Search

Your search keyword '"Hargens, A. R"' showing total 1,155 results
Start Over Author "Hargens, A. R"
1,155 results on '"Hargens, A. R"'

1. Using hierarchical unsupervised learning to integrate and reduce multi-level and multi-paraspinal muscle MRI data in relation to low back pain

Author

Torres-Espin, Abel, Keller, Anastasia, Johnson, Gabriel TA, Fields, Aaron J, Krug, Roland, Ferguson, Adam R, Hargens, Alan R, O’Neill, Conor W, Lotz, Jeffrey C, and Bailey, Jeannie F

Subjects
Allied Health and Rehabilitation Science, Biomedical and Clinical Sciences, Clinical Sciences, Health Sciences, Pain Research, Chronic Pain, Clinical Research, Neurosciences, Musculoskeletal, Neurological, Humans, Low Back Pain, Magnetic Resonance Imaging, Paraspinal Muscles, Unsupervised Machine Learning, Weightlessness, Lumbar spine, Paraspinal muscles, MRI, Low back pain, Integrative analysis, Multiple factor analysis, Hierarchical unsupervised learning, Biomedical Engineering, Orthopedics, Clinical sciences, Allied health and rehabilitation science
Abstract

PurposeThe paraspinal muscles (PSM) are a key feature potentially related to low back pain (LBP), and their structure and composition can be quantified using MRI. Most commonly, quantifying PSM measures across individual muscles and individual spinal levels renders numerous separate metrics that are analyzed in isolation. However, comprehensive multivariate approaches would be more appropriate for analyzing the PSM within an individual. To establish and test these methods, we hypothesized that multivariate summaries of PSM MRI measures would associate with the presence of LBP symptoms (i.e., pain intensity).MethodsWe applied hierarchical multiple factor analysis (hMFA), an unsupervised integrative method, to clinical PSM MRI data from unique cohort datasets including a longitudinal cohort of astronauts with pre- and post-spaceflight data and a cohort of chronic LBP subjects and asymptomatic controls. Three specific use cases were investigated: (1) predicting longitudinal changes in pain using combinations of baseline PSM measures; (2) integrating baseline and post-spaceflight MRI to assess longitudinal change in PSM and how it relates to pain; and (3) integrating PSM quality and adjacent spinal pathology between LBP patients and controls.ResultsOverall, we found distinct complex relationships with pain intensity between particular muscles and spinal levels. Subjects with high asymmetry between left and right lean muscle composition and differences between spinal segments PSM quality and structure are more likely to increase in pain reported outcome after prolonged time in microgravity. Moreover, changes in PSM quality and structure between pre and post-spaceflight relate to increase in pain after prolonged microgravity. Finally, we show how unsupervised hMFA recapitulates previous research on the association of CEP damage and LBP diagnostic.ConclusionOur analysis considers the spine as a multi-segmental unit as opposed to a series of discrete and isolated spine segments. Integrative and multivariate approaches can be used to distill large and complex imaging datasets thereby improving the clinical utility of MRI-based biomarkers, and providing metrics for further analytical goals, including phenotyping.

Published
2022

2. Biomechanical changes in the lumbar spine following spaceflight and factors associated with postspaceflight disc herniation

Author

Bailey, Jeannie F, Nyayapati, Priya, Johnson, Gabriel TA, Dziesinski, Lucas, Scheffler, Aaron W, Crawford, Rebecca, Scheuring, Richard, O'Neill, Conor W, Chang, Douglas, Hargens, Alan R, and Lotz, Jeffrey C

Subjects
Allied Health and Rehabilitation Science, Biomedical and Clinical Sciences, Clinical Sciences, Health Sciences, Biomedical Imaging, Pain Research, Chronic Pain, 2.1 Biological and endogenous factors, Aetiology, Musculoskeletal, Good Health and Well Being, Humans, Intervertebral Disc Displacement, Longitudinal Studies, Lumbar Vertebrae, Prospective Studies, Space Flight, Disc herniations, Low back pain, Lumbar spine, Multifidus, Spaceflight, Lumbar biomechanics, Unloading, Neurosciences, Orthopedics, Clinical sciences, Allied health and rehabilitation science
Abstract

