) Loss of plasma volume alone does not explain the observed loss of red blood cells in astronauts because, in the three manned Skylab missions, as the duration of the missions increased, loss of red blood cell mass decreased, whereas loss of plasma volume increased. This discrepancy is, however, well accounted for by the above hypothesis by taking into consideration the increased level of exercise of the astronauts as the duration of the mission increased. (4) Though water submersion of human subjects does mimic the effects of weightlessness, such effects were overriden in sea mammals because of adaptation to other factors associated with a life in the sea. (5) From the presented analysis of haemopoietic changes observed in spaceflight, an experiment can be designed for a future flight to uncover the causes and mechanisms of these changes and provide a basis for developing protective measures. Thus, the space environment can be used as an investigative tool to enhance the knowledge of the function of the haemopoietic system, which is a major homeostatic system of man and other vertebrates.