Department of Physical Therapy

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    A Handheld Quantifiable Soft Tissue Manipulation Device for Tracking Real-Time Dispersive Force-Motion Patterns to Characterize Manual Therapy Treatment
    (IEEE, 2023) Bhattacharjee, Abhinaba; Anwar, Sohel; Chien, Stanley; Loghmani, M. Terry; Physical Therapy, School of Health and Human Sciences
    Objective: Low back pain (LBP) is one of the leading neuromusculoskeletal (NMSK) problems around the globe. Soft Tissue Manipulation (STM) is a force-based, non-invasive intervention used to clinically address NMSK pain conditions. Current STM practice standards are mostly subjective, suggesting an urgent need for quantitative metrics. This research aims at developing a handheld, portable smart medical device for tracking real-time dispersive force-motions to characterize manual therapy treatments as Quantifiable Soft Tissue Manipulation (QSTM). Methods: The device includes two 3D load-cells to quantify compressive and planar-shear forces, coupled with a 6 degrees-of-freedom IMU sensor for acquiring volitionally adapted therapeutic motions while scanning and mobilizing myofascial restrictions over larger areas of the body. These force-motions characterize QSTM with treatment parameters (targeted force, application angle, rate, direction, motion pattern, time) as a part of post-processing on a PC software (Q-Ware©). A human case study was conducted to treat LBP as proof-of-concept for the device's clinical usability. Results: External validation of treatment parameters reported adequate device precision required for clinical use. The case study findings revealed identifiable therapeutic force-motion patterns within treatments indicating subject's elevated force-endurance with self-reported pain reduction. Conclusion: QSTM metrics may enable study of STM dosing for optimized pain reduction and functional outcomes using documentable manual therapy. Clinical trials will further determine its reliability and comparison to conventional STM. Significance: This medical device technology not only advances the state-of-the-art manual therapy with precision rehabilitation but also augments practice with reproducibility to examine neurobiological responses of individualized STM prescriptions for NMSK pathology.
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    Achilles tendon material properties are greater in the jump leg of jumping athletes
    (ISMNI, 2016-06) Bayliss, Amy J.; Weatherholt, Alyssa M.; Crandall, Trent T.; Farmer, Danielle L.; McConnell, Jethro C.; Crossley, K. M.; Warden, Stuart J.; Department of Physical Therapy, School of Health and Rehabilitation Sciences
    Purpose: The Achilles tendon (AT) must adapt to meet changes in demands. This study explored AT adaptation by comparing properties within the jump and non-jump legs of jumping athletes. Non-jumping control athletes were included to control limb dominance effects. Methods: AT properties were assessed in the preferred (jump) and non-preferred (lead) jumping legs of male collegiate-level long and/or high jump (jumpers; n=10) and cross-country (controls; n=10) athletes. Cross-sectional area (CSA), elongation, and force during isometric contractions were used to estimate the morphological, mechanical and material properties of the ATs bilaterally. Results: Jumpers exposed their ATs to more force and stress than controls (all p≤0.03). AT force and stress were also greater in the jump leg of both jumpers and controls than in the lead leg (all p<0.05). Jumpers had 17.8% greater AT stiffness and 24.4% greater Young’s modulus in their jump leg compared to lead leg (all p<0.05). There were no jump versus lead leg differences in AT stiffness or Young’s modulus within controls (all p>0.05). Conclusion: ATs chronically exposed to elevated mechanical loading were found to exhibit greater mechanical (stiffness) and material (Young’s modulus) properties.
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    Adaptation of the CARE Guidelines for Therapeutic Massage and Bodywork Publications: Efforts To Improve the Impact of Case Reports
    (2014-09) Munk, Niki; Boulanger, Karen
    Case reports provide the foundation of practice-based evidence for therapeutic massage and bodywork (TMB), as well as many other health-related fields. To improve the consistency of information contained in case reports, the CARE (CAse REport) Group developed and published a set of guidelines for the medical community to facilitate systematic data collection (http://www.care-statement.org/#). Because of the differences between the practice of medicine and TMB, modifying some sections of the CARE guidelines is necessary to make them compatible with TMB case reports. Accordingly, the objectives of this article are to present the CARE guidelines, apply each section of the guidelines to TMB practice and reporting with suggested adaptations, and highlight concerns, new ideas, and other resources for potential authors of TMB case reports. The primary sections of the CARE guidelines adapted for TMB case reports are diagnostic assessment, follow-up and outcomes, and therapeutic intervention. Specifically, because diagnosis falls outside of the scope of most TMB practitioners, suggestions are made as to how diagnoses made by other health care providers should be included in the context of a TMB case report. Additionally, two new aspects of the case presentation section are recommended: a) assessment measures, which outline and describe the outcome measures on which the case report will focus, and b) a description of the TMB provider (i.e., scope of practice, practice environment, experience level, training, credentialing, and/or expertise) as part of the intervention description. This article culminates with practical resources for TMB practitioners writing case reports, including a TMB Case Report Template—a single document that TMB practitioners can use to guide his or her process of writing a case report. Once the template is adopted by authors of TMB case reports, future efforts can explore the impact on the quality and quantity of case reports and how they impact TMB practice, research, education and, ultimately, the clients.
