The Effects of Multiple Unloading Exposures on Bone Properties in the Femur of Adult Male Rats

Morgan, Derrick Scott

2012 May 1900

NASA goals include long-term International Space Station (ISS) missions and the ambitious objective of eventually sending astronauts to Mars. Unfortunately, exposure to unloading due to microgravity during spaceflight has been shown to cause detrimental health effects on bone. Therefore, NASA is seeking a ground-based animal model to study the long-term effects of unloading on bone in order to better insure the health and mission capability of astronauts. The hindlimb unloaded (HU) rat model was used to study the effects of multiple unloading exposures and aging on bone properties. Six month old, adult, male Sprague-Dawley rats were separated into the following groups: baseline (BL, sacrificed when received at 6 months age), aging cage control (AC, normal weight-bearing cage activity), 1HU7 (unloaded for 1 month starting at 7 months of age and allowed to recover for 3 months), 1HU10 (normal cage activity until 10 months of age, unloaded for 1 month, recovered for 2 months), and 2HU10 (unloaded for 1 month at 7 months of age, allowed to recover for 2 months, unloaded again for 1 month at 10 months of age, followed by 2 months of recovery). Every 28 days a subset of animals (n=15) were euthanized and both femurs were excised. A peripheral quantitative computed tomography (pQCT) scanner was used to collect densitometric and geometric properties at the right and left femoral neck and at the left femoral midshaft. Mechanical testing (axial and lateral compression of the femoral neck and 3pt bending of the midshaft) was performed at each location and strength indices based on pQCT parameters were calculated. Femoral neck properties decreased due to HU but recovered with respect to increase over HU, BL, and AC by the end of the recovery periods. Femoral midshaft properties were relatively unaffected, but did show slight decreases for older animals at month 10, which recovered during the two month recovery period. Femoral neck geometry exhibited increased endocortical resorption and periosteal apposition of the cortical shell which suggests that trabecular bone plays an important role in how the total bone is affected by HU. Densitometric properties were affected less by HU with respect to BL than were mechanical strength values. Results suggest that femoral neck is more affected by unloading than midshaft, particularly for multiple exposures of unloading. Also, aging does not appear to be a critical factor for bone loss due to HU for either femoral neck or midshaft.

bone loss

microgravity

hindlimb unloading

Osteogenic effect of optimized muscle stimulation exercise as a countermeasure during hindlimb unloading

Sumner, Lindsay Rebecca

15 May 2009

No description available.

bone

mechanical properties

hindlimb unloading

resistive exercise

Simulated Microgravity and Radiation Exposure Effects on the Regulation of Skeletal Muscle Protein Synthesis

Wiggs, Michael

2011 August 1900

Long duration spaceflight missions out of lower earth orbit, back to the lunar surface, or possibly to Mars highlight the importance of preserving muscle mass and function. Muscle atrophy occurs within days of exposure to microgravity and prevailing thought is that a primary mechanism for muscle atrophy is a reduction in skeletal muscle protein synthesis. This dissertation examines the ability of skeletal muscle to recover muscle protein synthesis with slight perturbation, such as ambulatory reloading during disuse as well as partial loading, similar to body mass seen on the moon or Mars. We use traditional precursor-product labeling to measure protein synthesis, but use a relatively novel tracer, deuterium oxide, in order to make cumulative measures of protein synthesis over 24 h. The overarching goal of this dissertation is to define the response of skeletal muscle protein synthesis to different loading parameters in order to better understand the contribution of protein synthesis to skeletal muscle mass during disuse. In the first study, we demonstrate that muscle atrophy during 5 days of hindlimb unloading is in part due to a decrease in protein synthesis. We also highlight the ability of skeletal muscle to adapt by allowing two 1 h ambulatory reloading sessions on days 2 and 4. Although this countermeasure is able to rescue protein synthesis in soleus and gastrocnemius, it is unable attenuate any losses in muscle mass. In the second study, we compare partial weight loading to traditional hindlimb unloading. Weight bearing of 1/3 or 1/6 body weight is able to attenuate losses in muscle mass seen with unloading. Protein synthesis is maintained after 21 days of the experimental protocol, suggesting that protein synthesis is responsive to load and is likely not the only mechanism for determining muscle mass. In the final study, the effects of < 1 Gy x-ray exposure and partial weight suspension are measured to better understand the complex space environment, which includes a wide variety of radiation. Surprisingly, we found no effects of radiation on muscle protein synthesis in 1 G or partial loading. Targeting only protein synthesis may not be enough of a stimulus as evidenced by the data in this dissertation. Future plans should use a multiple-systems approach to counteract atrophy by increasing protein synthesis to maintain/elevate muscle mass during periods when it is otherwise compromised.