Background contextFor chronic low back pain, the causal mechanisms between pathological features from imaging and patient symptoms are unclear. For instance, disc herniations can often be present without symptoms. There remains a need for improved knowledge of the pathophysiological mechanisms that explore spinal tissue damage and clinical manifestations of pain and disability. Spaceflight and astronaut health provides a rare opportunity to study potential low back pain mechanisms longitudinally. Spaceflight disrupts diurnal loading on the spine and several lines of evidence indicate that astronauts are at a heightened risk for low back pain and disc herniation following spaceflight.PurposeTo examine the relationship between prolonged exposure to microgravity and the elevated incidence of postflight disc herniation, we conducted a longitudinal study to track the spinal health of twelve NASA astronauts before and after approximately 6 months in space. We hypothesize that the incidence of postflight disc herniation and low back complaints associates with spaceflight-included muscle atrophy and pre-existing spinal pathology.Study designThis is a prospective longitudinal study.Patient sampleOur sample included a cohort of twelve astronaut crewmembers.Outcome measuresFrom 3T MRI, we quantified disc water content (ms), disc degeneration (Pfirrmann grade), vertebral endplate irregularities, facet arthropathy and/ fluid, high intensity zones, disc herniation, multifidus total cross-sectional area (cm2), multifidus lean muscle cross-sectional area (cm2), and muscle quality/composition (%). From quantitative fluoroscopy we quantified, maximum flexion-extension ROM (°), maximum lateral bending ROM (°), and maximum translation (%). Lastly, patient outcomes and clinical notes were used for identifying postflight symptoms associated with disc herniations from 3T MRI.MethodsAdvanced imaging data from 3T MRI were collected at three separate time points in relation to spending six months in space: (1) within a year before launch ("pre-flight"), (2) within a week after return to Earth ("post-flight"), and (3) between 1 and 2 months after return to Earth ("recovery"). Fluoroscopy of segmental kinematics was collected at preflight and postflight timepoints. We assessed the effect of spaceflight and postflight recovery on longitudinal changes in spinal structure and function, as well as differences between crew members who did and did not present a symptomatic disc herniation following spaceflight.ResultsHalf of our astronauts (n=6) experienced new symptoms associated with a new or previously asymptomatic lumbar disc protrusion or extrusion following spaceflight. We observed decreased multifidus muscle quality following spaceflight in the lower lumbar spine, with a reduced percentage of lean muscle at L4L5 (-6.2%, p=.009) and L5S1 (-7.0%, p=.006) associated with the incidence of new disc herniation. Additionally, we observed reduced lumbar segment flexion-extension ROM for L2L3 (-17.2%, p=.006) and L3L4 (-20.5%, p=.02) following spaceflight, and furthermore that reduced ROM among the upper three lumbar segments (-24.1%, p=.01) associated with the incidence of disc herniation. Existing endplate pathology was most prevalent in the upper lumbar spine and associated with reduced segmental ROM (-20.5%, p=.02).ConclusionsIn conclusion from a 10-year study investigating the effects of spaceflight on the lumbar spine and risk for disc herniation, we found the incidence of lumbar disc herniation following spaceflight associates with compromised multifidus muscle quality and spinal segment kinematics, as well as pre-existing spinal endplate irregularities. These findings suggest differential effects of spinal stiffness and muscle loss in the upper versus lower lumbar spine regions that may specifically provoke risk for symptomatic disc herniation in the lower lumbar spine following spaceflight. Results from this study provide a unique longitudinal assessment of mechanisms and possible risk factors for developing disc herniations and related low back pain. Furthermore, these findings will help inform physiologic countermeasures to maintain spinal health in astronauts during long-duration missions in space.

Published
2022

4. The NASA Twins Study: A multidimensional analysis of a year-long human spaceflight

Author

Garrett-Bakelman, Francine E, Darshi, Manjula, Green, Stefan J, Gur, Ruben C, Lin, Ling, Macias, Brandon R, McKenna, Miles J, Meydan, Cem, Mishra, Tejaswini, Nasrini, Jad, Piening, Brian D, Rizzardi, Lindsay F, Sharma, Kumar, Siamwala, Jamila H, Taylor, Lynn, Vitaterna, Martha Hotz, Afkarian, Maryam, Afshinnekoo, Ebrahim, Ahadi, Sara, Ambati, Aditya, Arya, Maneesh, Bezdan, Daniela, Callahan, Colin M, Chen, Songjie, Choi, Augustine MK, Chlipala, George E, Contrepois, Kévin, Covington, Marisa, Crucian, Brian E, De Vivo, Immaculata, Dinges, David F, Ebert, Douglas J, Feinberg, Jason I, Gandara, Jorge A, George, Kerry A, Goutsias, John, Grills, George S, Hargens, Alan R, Heer, Martina, Hillary, Ryan P, Hoofnagle, Andrew N, Hook, Vivian YH, Jenkinson, Garrett, Jiang, Peng, Keshavarzian, Ali, Laurie, Steven S, Lee-McMullen, Brittany, Lumpkins, Sarah B, MacKay, Matthew, Maienschein-Cline, Mark G, Melnick, Ari M, Moore, Tyler M, Nakahira, Kiichi, Patel, Hemal H, Pietrzyk, Robert, Rao, Varsha, Saito, Rintaro, Salins, Denis N, Schilling, Jan M, Sears, Dorothy D, Sheridan, Caroline K, Stenger, Michael B, Tryggvadottir, Rakel, Urban, Alexander E, Vaisar, Tomas, Van Espen, Benjamin, Zhang, Jing, Ziegler, Michael G, Zwart, Sara R, Charles, John B, Kundrot, Craig E, Scott, Graham BI, Bailey, Susan M, Basner, Mathias, Feinberg, Andrew P, Lee, Stuart MC, Mason, Christopher E, Mignot, Emmanuel, Rana, Brinda K, Smith, Scott M, Snyder, Michael P, and Turek, Fred W

Subjects
Mental Health, Genetics, Adaptation, Physiological, Adaptive Immunity, Astronauts, Body Weight, Carotid Arteries, Carotid Intima-Media Thickness, DNA Damage, DNA Methylation, Gastrointestinal Microbiome, Genomic Instability, Humans, Male, Space Flight, Telomere Homeostasis, Time Factors, United States, United States National Aeronautics and Space Administration, General Science & Technology
Abstract

To understand the health impact of long-duration spaceflight, one identical twin astronaut was monitored before, during, and after a 1-year mission onboard the International Space Station; his twin served as a genetically matched ground control. Longitudinal assessments identified spaceflight-specific changes, including decreased body mass, telomere elongation, genome instability, carotid artery distension and increased intima-media thickness, altered ocular structure, transcriptional and metabolic changes, DNA methylation changes in immune and oxidative stress-related pathways, gastrointestinal microbiota alterations, and some cognitive decline postflight. Although average telomere length, global gene expression, and microbiome changes returned to near preflight levels within 6 months after return to Earth, increased numbers of short telomeres were observed and expression of some genes was still disrupted. These multiomic, molecular, physiological, and behavioral datasets provide a valuable roadmap of the putative health risks for future human spaceflight.

