Mimicking a Space Mission to Mars Using Hindlimb Unloading and Partial Weight Bearing in Rats
Summary
By using an innovative ground-based analogue model, we are able to simulate a space mission including a trip to (0 g) and a stay on Mars (0.38 g) in rats. This model allows for a longitudinal assessment of the physiological changes occurring during the two hypo-gravitational stages of the mission.
Abstract
Rodent ground-based models are widely used to understand the physiological consequences of space flight on the physiological system and have been routinely employed since 1979 and the development of hind limb unloading (HLU). However, the next steps in space exploration now include to travel to Mars where the gravity is 38% of Earth’s gravity. Since no human being has experienced this level of partial gravity, a sustainable ground-based model is necessary to investigate how the body, already impaired by the time spent in microgravity, would react to this partial load. Here, we used our innovative partial weight-bearing (PWB) model to mimic a short mission and stay on Mars to assess the physiological impairments in the hind limb muscles induced by two different levels of reduced gravity applied in sequential fashion. This could provide a safe, ground-based model to study the musculoskeletal adaptations to gravitational change and to establish effective countermeasures to preserve astronauts’ health and function.
Introduction
Extraterrestrial targets, including the Moon and Mars, represent the future of human space exploration, but both have considerably weaker gravity than Earth. While the consequences of weightlessness on the musculoskeletal system have been extensively studied in astronauts1,2,3,4,5 and in rodents6,7,8,9, the latter thanks to the well-established hindlimb unloading (HLU) model10, very little is known about the effects of partial gravity. Martian gravity is 38% of Earth’s and this planet has become the focus of long-term exploration11; hence, it is crucial to understand the muscular alterations that may occur in this setting. To do so, we developed a partial weight bearing (PWB) system in rats12, based on previous work done in mice6,13, which was validated using both muscle and bone outcomes. However, the exploration of Mars will be preceded by a prolonged period of microgravity, which was not addressed in our previously described model12. Therefore, in this study, we altered our model to mimic a trip to Mars, comprised of a first phase of total hindlimb unloading and immediately followed by a second phase of partial weight bearing at 40% of normal loading.
Unlike most HLU models, we chose to use a pelvic harness (based on the one described by Chowdhury et al.9) rather than a tail suspension to improve animals’ comfort and to be able to move seamlessly and effortlessly from HLU to PWB in a matter of minutes. In conjunction, we used the cages and suspension devices that we previously developed and described extensively12. In addition to providing reliable/consistent data, we also previously demonstrated that the fixed attachment point of the suspension system at the center of the rod did not prevent the animals from moving, grooming, feeding, or drinking. In this article, we will describe how to unload the animals’ hind limbs (both totally and partially), verify their achieved gravity levels, as well as how to functionally assess the resulting muscular alterations using grip force and wet muscle mass. This model would be extremely useful for researchers seeking to investigate the consequences of partial gravity (either artificial or extra-terrestrial) on an already compromised musculoskeletal system, thus allowing them to investigate how organisms adapt to partial reloading, and for the development of countermeasures that could be developed to maintain health during and after human spaceflight.
Protocol
Representative Results
Discussion
This model presents the first ground-based analogue developed to investigate successive mechanical unloading levels and aims to mimic a trip to and stay on Mars.
Many steps of this protocol are critical to ensure its success and need to be closely examined. First, it is crucial to monitor the wellbeing of the animals and ensure that they are maintaining a normal behavior (i.e., performing tasks such as eating, resting, and exploring), particularly during the PWB state where they maintain a rel…
Declarações
The authors have nothing to disclose.
Acknowledgements
This work was supported by the National Aeronautics and Space Administration (NASA: NNX16AL36G). Authors would like to thank Carson Semple for providing the drawings included in this manuscript.