protein synthesis

hindlimb unloading

partial suspension

disuse

Osteogenic effect of optimized muscle stimulation exercise as a countermeasure during hindlimb unloading

Sumner, Lindsay Rebecca

15 May 2009

No description available.

bone

mechanical properties

hindlimb unloading

resistive exercise

Osteogenic effect of electric muscle stimulation as a countermeasure during hindlimb unloading

Alcorn, Justin Dow

17 September 2007

Rats that undergo hindlimb unloading (HU) as a simulation for space flight experience bone changes similar to astronauts in microgravity. The purpose of this research was to assess whether an exercise countermeasure would be effective in preventing or mitigating bone degradation during HU. Controlled electrical muscle stimulation was applied to the lower left hindlimb to simulate resistive exercise. Adult 6-mo. old male rats were assigned to 3 groups of 12 each: hindlimb unloaded (HU), aging cage control (CC), and baseline (BL). The CC group was pair-fed to match the nutritional intake of HU animals during the 28 days of the study. The left leg was exercised 3 days a week for the duration of the study, with the unexercised right leg serving as a contra-lateral control. Mechanical tests were conducted to assess the strength of cancellous bone in the proximal tibia metaphysis. Although isolated specimens of cancellous bone are not feasible, reduced platen compression (RPC) was employed to directly load only the cancellous core region of each specimen. There was no significant difference in ultimate stress or elastic modulus between BL, CC, and HU-Ex (exercised). However, HU-Ex results were dramatically and significantly higher than HU-No Ex (contra-lateral unexercised control) for both ultimate stress (68%) and elastic modulus (81%). It is also notable that ultimate stress was 32% higher (but not statistically significant) for HU-Ex compared to CC. The total bone mineral density in the tibial metaphysis was significantly larger, 11%, in the HUEx compared to the HU-No Ex group's values. The results clearly demonstrate the efficacy of the exercise protocol in preventing the substantial mechanical deterioration induced by HU.

Hindlimb Unloading

aging

male

rat

mechanical properties

Intermittent application of hypergravity by centrifugation attenuates disruption of rat gait induced by 2 weeks of simulated microgravity / 微小重力環境によって惹起されたラットの歩行動作変化は遠心重力による間欠的高重力刺激によって抑制され得る

Tajino, Junichi

24 September 2015

京都大学 / 0048 / 新制・課程博士 / 博士(人間健康科学) / 甲第19278号 / 人健博第30号 / 新制||人健||3(附属図書館) / 32280 / 京都大学大学院医学研究科人間健康科学系専攻 / (主査)教授 市橋 則明, 教授 三谷 章, 教授 松田 秀一 / 学位規則第4条第1項該当 / Doctor of Human Health Sciences / Kyoto University / DFAM

Hindlimb Unloading

Hypergravity

Centrifugation

Rat

Gait

498

Characterization of the Bone Loss and Recovery Response at the Distal Femur Metaphysis of the Adult Male Hindlimb Unloaded Rat

