Contributions of severe burn and disuse to bone structure and strength in rats.

Burn and disuse results in metabolic and bone changes associated with substantial and sustained bone loss. Such loss can lead to an increased fracture incidence and osteopenia. We studied the independent effects of burn and disuse on bone morphology, composition and strength, and microstructure of the bone alterations 14days after injury. Sprague-Dawley rats were randomized into four groups: Sham/Ambulatory (SA), Burn/Ambulatory (BA), Sham/Hindlimb Unloaded (SH) and Burn/Hindlimb Unloaded (BH). Burn groups received a 40% total body surface area full-thickness scald burn. Disuse by hindlimb unloading was initiated immediately following injury. Bone turnover was determined in plasma and urine. Femur biomechanical parameters were measured by three-point bending tests and bone microarchitecture was determined by micro-computed tomography (uCT). On day 14, a significant reduction in body mass was observed as a result of burn, disuse and a combination of both. In terms of bone health, disuse alone and in combination affected femur weight, length and bone mineral content. Bending failure energy, an index of femur strength, was significantly reduced in all groups and maximum bending stress was lower when burn and disuse were combined. Osteocalcin was reduced in BA compared to the other groups, indicating influence of burn. The reductions observed in femur weight, BMC, biomechanical parameters and indices of bone formation are primarily responses to the combination of burn and disuse. These results offer insight into bone degradation following severe injury and disuse.

Tissue-specific variation in expression of prolactin receptor gene subtypes in hypergravity-exposed rats.

Prolactin (PRL) effects are mediated by membrane receptors (PRLR) of which the long (PRLR-L) and short form (PRLR-S) predominate. Our objective was to compare the distribution pattern of PRLR-L and PRLR-S transcripts and their ratio in adipose (AD), liver (LV), mammary (MG) and pituitary (PG) tissues of stationary (SC, n = 8) and hypergravity (HG, n = 8) exposed periparturient rats. Pregnant rats were exposed to 2 g force from day 11 of gestation (G11) through post partum day 1 (P1). PRLR-L mRNA expression compared to PRLR-S was greater (P < 0.001) in AD, MG and PG but was lower (P < 0.001) in LV in both HG and SC animals at P1. The ratio of PRLR-L/PRLR-S mRNA in the AD, LV, MG and PG was not different between HG and SC rats. In summary, these data reveal that the hypergravity-induced downregulation of PRLR is not directly triggered by deranged distribution of PRLR isoforms.

Effects of hypergravity on mammary metabolic function: gravity acts as a continuum.

Mammary metabolic activity in pregnant rats is significantly increased in response to spaceflight. To determine whether changes in mammary metabolism are related to gravity load, we exposed pregnant rats to hypergravity and measured mammary metabolic activity. From days 11-20 of gestation (G), animals were centrifuged (20 rpm; 1.5, 1.75, or 2.0 x gravity) or were maintained at 1 G. On G20, five rats from each group were removed from the centrifuge and euthanized. The remaining dams (n = 5/treatment) were housed at 1 G until parturition. After 2 h of nursing by the pups, the postpartum dams were euthanized (G22). Glucose oxidation to CO2 and incorporation into lipids was measured. Mammary glands from dams euthanized on G20 revealed a strong negative correlation between metabolic rate and increased G load. Approximately 98% of the variation in glucose oxidation and 94% of the variation in glucose incorporation into lipids can be accounted for by differences in G load. Differences in metabolic activity disappeared in the postpartum dams. When we combined previous data from the microgravity with hypergravity environments and plotted the ratio of mammary metabolic rate vs. G load, there was a significant exponential relationship (r2 = 0.99). These data demonstrate a remarkable continuum of response across the microgravity and hypergravity environments and support the concept that gravitational load influences mammary tissue metabolism.

Body mass, energy intake, and water consumption of rats and humans during space flight.

Alteration of metabolism has been suggested as a major limiting factor to long-term space flight. In humans and primates, a negative energy balance has been reported. The metabolic response of rats to space flight has been suggested to result in a negative energy balance. We hypothesized that rats flown in space would maintain energy balance as indicated by maintenance of caloric intake and body mass gain. Further, the metabolism of the rat would be similar to that of laboratory-reared animals. We studied the results from 15 space flights lasting 4 to 19 d. There was no difference in average body weight (206 +/- 13.9 versus 206 +/- 14.8 g), body weight gain (5.8 +/- 0.48 versus 5.9 +/- 0.56 g/d), caloric intake (309 +/- 21.0 versus 309 +/- 20.1 kcal/kg of body mass per day), or water intake (200 +/- 8.6 versus 199 +/- 9.3 mL/kg of body mass per day) between flight and ground control animals. Compared with standard laboratory animals of similar body mass, no differences were noted. The observations suggested that the negative balance observed in humans and non-human primates may be due to other factors in the space-flight environment.