Published
2019

5. Parabolic Flight

Author

Petersen, Johan C. G., Hargens, Alan R., Petersen, Lonnie G., Kozlovskaya, Inessa, Section editor, Young, Laurence R., editor, and Sutton, Jeffrey P., editor

Published
2021
Full Text
View/download PDF

8. From the international space station to the clinic: how prolonged unloading may disrupt lumbar spine stability

Author

Bailey, Jeannie F, Miller, Stephanie L, Khieu, Kristine, O'Neill, Conor W, Healey, Robert M, Coughlin, Dezba G, Sayson, Jojo V, Chang, Douglas G, Hargens, Alan R, and Lotz, Jeffrey C

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Health Sciences, Traditional, Complementary and Integrative Medicine, Pain Research, Biomedical Imaging, Chronic Pain, Bioengineering, Musculoskeletal, Adult, Astronauts, Female, Humans, Intervertebral Disc Degeneration, Intervertebral Disc Displacement, Lumbosacral Region, Magnetic Resonance Imaging, Male, Middle Aged, Paraspinal Muscles, Posture, Weightlessness, Instability, Low back pain, Lumbar spine, Multifidus, Spaceflight, Unloading, Neurosciences, Orthopedics, Clinical sciences, Allied health and rehabilitation science
Abstract

Background contextProlonged microgravity exposure is associated with localized low back pain and an elevated risk of post-flight disc herniation. Although the mechanisms by which microgravity impairs the spine are unclear, they should be foundational for developing in-flight countermeasures for maintaining astronaut spine health. Because human spine anatomy has adapted to upright posture on Earth, observations of how spaceflight affects the spine should also provide new and potentially important information on spine biomechanics that benefit the general population.PurposeThis study compares quantitative measures of lumbar spine anatomy, health, and biomechanics in astronauts before and after 6 months of microgravity exposure on board the International Space Station (ISS).Study designThis is a prospective longitudinal study.SampleSix astronaut crewmember volunteers from the National Aeronautics and Space Administration (NASA) with 6-month missions aboard the ISS comprised our study sample.Outcome measuresFor multifidus and erector spinae at L3-L4, measures include cross-sectional area (CSA), functional cross-sectional area (FCSA), and FCSA/CSA. Other measures include supine lumbar lordosis (L1-S1), active (standing) and passive (lying) flexion-extension range of motion (FE ROM) for each lumbar disc segment, disc water content from T2-weighted intensity, Pfirrmann grade, vertebral end plate pathology, and subject-reported incidence of chronic low back pain or disc injuries at 1-year follow-up.Methods3T magnetic resonance imaging and dynamic fluoroscopy of the lumbar spine were collected for each subject at two time points: approximately 30 days before launch (pre-flight) and 1 day following 6 months spaceflight on the ISS (post-flight). Outcome measures were compared between time points using paired t tests and regression analyses.ResultsSupine lumbar lordosis decreased (flattened) by an average of 11% (p=.019). Active FE ROM decreased for the middle three lumbar discs (L2-L3: -22.1%, p=.049; L3-L4: -17.3%, p=.016; L4-L5: -30.3%, p=.004). By contrast, no significant passive FE ROM changes in these discs were observed (p>.05). Disc water content did not differ systematically from pre- to post-flight. Multifidus and erector spinae changed variably between subjects, with five of six subjects experiencing an average decrease 20% for FCSA and 8%-9% for CSA in both muscles. For all subjects, changes in multifidus FCSA strongly correlated with changes in lordosis (r2=0.86, p=.008) and active FE ROM at L4-L5 (r2=0.94, p=.007). Additionally, changes in multifidus FCSA/CSA correlated with changes in lordosis (r2=0.69, p=.03). Although multifidus-associated changes in lordosis and ROM were present among all subjects, only those with severe, pre-flight end plate irregularities (two of six subjects) had post-flight lumbar symptoms (including chronic low back pain or disc herniation).ConclusionsWe observed that multifidus atrophy, rather than intervertebral disc swelling, associated strongly with lumbar flattening and increased stiffness. Because these changes have been previously linked with detrimental spine biomechanics and pain in terrestrial populations, when combined with evidence of pre-flight vertebral end plate insufficiency, they may elevate injury risk for astronauts upon return to gravity loading. Our results also have implications for deconditioned spines on Earth. We anticipate that our results will inform new astronaut countermeasures that target the multifidus muscles, and research on the role of muscular stability in relation to chronic low back pain and disc injury.