Davis, Joshua Morgan

2011 December 1900

Extended periods of mechanical unloading are known to be detrimental to bone health. Astronauts who spend months in microgravity aboard the International Space Station (ISS) are at particular risk. It is anticipated that NASA will not drastically increase the size of the astronaut corps, and this will mean increased likelihood of repeat missions for more astronauts. Thus, it is important to better understand the effects that prolonged, multiple bouts of unloading have on bone. This study utilized the hindlimb unloaded (HU) rat model to examine bone loss and recovery for single and double unloading bouts. Adult male Sprague-Dawley rats (6 months old) were randomized into the following groups: baseline (sacrificed at 6 months), 1HU7 (unloaded for 1 month, weight-bearing recovery for 3 months), 2HU10 (unloaded for 1 month, recovered for 2 months, unloaded for another month, and then recovered 2 months), 1HU10 (normal cage activity until 1 month HU ending at month 10, 2 month recovery followed), and aging controls (remained ambulatory throughout experiment). Every month (28 days), animals were terminated and the left femurs were excised, resulting in n=15 per group for each time point. Mineral and geometric properties were measured using peripheral quantitative computed tomography (pQCT) at the distal femur metaphysis, and quasi-static reduced platen compression (RPC) was used to estimate the mechanical properties of cancellous bone. Strength indices based on pQCT parameters were calculated as predictors of mechanical properties. Bone mass properties decreased due to HU and recovered within 2-3 months post-HU. A combination of increased periosteal apposition and endocortical resorption also occurred during HU. The initial HU bout suppressed normal age-related increases in mechanical properties and recovered within 1-2 months. Cancellous compressive strength index (CSI) most closely matched changes in mechanical properties. A second HU bout after two months recovery had a less detrimental effect on pQCT parameters but a greater negative impact on mechanical properties, when compared to pre-HU values. The opposite is true for mechanical properties if loss is characterized relative to aging controls. Recovery after the second HU period did not appear to be significantly affected by a previous bout of HU.

Hindlimb unloading

distal femur

metaphysis

pQCT

bone

cancellous

trabecular

reduced platen compression

RPC

rat

loss

recovery

Skeletal Response to Simulated Microgravity Exposures and Exercise in the Adult Rat Model

Shirazi-Fard, Yasaman

02 October 2013

Mechanical unloading has deleterious effects on the musculoskeletal system and results in significant reductions in bone density, mass, and strength, which do not fully recover even years after returning to weightbearing. For example, the rate of bone loss in microgravity is 10-fold more rapid than the rate of loss seen in elderly Caucasian females, the population group most predisposed to osteoporosis. This raises concern with individuals who are exposed to multiple bed rest periods or crewmembers who make repeated missions. Exercise offers a way to reduce or reverse these effects. Dual-energy X-ray absorptiometry (DXA) densitometry and bone mineral density (BMD) alone are generally insufficient for capturing the complex changes in bone mass, structure, and integrity and not an accurate predictor of fracture risk. Therefore, it is essential to measure the mechanical properties of bone tissue directly using animal models. The hindlimb unloaded (HU) rat model is a well-established ground-based analog for studying bone response to disuse and effects of spaceflight. The current study is one of the very few that has measured longitudinally densitometric and mechanical properties of bone after repeated simulated microgravity and long-term recovery at multiple anatomic sites in skeletally mature rats. The specific aims were to characterize 1) loss and recovery dynamics of bone following a period of unloading, 2) bone response after a second exposure to 28 days of HU, following an initial 28 days of HU and a recovery period equal to twice the duration of initial exposure, and 3) effects of resistance exercise during recovery period following an initial HU exposure and its effects on a subsequent exposure. In general, our data showed that bone response to unloading and recovery is site-specific. More specifically, we found that: 1) the rat proximal tibia metaphysis modeled the loss and discordant recovery dynamics as seen in the International Space Station (ISS) crewmembers proximal femur better than the rat femoral neck; 2) the initial exposure to HU has minimal effect on the subsequent HU exposure, and detrimental effects of the second HU exposure were milder than the initial due to reduced mechanosensitivity of the bone; 3) exercise significantly enhanced recovery following the initial HU exposure, and losses during the second exposure were not affected by exercise in most cases.

bone loss

disuse osteoporosis

simulated microgravity

hindlimb unloading

mechanical properties

adult rat model

resistance exercise

Effect of Early Life Physical Inactivity Level on Muscle Health During Early Postnatal Development

Smith, Austin

02 August 2022

No description available.