Rate controlling steps in fatty acid oxidation by unloaded rodent soleus muscle.

In response to decreased usage skeletal muscle undergoes an adaptive reductive remodeling due to the decrease in tension on the weight bearing components of the musculo-skeletal system. Accompanying a shift in fiber type is an increased reliance of carbohydrate metabolism and decreased reliance on fat for energy. These responses have been found with both space flight and ground based models of disuse atrophy including the chronically adapted rodent hind limb suspended (HLS) rat (1, 4-7, 10, 11). In addition, after space flight, the ability of soleus muscle homogenates to oxidize palmitate is decreased. We have previously shown that expression of the mRNA of enzymes involved in beta-oxidation is reduced in the soleus muscle of HLS rats. At the same time mRNA expression of enzymes involved in glycolysis was increased. This study extends these observations to address the question of whether the decrease in beta-oxidation is caused by a reduction in the capacity of the pathway to oxidize fat or the regulation is effected before fatty acids enter the mitochondria, i.e. the reduced capacity of the fatty acid oxidation pathway is because less fat is available for oxidation. The two key steps involved in fatty acid uptake into the cells are lipoprotein lipase and the transport of the free fatty acids produced by lipoprotein lipase into the cell via the carnitine acyltransferase system.

Maternal reproductive experience enhances early postnatal outcome following gestation and birth of rats in hypergravity.

A major goal of space life sciences research is to broaden scientific knowledge of the influence of gravity on living systems. Recent spaceflight and centrifugation studies demonstrate that reproduction and ontogenesis in mammals are amenable to study under gravitational conditions that deviate considerably from those typically experienced on Earth (1 x g). In the present study, we tested the hypothesis that maternal reproductive experience determines neonatal outcome following gestation and birth under increased (hyper) gravity. Primigravid and bigravid female rats and their offspring were exposed to 1.5 x g centrifugation from Gestational Day 11 either through birth or through the first postnatal week. On the day of birth, litter sizes were identical across gravity and parity conditions, although significantly fewer live neonates were observed among hypergravity-reared litters born to primigravid dams than among those born to bigravid dams (82% and 94%, respectively; 1.0 x g controls, 99%). Within the hypergravity groups, neonatal mortality was comparable across parity conditions from Postnatal Day 1 through Day 7, at which time litter sizes stabilized. Maternal reproductive experience ameliorated neonatal losses during the first 24 h after birth but not on subsequent days, and neonatal mortality was associated with changes in maternal care patterns. These results indicate that repeated maternal reproductive experience affords protection against neonatal losses during exposure to increased gravity. Differential mortality of neonates born to primigravid versus bigravid dams denotes gravitational load as one environmental mechanism enabling the expression of parity-related variations in birth outcome.

Effects of hypergravity exposure on the developing central nervous system: possible involvement of thyroid hormone.

The present study examined the effects of hypergravity exposure on the developing brain and specifically explored the possibility that these effects are mediated by altered thyroid status. Thirty-four timed-pregnant Sprague-Dawley rats were exposed to continuous centrifugation at 1.5 G (HG) from gestational Day 11 until one of three key developmental points: postnatal Day (P) 6, P15, or P21 (10 pups/dam: 5 males/5 females). During the 32-day centrifugation, stationary controls (SC, n = 25 dams) were housed in the same room as HG animals. Neonatal body, forebrain, and cerebellum mass and neonatal and maternal thyroid status were assessed at each time point. The body mass of centrifuged neonates was comparatively lower at each time point. The mass of the forebrain and the mass of the cerebellum were maximally reduced in hypergravity-exposed neonates at P6 by 15.9% and 25.6%, respectively. Analysis of neonatal plasma suggested a transient hypothyroid status, as indicated by increased thyroid stimulating hormone (TSH) level (38.6%) at P6, while maternal plasma TSH levels were maximally elevated at P15 (38.9%). Neither neonatal nor maternal plasma TH levels were altered, suggesting a moderate hypothyroid condition. Thus, continuous exposure of the developing rats to hypergravity during the embryonic and neonatal periods has a highly significant effect on the developing forebrain and cerebellum and neonatal thyroid status (P < 0.05, Bonferroni corrected). These data are consistent with the hypothesized role of the thyroid hormone in mediating the effect of hypergravity in the developing central nervous system and begin to define the role of TH in the overall response of the developing organism to altered gravity.

Increases in body mass of rats during spaceflight: models and measurements.