Materials
| 10G Insulated Solid Copper Wire | Grainger | 4WYY8 | 100 ft solid building wire with THHN wire type and 10 AWG wire size, black |
| 2 Custom design plexiglass walls | P&K Custom Acrylics Inc. | N/A | 2 clear plexiglass custom wall 3/16" tick, width 12 3/16", height 18 13/16", 1 rounded slot 0.25 in of diameter located at the center top of the wall |
| 3M Transpore Surgical Tape | Fisher Scientific | 18-999-380 | Transpore Surgical Tape |
| Accessory Grasping Bar Rat | Harvard Apparatus | 76-0479 | Accessory grasping bar rat, front or hind paws |
| Analytical Scale | Fisher Scientific | 01-920-251 | OHAUS Adventurer Analytic Balance |
| Animal Scale | ZIEIS by Amazon | N/A | 70 lb capacity digital scale big top 11.5" x 9.3" dura platform z-seal 110V adapter 0.5 ounce accuracy |
| Back Bra Extenders | Luzen by Amazon | N/A | 17 pcs 2 hook 3 rows assorted random color women spacing bra clip extender strap |
| Digital Force Gage | Wagner Instruments | DFE2-010 | 50 N Capacity Digital Grip Force Meter Chatillon DFE II |
| Gauze | Fisher Scientific | 13-761-52 | Non-sterile Cotton Gauze Sponges |
| Key rings and swivel claps | Paxcoo Direct by Amazon | N/A | PaxCoo 100 pcs metal swivel lanyard snap hook with key rings |
| Lobster Claps | Panda Jewelry International Limited by Amazon | N/A | Pandahall 100 pcs grade A stainless steel lobster claw clasps 13x8mm |
| Rat Tether Jacket – Large | Braintree Scientific | RJ L | Rodent Jacket |
| Rat Tether Jacket – Medium | Braintree Scientific | RJ M | Rodent Jacket |
| Silicone tubing | Versilon St Gobain Ceramics and Plastics | ABX00011 | SPX-50 Silicone Tubing |
| Stainless Steel Chains | Super Lover by Amazon | N/A | 4.5m 15FT stainless steel cable chain link in bulk 6x8mm |
Referências
- Desplanches, D. Structural and Functional Adaptations of Skeletal Muscle to Weightlessness. International Journal of Sports Medicine. 18 (S4), (1997).
- Fitts, R. H., Riley, D. R., Wildrick, J. J. Physiology of a microgravity environment : Invited review : microgravity and skeletal muscle. Journal of Applied Physiology. 89, 823-839 (2000).
- Fitts, R. H., Riley, D. R., Widrick, J. J. Functional and structural adaptations of skeletal muscle to microgravity. The Journal of Experimental Biology. 204 (Pt 18), 3201-3208 (2001).
- Narici, M. V., De Boer, M. D. Disuse of the musculo-skeletal system in space and on earth. European Journal of Applied Physiology. 111 (3), 403-420 (2011).
- di Prampero, P. E., Narici, M. V. Muscles in microgravity: from fibres to human motion. Journal of Biomechanics. 36 (3), 403-412 (2003).
- Wagner, E. B., Granzella, N. P., Saito, H., Newman, D. J., Young, L. R., Bouxsein, M. L. Partial weight suspension: a novel murine model for investigating adaptation to reduced musculoskeletal loading. Journal of Applied Physiology (Bethesda, Md. : 1985). 109 (2), 350-357 (2010).
- Sung, M., et al. Spaceflight and hind limb unloading induce similar changes in electrical impedance characteristics of mouse gastrocnemius muscle. Journal of Musculoskeletal and Neuronal Interactions. 13 (4), 405-411 (2013).
- Mcdonald, K. S., Blaser, C. A., Fitts, R. H. Force-velocity and power characteristics of rat soleus muscle fibers after hindlimb suspension. Journal of Applied Physiology. 77 (4), 1609-1616 (1994).
- Chowdhury, P., Long, A., Harris, G., Soulsby, M. E., Dobretsov, M. Animal model of simulated microgravity: a comparative study of hindlimb unloading via tail versus pelvic suspension. Physiological Reports. 1 (1), e00012 (2013).
- Morey, E. R., Sabelman, E. E., Turner, R. T., Baylink, D. J. A new rat model simulating some aspects of space flight. The Physiologist. 22 (6), (1979).
- . National Space Exploration Campaign Report Available from: https://www.nasa.gov/sites/default/files/atoms/files/nationalspaceexplorationcampaign.pdf (2018)
- Mortreux, M., Nagy, J. A., Ko, F. C., Bouxsein, M. L., Rutkove, S. B. A novel partial gravity ground-based analogue for rats via quadrupedal unloading. Journal of Applied Physiology. 125, 175-182 (2018).
- Ellman, R., et al. Combined effects of botulinum toxin injection and hind limb unloading on bone and muscle. Calcified Tissue International. 94 (3), (2014).
- Swift, J. M., et al. Partial Weight Bearing Does Not Prevent Musculoskeletal Losses Associated with Disuse. Medicine & Science in Sports & Exercise. 45 (11), 2052-2060 (2013).
- Morey-Holton, E. R., Globus, R. K. Hindlimb unloading rodent model: technical aspects. Journal of Applied Physiology. 92 (4), 1367-1377 (2002).
- Andreev-Andrievskiy, A. A., Popova, A. S., Lagereva, E. A., Vinogradova, O. L. Fluid shift versus body size: changes of hematological parameters and body fluid volume in hindlimb-unloaded mice, rats and rabbits. Journal of Experimental Biology. 221 (Pt 17), (2018).