Kinesiology

Skeletal muscle disuse

physical inactivity

disuse atrophy

small mouse cage (SMC)

hindlimb unloading (HU)

grip strength

tissue composition

recovery

Effets de l’hypoxie respiratoire sur les progéniteurs médullaires dans un modèle murin d’hypodynamie : intérêt pour la réparation osseuse / In Vivo Hypobaric Hypoxia, Hypodynamia and Bone Healing in Mice

Durand, Marjorie

18 December 2013

La réparation osseuse est assurée par le recrutement constant de cellules souches/progéniteurs ostéo-compétents de nature hématopoïétique (CSH/PH), et mésenchymateuse (CSM). Une approche prometteuse pour le traitement des défauts osseux graves consisterait à favoriser le recrutement et la mobilisation des CSH/PH et des CSM à partir de la moelle osseuse vers le site de lésion. Plusieurs facteurs environnementaux sont connus pour moduler la prolifération, la mobilisation et la différenciation des progéniteurs ostéocompétents, dont l’hypoxie et l’hypodynamie (absence de contraintes mécaniques). Le but de ce travail de thèse a été d’investiguer in vivo l’impact de l’hypoxie respiratoire et de l’absence de contraintes mécaniques, appliquées séparément ou ensemble sur i) la mobilisation des progéniteurs ostéocompétents et sur ii) la réparation d’un défaut osseux cavitaire fémoral chez la souris. Sur un modèle murin dépourvu de défaut osseux, nos données montrent que l’hypoxie respiratoire est un agent mobilisateur des progéniteurs ostéocompétents, et qu’elle pourrait donc potentiellement exercer des effets bénéfiques sur la réparation osseuse. Toutefois, les effets de l’hypoxie sont modulés selon le statut hypodynamique ou non de l’animal. L’absence de contraintes mécaniques limite la mobilisation des progéniteurs érythrocytaires et mésenchymateux initiée par l’hypoxie, suggérant un effet potentiellement délétère de l’hypodynamie en condition hypoxique dans le contexte de la réparation osseuse. Chez les souris opérées, nous confirmons que l’hypoxie respiratoire déclenchée lors des phases de remodelage améliore la réparation du défaut osseux cavitaire. Une mobilisation des progéniteurs mésenchymateux et hématopoïétiques du fémur contra-latéral vers le fémur opéré est noté, mais le mode d’action de l’hypoxie passerait plutôt par une accélération du mécanisme de réparation dans la zone lésée. De façon intéressante, nous montrons que l’hypodynamie ne diminue pas le bénéfice apporté par l’hypoxie respiratoire à la réparation osseuse. En conclusion, ce travail de thèse identifie l’hypoxie respiratoire comme un candidat thérapeutique pertinent pour l’amélioration de la réparation osseuse. Bien que la perte des contraintes mécaniques module la biologie des cellules ostéoprogénitrices en absence de lésion, l’hypodynamie ne semble pas influencer la consolidation osseuse dans le cadre d’une amélioration de la réparation par un épisode hypoxique tardif. / Many environmental factors are known to influence bone cell fate, including proliferation, mobilization and differentiation of osteoprogenitor cells deriving from both hematopoietic and mesenchymal lineages. Among these factors, hypoxia and unloading (lack of mechanical loading / hypodynamia) are of particular interest. This study aims at investigating the impact of short-term hypobaric hypoxia and hindlimb unloading applied alone or in combination i) on the mobilization of osteocompetent progenitor cells on mice and ii) on the healing in a mouse model of surgical metaphyseal bone defect.In mice free of bone defect, our data indicate that respiratory hypobaric hypoxia acts as a mobilizing stimulus for osteoprogenitor cells. However, the effects of hypoxia in the bone marrow depend on whether mice are subjected to hindlimb unloading or not: hypodynamia tends to restrain the mobilization of both mesenchymal and erythroid progenitors under hypoxia. This suggests a potential detrimental influence of hypodynamia in the course of bone healing in hypoxic condition.In mice with surgery, we showed that hypobaric hypoxia during the remodelling process strongly enhances bone healing. A mobilization of both mesenchymal and hematopoietic progenitors is detected from the contralateral femur to the operated femur. In the lesion area, an acceleration of the repair process is evidenced. Interestingly, hindlimb unloading does not exert any negative influence on bone repair in our animal model. In conclusion, this study identifies delayed hypobaric hypoxia as a potent candidate to enhance bone healing. Even if unloading exerts significant effects on the biology of osteoprogenitor cells on mice free of bone defect, its influence is not detrimental for bone repair.

Hypoxie respiratoire

Suspension hypodynamique

Cellules stromales mésenchymateuses

Progéniteurs hématopoïétiques

Réparation osseuse

Respiratory hypoxia

Hindlimb unloading

Mesenchymal stromal cells

Hematopoietic progenitors

Bone healing