Published
2018

10. From the International Space Station to the Clinic: How Prolonged Unloading May Disrupt Lumbar Stability

Author

Bailey, Jeannie F, Miller, Stephanie L, Khieu, Kristine, O'Neill, Conor W, Healey, Robert M, Couglin, Dezba G, Sayson, Jojo V, Chang, Douglas G, Hargens, Alan R, and Lotz, Jeffrey C

Subjects
Allied Health and Rehabilitation Science, Biomedical and Clinical Sciences, Clinical Sciences, Health Sciences, Neurosciences, Orthopedics, Clinical sciences, Allied health and rehabilitation science
Published
2017

11. Lumbar Spine Paraspinal Muscle and Intervertebral Disc Height Changes in Astronauts After Long-Duration Spaceflight on the International Space Station

Author

Chang, Douglas G, Healey, Robert M, Snyder, Alexander J, Sayson, Jojo V, Macias, Brandon R, Coughlin, Dezba G, Bailey, Jeannie F, Parazynski, Scott E, Lotz, Jeffrey C, and Hargens, Alan R

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Health Sciences, Biomedical Imaging, Musculoskeletal, Astronauts, Female, Humans, Intervertebral Disc, Lumbar Vertebrae, Lumbosacral Region, Magnetic Resonance Imaging, Male, Middle Aged, Paraspinal Muscles, Prospective Studies, Space Flight, Time Factors, aerospace medicine, atrophy, back pain, immobilization, intervertebral disc, magnetic resonance imaging, muscles, paraspinal muscles, spine, weightlessness, Biomedical Engineering, Orthopedics, Clinical sciences, Neurosciences, Allied health and rehabilitation science
Abstract

Study designProspective case series.ObjectiveEvaluate lumbar paraspinal muscle (PSM) cross-sectional area and intervertebral disc (IVD) height changes induced by a 6-month space mission on the International Space Station. The long-term objective of this project is to promote spine health and prevent spinal injury during space missions and here on Earth.Summary of background dataNational Aeronautics and Space Administration (NASA) crewmembers have a 4.3 times higher risk of herniated IVDs, compared with the general and military aviator populations. The highest risk occurs during the first year after a mission. Microgravity exposure during long-duration spaceflights results in approximately 5 cm lengthening of body height, spinal pain, and skeletal deconditioning. How the PSMs and IVDs respond during spaceflight is not well described.MethodsSix NASA crewmembers were imaged supine with a 3 Tesla magnetic resonance imaging. Imaging was conducted preflight, immediately postflight, and then 33 to 67 days after landing. Functional cross-sectional area (FCSA) measurements of the PSMs were performed at the L3-4 level. FCSA was measured by grayscale thresholding within the posterior lumbar extensors to isolate lean muscle on T2-weighted scans. IVD heights were measured at the anterior, middle, and posterior sections of all lumbar levels. Repeated measures analysis of variance was used to determine significance at P

Published
2016

12. Self-Generated Lower Body Negative Pressure Exercise: A Low Power Countermeasure for Acute Space Missions.

Author

Velichala, Suhas Rao, Kassel, Ryan D., Ly, Victoria, Watenpaugh, Donald E., Lee, Stuart M. C., Macias, Brandon R., and Hargens, Alan R.

Subjects
FLUID dynamics, GRAVITATIONAL effects, SUPINE position, BLOOD pressure, HEART beat
Abstract

Microgravity in spaceflight produces headward fluid shifts which probably contribute to Spaceflight-Associated Neuro-Ocular Syndrome (SANS). Developing new methods to mitigate these shifts is crucial for preventing SANS. One possible strategy is the use of self-generated lower body negative pressure (LBNP). This study evaluates biological or physiological effects induced by bed rest to simulate adaptations to microgravity. Participants were tested during powered LBNP and dynamic self-generated (SELF) LBNP at 25 mmHg for 15 min. The results were compared to the physiologic responses observed in seated upright and supine positions without LBNP, which served as controls for normal gravitational effects on fluid dynamics. Eleven participants' (five male, six female) heart rates, blood pressures, and cross-sectional areas (CSA) of left and right internal jugular veins (IJV) were monitored. Self-generated LBNP, which requires mild to moderate physical activity, significantly elevated heart rate and blood pressure (p < 0.01). Self-generated LBNP also significantly reduced right IJV CSA compared to supine position (p = 0.005), though changes on the left side were not significant (p = 0.365). While the effects of SELF and traditional LBNP on IJV CSA were largely similar, traditional LBNP significantly reduced IJV CSA on both sides. Given its low mass, volume, and power requirements, SELF LBNP is a promising countermeasure against SANS. Results from this study warrant longer-term studies of SELF LBNP under simulated spaceflight conditions. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

13. The effect of simulated microgravity on lumbar spine biomechanics: an in vitro study

Author

Laws, Cory J, Berg-Johansen, Britta, Hargens, Alan R, and Lotz, Jeffrey C

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Health Sciences, Bioengineering, Biomechanical Phenomena, Humans, Intervertebral Disc, Intervertebral Disc Displacement, Lumbar Vertebrae, Posture, Pressure, Range of Motion, Articular, Research, Space Flight, Stress, Mechanical, Weightlessness, Spaceflight, Microgravity, Intervertebral disc, Herniation, Biomechanics, Biomedical Engineering, Orthopedics, Clinical sciences, Allied health and rehabilitation science
Abstract