To test the hypothesis that the body mass of rats is increased during spaceflight, we developed two models from the literature and obtained mass measurements during spaceflight. From studies of centrifugation (hypergravity), there is a reduction in body mass of rats dependent on the exposure gravity level. From data in 18 publications on rats subjected to hypergravity by centrifugation, we developed a model that predicted a 27% increase in body mass during the microgravity of spaceflight. Following spaceflight, with an increase in gravity on return to Earth, there is a reduction in body mass of rats for over 3 d. We related the reduction in body mass after spaceflight to the time after landing that mass measurements were made. From data in 23 publications on rats returning from spaceflight, we developed a model that predicted a 19% increase in body mass during spaceflight. Measurement of body mass of rats on days 6 and 10 of spaceflight found a 7 and 9% increase compared with ground control animals. The increase in body mass during spaceflight suggests that the rat may provide a viable model for metabolic studies in which changes during spaceflight may be predicted in part by ground-based hypergravity studies.

Body mass, food and water intake, and activity of pregnant and lactating rat dams during 1.5-g centrifugation.

In the present study, we analyzed the relationship between body mass, food and water intake, and behavioral activity in pregnant and lactating rat dams exposed to continuous, 1.5-g centrifugation for 32 days. The period of centrifugation spanned from Gestational day (G) 11 of the rats' 22-day pregnancy until Postnatal day (P) 21, the time of weaning.

Survival and growth of developing rats during centrifugation at 2G.

We studied the effects of 2G hypergravity on the survival, body mass and growth of postnatal rats (Rattus norvegicus). Nursing litters comprised of either neonatal (Postnatal day [P]7) or pre-weanling (P14) rats and their mothers were exposed to 16 days of continuous centrifugation. All of the offspring survived and gained body mass, indicating that mothers nursed their young. Following the onset of centrifugation, neonatal and pre-weanling rats showed a reduction in growth relative to age-matched environmental controls (EC). At the completion of testing, body mass of the hypergravity (HG) groups was significantly less than that of controls (p<0.05). Over the course of the test, the HG-exposed P7 group showed an overall 55% gain in body mass as compared to a 71% increase in controls, while the HG-exposed P14 group showed a 62% increase relative to 75% in controls. Neonatal offspring (P7) gained body mass during centrifugation, but at significantly slower rates as compared to EC controls (p<0.05). In contrast, growth rates of pre-weanling (P14) rats were not reduced relative to controls, possibly related to the initiation of weaning, around P18 in the rat. These findings raise key issues relevant to studies of nursing mammals reared in altered gravity.

Deposition and renal handling of urinary electrolytes from rats during spaceflight.

To study renal handling of urinary electrolytes from male Fisher 344 rats during spaceflight, waste pads were obtained from cages flown in space and from cages used for ground controls. Pads were obtained from cages in which animals were group-housed (n=6 animals/cage) (Animal Enclosure Module; AEM) for 12 days or individually housed (2 animals/divided cage) (Research Animal Holding Facility; RAHF) for 19 days. Pads were washed, and extracts analyzed for sodium, potassium, chloride, calcium, and creatinine concentrations. It was observed that spaceflight reduced the absolute concentrations of electrolytes deposited onto the pads. When adjustments were made for deposition on all cage surfaces during flight, electrolyte and creatinine concentrations were similar to those of controls. Specifically, there were no differences in the sodium-, potassium-, and chloride-to-creatinine ratios of flight and control animals, suggesting no difference in the renal handling of these electrolytes during spaceflight. The calcium-to-creatinine ratio of urine on flight waste pads was reduced, suggesting an increase in reabsorption. From these analyses, the renal handling of sodium, potassium, and chloride does not appear to be altered in rats during spaceflight, while that of calcium may be. Deposition of urine on all surfaces of the cages during spaceflight should be considered in the design of future animal habitats, and in future analyses of waste pad constituents.

Developmental testing of the Advanced Animal Habitat to determine compatibility with rats and mice.

The Research Animal Holding Facility (RAHF) and the Animal Enclosure Module (AEM) have housed rats during Space Shuttle flights since the 1980s, but the operational constraints of the hardware have limited the scientific return from these Shuttle flights. The RAHF provides environmental control and monitoring for 24 rats with in-flight animal access, but it must be flown in the Spacelab. Due to the infrequent availability of Spacelab flights, rodent experiments rely heavily on the AEM. Unfortunately, the AEM supports only six rats, has no environmental control and provides no animal access in flight. The Advanced Animal Habitat (AAH) is being developed to support up to 12 adult rats or 30 adult mice for up to 30 days, provide active temperature control, animal telemetry and on-orbit video, record environmental parameters in the animal cage, and provide in-flight animal access in the Middeck, the Spacelab or the Space Station. To ensure the AAH can meet these requirements, animal testing is being conducted with rats and mice in every step of development. Testing began with the cage configuration.