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    Adaptation of the proximal humerus to physical activity: a within-subject controlled study in baseball players
    (Elsevier, 2019-01-08) Warden, Stuart J.; Carballido-Gamio, Julio; Avin, Keith G.; Kersh, Mariana E.; Fuchs, Robyn K.; Krug, Roland; Bice, Ryan; Physical Therapy, School of Health and Human Sciences
    The proximal humerus is a common, yet understudied site for osteoporotic fracture. The current study explored the impact of prolonged physical activity on proximal humerus bone health by comparing bone properties between the throwing and nonthrowing arms within professional baseball players. The proximal humerus in throwing arms had 28.1% (95% CI, 17.8 to 38.3%) greater bone mass compared to nonthrowing arms, as assessed using dual-energy x-ray absorptiometry. At the level of the surgical neck, computed tomography revealed 12.0% (95% CI, 8.2 to 15.8%) greater total cross-sectional area and 31.0% (95% CI, 17.8 to 44.2%) greater cortical thickness within throwing arms, which contributed to 56.8% (95% CI, 44.9 to 68.8%) greater polar moment of inertia (i.e., estimated ability to resist torsional forces) compared to nonthrowing arms. Within the humeral head and greater tubercle regions, throwing arms had 3.1% (95% CI, 1.1 to 5.1%) more trabecular bone, as assessed using high-resolution magnetic resonance imaging. Three-dimensional mapping of voxel- and vertex-wise differences between arms using statistical parametric mapping techniques revealed throwing arms had adaptation within much of the proximal diaphysis, especially the posterolateral cortex. The pattern of proximal diaphysis adaptation approximated the pattern of strain energy distribution within the proximal humerus during a fastball pitch derived from a musculoskeletal and finite element model in a representative player. These data demonstrate the adaptive ability of the proximal humerus to physical activity-related mechanical loads. It remains to be established how they translate to exercise prescription to improve bone health within the proximal humerus, however, they provide unique insight into the relationship between prolonged loading and skeletal adaptation at a clinically relevant osteoporotic site.
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    Am I big boned? Bone length scaled reference data for HRpQCT measures of the radial and tibial diaphysis in White adults
    (Elsevier, 2024-01-06) Warden, Stuart J.; Fuchs, Robyn K.; Liu, Ziyue; Toloday, Katelynn R.; Surowiec, Rachel; Moe, Sharon M.; Physical Therapy, School of Health and Human Sciences
    Cross-sectional size of a long bone shaft influences its mechanical properties. We recently used high-resolution peripheral quantitative computed tomography (HRpQCT) to create reference data for size measures of the radial and tibial diaphyses. However, data did not take into account the impact of bone length. Human bone exhibits relatively isometric allometry whereby cross-sectional area increases proportionally with bone length. The consequence is that taller than average individuals will generally have larger z-scores for bone size outcomes when length is not considered. The goal of the current work was to develop a means of determining whether an individual's cross-sectional bone size is suitable for their bone length. HRpQCT scans performed at 30 % of bone length proximal from the distal end of the radius and tibia were acquired from 1034 White females (age = 18.0 to 85.3 y) and 392 White males (age = 18.4 to 83.6 y). Positive relationships were confirmed between bone length and cross-sectional areas and estimated mechanical properties. Scaling factors were calculated and used to scale HRpQCT outcomes to bone length. Centile curves were generated for both raw and bone length scaled HRpQCT data using the LMS approach. Excel-based calculators are provided to facilitate calculation of z-scores for both raw and bone length scaled HRpQCT outcomes. The raw z-scores indicate the magnitude that an individual's HRpQCT outcomes differ relative to expected sex- and age-specific values, with the scaled z-scores also considering bone length. The latter enables it to be determined whether an individual or population of interest has normal sized bones for their length, which may have implications for injury risk. In addition to providing a means of expressing HRpQCT bone size outcomes relative to bone length, the current study also provides centile curves for outcomes previously without reference data, including tissue mineral density and moments of inertia.