PurposeDisc herniation risk is quadrupled following spaceflight. This study tested the hypothesis that swelling-induced disc height increases (comparable to those reported in spaceflight) stiffen the spine and elevate annular strain and nuclear pressure during forward bending.MethodsEight human lumbar motion segments were secured to custom-designed testing jigs and subjected to baseline flexion and compression and pure moment flexibility tests. Discs were then free-swelled in saline to varying supraphysiologic heights consistent with prolonged weightlessness and re-tested to assess biomechanical changes.ResultsSwelling-induced disc height changes correlated positively with intradiscal pressure (p

Published
2016

14. Treadmill exercise within lower body negative pressure protects leg lean tissue mass and extensor strength and endurance during bed rest

Author

Schneider, Suzanne M, Lee, Stuart MC, Feiveson, Alan H, Watenpaugh, Donald E, Macias, Brandon R, and Hargens, Alan R

Subjects
Medical Physiology, Biomedical and Clinical Sciences, Clinical Research, Prevention, Rehabilitation, Cardiovascular, Physical Rehabilitation, Musculoskeletal, Adult, Bed Rest, Exercise Test, Exercise Therapy, Female, Humans, Isometric Contraction, Leg, Lower Body Negative Pressure, Male, Muscle Strength, Physical Endurance, Space Flight, Young Adult, Body composition, head down tilt, isokinetic, microgravity, muscle atrophy, spaceflight, Physiology, Clinical Sciences, Medical physiology
Abstract

Leg muscle mass and strength are decreased during reduced activity and non-weight-bearing conditions such as bed rest (BR) and spaceflight. Supine treadmill exercise within lower body negative pressure (LBNPEX) provides full-body weight loading during BR and may prevent muscle deconditioning. We hypothesized that a 40-min interval exercise protocol performed against LBNPEX 6 days week(-1) would attenuate losses in leg lean mass (LLM), strength, and endurance during 6° head-down tilt BR, with similar benefits for men and women. Fifteen pairs of healthy monozygous twins (8 male and 7 female pairs) completed 30 days of BR with one sibling of each twin pair assigned randomly as the non-exercise control (CON) and the other twin as the exercise subject (EX). Before and after BR, LLM and isokinetic leg strength and endurance were measured. Mean knee and ankle extensor and flexor strength and endurance and LLM decreased from pre- to post-BR in the male CON subjects (P

Published
2016

15. WISE 2005: Aerobic and resistive countermeasures prevent paraspinal muscle deconditioning during 60-day bed rest in women

Author

Holt, Jacquelyn A, Macias, Brandon R, Schneider, Suzanne M, Watenpaugh, Donald E, Lee, Stuart MC, Chang, Douglas G, and Hargens, Alan R

Subjects
Biomedical and Clinical Sciences, Allied Health and Rehabilitation Science, Health Sciences, Clinical Sciences, Sports Science and Exercise, Prevention, Musculoskeletal, Astronauts, Bed Rest, Exercise, Exercise Test, Female, Head-Down Tilt, Humans, Lower Body Negative Pressure, Lumbar Vertebrae, Lumbosacral Region, Paraspinal Muscles, Resistance Training, Space Flight, Weightlessness, Weightlessness Countermeasures, Weightlessness Simulation, disuse, spaceflight, erector spinae, exercise training, muscle atrophy, Biological Sciences, Medical and Health Sciences, Physiology, Biological sciences, Biomedical and clinical sciences, Health sciences
Abstract

Microgravity-induced lumbar paraspinal muscle deconditioning may contribute to back pain commonly experienced by astronauts and may increase the risk of postflight injury. We hypothesized that a combined resistive and aerobic exercise countermeasure protocol that included spinal loading would mitigate lumbar paraspinal muscle deconditioning during 60 days of bed rest in women. Sixteen women underwent 60-day, 6° head-down-tilt bed rest (BR) and were randomized into control and exercise groups. During bed rest the control group performed no exercise. The exercise group performed supine treadmill exercise within lower body negative pressure (LBNP) for 3-4 days/wk and flywheel resistive exercise for 2-3 days/wk. Paraspinal muscle cross-sectional area (CSA) was measured using a lumbar spine MRI sequence before and after BR. In addition, isokinetic spinal flexion and extension strengths were measured before and after BR. Data are presented as means ± SD. Total lumbar paraspinal muscle CSA decreased significantly more in controls (10.9 ± 3.4%) than in exercisers (4.3 ± 3.4%; P < 0.05). The erector spinae was the primary contributor (76%) to total lumbar paraspinal muscle loss. Moreover, exercise attenuated isokinetic spinal extension loss (-4.3 ± 4.5%), compared with controls (-16.6 ± 11.2%; P < 0.05). In conclusion, LBNP treadmill and flywheel resistive exercises during simulated microgravity mitigate decrements in lumbar paraspinal muscle structure and spine function. Therefore spaceflight exercise countermeasures that attempt to reproduce spinal loads experienced on Earth may mitigate spinal deconditioning during long-duration space travel.

Published
2016

16. Spaceflight‐induced bone loss alters failure mode and reduces bending strength in murine spinal segments

Author

Berg‐Johansen, Britta, Liebenberg, Ellen C, Li, Alfred, Macias, Brandon R, Hargens, Alan R, and Lotz, Jeffrey C

Subjects
Engineering, Biomedical Engineering, Musculoskeletal, Animals, Bone Resorption, Bone and Bones, Male, Mice, Inbred C57BL, Space Flight, Tail, Weight-Bearing, Weightlessness, X-Ray Microtomography, spaceflight, intervertebral disc, four-point bending, herniation, murine, Clinical Sciences, Human Movement and Sports Sciences, Orthopedics, Biomedical engineering, Sports science and exercise
Abstract

Intervertebral disc herniation rates are quadrupled in astronauts following spaceflight. While bending motions are main contributors to herniation, the effects of microgravity on the bending properties of spinal discs are unknown. Consequently, the goal of this study was to quantify the bending properties of tail discs from mice with or without microgravity exposure. Caudal motion segments from six mice returned from a 30-day Bion M1 mission and eight vivarium controls were loaded to failure in four-point bending. After testing, specimens were processed using histology to determine the location of failure, and adjacent motion segments were scanned with micro-computed tomography (μCT) to quantify bone properties. We observed that spaceflight significantly shortened the nonlinear toe region of the force-displacement curve by 32% and reduced the bending strength by 17%. Flight mouse spinal segments tended to fail within the growth plate and epiphyseal bone, while controls tended to fail at the disc-vertebra junction. Spaceflight significantly reduced vertebral bone volume fraction, bone mineral density, and trabecular thickness, which may explain the tendency of flight specimens to fail within the epiphyseal bone. Together, these results indicate that vertebral bone loss during spaceflight may degrade spine bending properties and contribute to increased disc herniation risk in astronauts.

Published
2016

18. Parabolic Flight

Author

Petersen, Johan C. G., primary, Hargens, Alan R., additional, and Petersen, Lonnie G., additional

Published
2020
Full Text
View/download PDF

21. Anterior-posterior transcranial ultrasound to measure cranial oscillations.

Author

Liu, John HK, Lynch, John E, Rosales-Velderrain, Armando, Chang, Douglas G, Weinreb, Robert N, and Hargens, Alan R

Subjects
Humans, Ultrasonography, Doppler, Transcranial, Analysis of Variance, Regression Analysis, Weightlessness Simulation, Aerospace Medicine, Fluid Shifts, Head-Down Tilt, Pulsatile Flow, Space Flight, Adult, Female, Male, Biomedical Imaging, body tilt, cranial oscillation, human, ultrasound, Human Movement and Sports Sciences, Medical Physiology, Public Health and Health Services, Physiology
Abstract

BackgroundWe aimed to provide information on whether or not the correlation between body tilt and the pulse amplitude of transcranial ultrasonic time-of-flight waveform can be observed in the anterior-posterior skull direction. Also, we asked the question whether or not the skull pulsation can be detected since the cranial bones involved are thicker.MethodsThe experimental model of body tilt that alters intracranial pressure by shifting body fluid headward was employed. Transcranial ultrasound waveforms were examined in 15 healthy volunteers positioned at five tilt angles of +30 degrees, 0 degrees, -30 degrees, -60 degrees, and -90 degrees from the horizontal body position. A pulse-echo transducer was placed on the middle forehead and ultrasound waveforms were recorded. Synchronized variations in the ultrasonic time-of-flight with heartbeats were monitored using the pulsed phase locked loop technique for the output voltage of the ultrasound transducer. Simultaneous effects of body tilt on cardiovascular parameters were also evaluated.ResultsPulse amplitudes of ultrasonic time-of-flight waveforms were found to vary with body tilt. Repeated-measures ANOVA and regression analysis showed a negative correlation between body tilt angle and pulse amplitude. The regression line has the equation: pulse amplitude = (1.158-0.01023 x tilt angle) x 10(-4) voltage. There was no such relationship between head-down body tilt and altered mean blood pressure or heart rate.ConclusionAn increase in the pulse amplitude of the anterior-posterior transcranial ultrasonic time-of-flight waveform can be detected when the head-down body tilt angle increases.

Published
2013

22. Body position and backpack loading: an upright magnetic resonance imaging study of the adult lumbar spine

Author

Shymon, Stephen Joseph, Hargens, Alan R, Minkoff, Lawrence A, and Chang, Douglas G

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Biochemistry and Cell Biology, Physiology, Medical Physiology, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical physiology
Abstract

The human lumbar spine is uniquely adapted to the gravitational stress of upright posture. Using upright magnetic resonance imaging (uMRI), we characterized the adult lumbar spine's response to upright gravitational loading. We hypothesized that a gravitational load would compress the intervertebral discs (IVDs). Five volunteers underwent T2 weighted sagittal 0.6T uMRI scans of the lumbar spine while supine, upright, and upright with a 10% body weight (BW) backpack. While upright, the 10% BW load significantly compressed the L4‐L5 and L5‐S1 IVDs by about 10% relative to supine (p < 0.05). Upright posture and the 10% BW load significantly compressed the anterior L5‐S1 IVD relative to supine (p < 0.05). Gravitational loading of the lumbar spine plus an added 10% BW load compresses the caudal IVDs (L4‐L5 and L5‐S1), suggesting that these discs are either bearing more of the load or are more compliant than the other IVDs. This study is the first radiographic analysis to describe the adult lumbar spine in the upright position with added spinal load. This study was supported by the National Aeronautics and Space Administration Grant NNX10AM18G and the UCSD Clinical Translational Research Institute Fellowship Award.

Published
2013

23. WISE-2005: effect of aerobic and resistive exercises on orthostatic tolerance during 60 days bed rest in women

Author

Guinet, Patrick, Schneider, Suzanne M., Macias, Brandon R., Watenpaugh, Donald E., Hughson, Richard L., Traon, Anne Pavy, Bansard, Jean-Yves, and Hargens, Alan R.

Subjects
Biomedicine, Sports Medicine, Occupational Medicine/Industrial Medicine, Human Physiology, Simulated microgravity, Cardiovascular deconditioning, Exercise countermeasure, Lower body negative pressure
Abstract

Cardiovascular deconditioning after long duration spaceflight is especially challenging in women who have a lower orthostatic tolerance (OT) compared with men. We hypothesized that an exercise prescription, combining supine aerobic treadmill exercise in a lower body negative pressure (LBNP) chamber followed by 10 min of resting LBNP, three to four times a week, and flywheel resistive training every third day would maintain orthostatic tolerance (OT) in women during a 60-day head-down-tilt bed rest (HDBR). Sixteen women were assigned to two groups (exercise, control). Pre and post HDBR OT was assessed with a tilt/LBNP test until presyncope. OT time (mean ± SE) decreased from 17.5 ± 1.0 min to 9.1 ± 1.5 min (−50 ± 6%) in control group (P

Published
2009

25. Evaluation of treadmill exercise in a lower body negative pressure chamber as a countermeasure for weightlessness-induced bone loss: A bed rest study with identical twins

Author

Smith, Scott M, Davis-Street, Janis E, Fesperman, J Vernell, Calkins, D S, Bawa, Maneesh, Macias, Brandon R, Meyer, R Scott, and Hargens, Alan R

Subjects
spaceflight, bed rest, simulated weightlessness, bone resorption, bone markers
Abstract

Introduction: Bone loss is one of the greatest physiological challenges for extended-duration space missions. The ability of exercise to counteract weightlessness-induced bone loss has been studied extensively, but to date, it has proven ineffective. We evaluated the effectiveness of a combination of two countermeasures-treadmill exercise while inside a lower body negative pressure (LBNP) chamber-on bone loss during a 30-day bed rest study. Materials and Methods: Eight pairs of identical twins were randomized into sedentary (SED) or exercise/LBNP (EX/LBNP) groups. Blood and urine samples were collected before, several times during, and after the 30-day bed rest period. These samples were analyzed for markers of bone and calcium metabolism. Repeated measures ANOVA was used to determine statistical significance. Because identical twins were used, both time and group were treated as repeated variables. Results: Markers of bone resorption were increased during bed rest in samples from sedentary subjects, including the collagen cross-links and serum and urinary calcium concentrations. For N-telopeptide and deoxypyridinoline, there were significant (p < 0.05) interactions between group (SED versus EX/LBNP) and phase of the study (sample collection point). Pyridinium cross-links were increased above pre-bed rest levels in both groups, but the EX/LBNP group had a smaller increase than the SED group. Markers of bone formation were unchanged by bed rest in both groups. Conclusions: These data show that this weight-bearing exercise combined with LBNP ameliorates some of the negative effects of simulated weightlessness on bone metabolism. This protocol may pave the way to counteracting bone loss during spaceflight and may provide valuable information about normal and abnormal bone physiology here on Earth.

Published
2003

28. Noninvasive indicators of intracranial pressure before, during, and after long-duration spaceflight

Author

Jasien, Jessica V., primary, Laurie, Steven S., additional, Lee, Stuart M. C., additional, Martin, David S., additional, Kemp, David T., additional, Ebert, Douglas J., additional, Ploutz-Snyder, Robert, additional, Marshall-Goebel, Karina, additional, Alferova, Irina V., additional, Sargsyan, Ashot, additional, Danielson, Richard W., additional, Hargens, Alan R., additional, Dulchavsky, Scott A., additional, Stenger, Michael B., additional, and Macias, Brandon R., additional

Published
2022
Full Text
View/download PDF

33. Submacular Choroid Thickness Increases During Long-Duration Spaceflight

Author

Laurie, Steven S, Macias, Brandon R, Ferguson, Connor R, Dunn, Jocelyn T, Ebert, Doug, Liu, John H.K, Lee, Stuart M. C, Dulchavsky, Scott A, Hargens, Alan R, and Stenger, Michael B

Subjects
Optics
Abstract

The Spaceflight Associated Neuro-ocular Syndrome (SANS) is characterized by the development of optic disc edema, choroidal folds, cotton-wool spots, globe flattening, and/or refractive error changes greater than or equal to 0.75D during long-duration spaceflight to the International Space Station (ISS). It is hypothesized that these findings result from the headward fluid shift that occurs due to weightlessness. We can induce a headward fluid shift on Earth using positional changes and on ISS due to weightlessness. Lower-body negative pressure (LBNP) is used to reverse the headward fluid shift by drawing fluid into the lower body and can be used on Earth and on ISS.

Published
2018

35. Changes in Optic Nerve Head and Retinal Morphology During Spaceflight and Acute Fluid Shift Reversal

Author

Pardon, Laura P., primary, Macias, Brandon R., additional, Ferguson, Connor R., additional, Greenwald, Scott H., additional, Ploutz-Snyder, Robert, additional, Alferova, Irina V., additional, Ebert, Doug, additional, Dulchavsky, Scott A., additional, Hargens, Alan R., additional, Stenger, Michael B., additional, and Laurie, Steven S., additional

Published
2022
Full Text
View/download PDF

43. Fluid Shifts

Author

Stenger, M. B, Hargens, A. R, Dulchavsky, S. A, Arbeille, P, Danielson, R. W, Ebert, D. J, Garcia, K. M, Johnston, S. L, Laurie, S. S, Lee, S. M. C, Liu, J, Macias, B, Martin, D. S, Minkoff, L, Ploutz-Snyder, R, Ribeiro, L. C, Sargsyan, A, and Smith, S. M

Subjects
Aerospace Medicine
Abstract

Introduction. NASA's Human Research Program is focused on addressing health risks associated with long-duration missions on the International Space Station (ISS) and future exploration-class missions beyond low Earth orbit. Visual acuity changes observed after short-duration missions were largely transient, but now more than 50 percent of ISS astronauts have experienced more profound, chronic changes with objective structural findings such as optic disc edema, globe flattening and choroidal folds. These structural and functional changes are referred to as the visual impairment and intracranial pressure (VIIP) syndrome. Development of VIIP symptoms may be related to elevated intracranial pressure (ICP) secondary to spaceflight-induced cephalad fluid shifts, but this hypothesis has not been tested. The purpose of this study is to characterize fluid distribution and compartmentalization associated with long-duration spaceflight and to determine if a relation exists with vision changes and other elements of the VIIP syndrome. We also seek to determine whether the magnitude of fluid shifts during spaceflight, as well as any VIIP-related effects of those shifts, are predicted by the crewmember's pre-flight status and responses to acute hemodynamic manipulations, specifically posture changes and lower body negative pressure. Methods. We will examine a variety of physiologic variables in 10 long-duration ISS crewmembers using the test conditions and timeline presented in the figure below. Measures include: (1) fluid compartmentalization (total body water by D2O, extracellular fluid by NaBr, intracellular fluid by calculation, plasma volume by CO rebreathe, interstitial fluid by calculation); (2) forehead/eyelids, tibia, and calcaneus tissue thickness (by ultrasound); (3) vascular dimensions by ultrasound (jugular veins, cerebral and carotid arteries, vertebral arteries and veins, portal vein); (4) vascular dynamics by MRI (head/neck blood flow, cerebrospinal fluid pulsatility); (5) ocular measures (optical coherence tomography; intraocular pressure; 2-dimensional ultrasound including optic nerve sheath diameter, globe flattening, and retina-choroid thickness; Doppler ultrasound of ophthalmic and retinal arteries and veins); (6) cardiac variables by ultrasound (inferior vena cava, tricuspid flow and tissue Doppler, pulmonic valve, stroke volume, right heart dimensions and function, four-chamber views); and (7) ICP measures (tympanic membrane displacement, otoacoustic emissions). Pre- and post-flight, acute head-down tilt will induce cephalad fluid shifts, whereas lower body negative pressure will oppose these shifts. Controlled Mueller maneuvers will manipulate cardiovascular variables. Through interventions applied before, during, and after flight, we intend to fully evaluate the relationship between fluid shifts and the VIIP syndrome. Discussion. Ten subjects have consented to participate in this experiment, including the recent One-Year Mission crewmembers, who have recently completed R plus180 testing; all other subjects have completed pre-flight testing. Preliminary results from the One-Year Mission crewmembers will be presented, including measures of ocular structure and function, vascular dimensions, fluid distribution, and non-invasive estimates of intracranial pressure.

Published
2017

44. Ground-Based Studies of Headward Fluid Shifts Related to Space Flight

Author

Petersen, L. G, Watkins, W, Hargens, A. R, and Macias, B. R

Subjects
Aerospace Medicine
Abstract

Long-term space flight decreases visual acuity in more than 50% of astronauts with some reports of post-flight lumbar opening pressures up to 21 mmHg1. Loss of hydrostatic (gravitational) pressures in microgravity shifts blood, spinal fluid and tissue fluids towards the head, probably causing venous congestion and leading to symptoms compatible with chronically increased intracranial pressure (ICP). This is characterized as the Visual Impairment and Intracranial Pressure (VIIP) syndrome. Simulation of gravitational stress by application of Lower Body Negative Pressure (LBNP) is proposed as a means to reduce ICP and reestablish cerebral health in astronauts during long mission stay in space. We hypothesize that 50 mmHg of lower body negative pressure (LBNP) during supine and simulated intracranial hypertension by 15 deg head-down tilt (HDT) counteracts elevations in ICP and internal jugular vein crosssectional area (IJV CSA).

Published
2017

45. Noninvasive Measurement of Pulsatile Intracranial Pressure Using Ultrasound

Author

Ueno, T., Ballard, R. E., Shuer, L. M., Cantrell, J. H., Yost, W. T., Hargens, Alan R., Reulen, Hans-J., editor, Steiger, H.-J., editor, Marmarou, Anthony, editor, Bullock, Ross, editor, Avezaat, Cees, editor, Baethmann, Alexander, editor, Becker, Donald, editor, Brock, Mario, editor, Hoff, Julian, editor, Nagai, Hajime, editor, and Teasdale, Graham, editor

Published
1998
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results