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    Baseball and softball pitchers are distinct within-subject controlled models for exploring proximal femur adaptation to physical activity
    (Springer, 2019-01-21) Fuchs, Robyn K.; Thompson, William R.; Weatherholt, Alyssa M.; Warden, Stuart J.; Physical Therapy, School of Health and Human Sciences
    Purpose: Within-subject controlled models in individuals who preferentially load one side of the body enable efficient exploration of the skeletal benefits of physical activity. There is no established model of physical activity-induced side-to-side differences (i.e., asymmetry) at the proximal femur. Methods: Proximal femur asymmetry was assessed via dual-energy x-ray absorptiometry in male jumping athletes (JMP, n=16), male baseball pitchers (BB, n=21), female fast-pitch softball pitchers (SB, n=22), and controls (CON, n=42). The jumping leg was the dominant leg in JMP, whereas in BB, SB and CON the dominant leg was contralateral to the dominant/throwing arm. Results: BB and SB had 5.5% (95%CI, 3.9 to 7.0%) and 6.5% (95%CI, 4.8 to 8.2%) dominant-to-nondominant leg differences for total hip areal bone mineral density (aBMD), with the asymmetry being greater than both CON and JMP (p<0.05). BB and SB also possessed dominant-to-nondominant leg differences in femoral neck and trochanteric aBMD (p<0.001). SB had 9.7% (95% CI, 6.4 to 13.0%) dominant-to-nondominant leg differences in femoral neck bone mineral content, which was larger than any other group (p≤0.006). At the narrow neck, SB had large (>8%) dominant-to-nondominant leg differences in cross-sectional area, cross-sectional moment of inertia and section modulus, which were larger than any other group (p≤0.02). Conclusion: Male baseball and female softball pitchers are distinct within-subject controlled models for exploring adaptation of the proximal femur to physical activity. They exhibit adaptation in their dominant/landing leg (i.e., leg contralateral to the throwing arm), but the pattern differs with softball pitchers exhibiting greater femoral neck adaptation.
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    Become one with the force: optimising mechanotherapy through an understanding of mechanobiology
    (BMJ Journals, 2017-07) Warden, Stuart J; Thompson, William R; Physical Therapy, School of Health and Rehabilitation Sciences
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    Bone Microarchitecture and Strength Adaptation to Physical Activity: A Within-Subject Controlled, HRpQCT Study
    (Wolters Kluwer, 2021) Warden, Stuart J.; Wright, Christian S.; Fuchs, Robyn K.; Physical Therapy, School of Health and Rehabilitation Sciences
    Purpose Physical activity benefits bone mass and cortical bone size. The current study assessed the impact of chronic (≥10 years) physical activity on trabecular microarchitectural properties and micro-finite element (μFE) analyses of estimated bone strength. Methods Female collegiate-level tennis players (n=15; age=20.3±0.9 yrs) were used as a within-subject controlled model of chronic unilateral upper-extremity physical activity. Racquet-to-nonracquet arm differences at the distal radius and radial diaphysis were assessed using high-resolution peripheral computed tomography (HRpQCT). The distal tibia and tibial diaphysis in both legs were also assessed, and cross-country runners (n=15; age=20.8±1.2 yrs) included as controls. Results The distal radius of the racquet arm had 11.8% (95% confidence interval [CI], 7.9 to 15.7%) greater trabecular bone volume/tissue volume, with trabeculae that were greater in number, thickness, connectivity, and proximity to each other than in the nonracquet arm (all p<0.01). Combined with enhanced cortical bone properties, the microarchitectural advantages at the distal radius contributed a 18.7% (95% CI, 13.0 to 24.4%) racquet-to-nonracquet arm difference in predicted load before failure. At the radial diaphysis, predicted load to failure was 9.6% (95% CI, 6.7 to 12.6%) greater in the racquet vs. nonracquet arm. There were fewer and smaller side-to-side differences at the distal tibia; however, the tibial diaphysis in the leg opposite the racquet arm was larger with a thicker cortex and had 4.4% (95% CI, 1.7 to 7.1%) greater strength than the contralateral leg. Conclusion Chronically elevated physical activity enhances trabecular microarchitecture and μFE estimated strength, furthering observations from short-term longitudinal studies. The data also demonstrate tennis players exhibit crossed symmetry wherein the leg opposite the racquet arm possesses enhanced tibial properties compared to in the contralateral leg.
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    Case Reports: A Meaningful Way for Massage Practice to Inform Research and Education
    (2013-09) Munk, Niki
    Practice-induced challenges to massage research and education include those related to disparate training standards, requirements, and expectations across the US, North America, and internationally. These challenges should not overshadow the need for practice to inform research and education, especially in light of the move towards effectiveness research. What remains constantly applicable to massage practitioners of all locations and from all backgrounds are treatment details regarding the techniques used, client/patient characteristics, condition/issue of complaint, provider and client/patient expectations, and outcomes. Case reports provide a venue for this information to be shared across all practitioners, educators, and researchers. While many massage practitioners are not trained in scientific writing, preparing and publishing a case report need not be daunting, especially with writing partners when writing burden can be shared. Writing in isolation can be challenging, even for trained researchers. Perceived practitioner contribution and credit are not reduced when authorship in a manuscript is shared; rather it may be enhanced with an experienced partner.
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    Cell Mechanosensitivity to Extremely Low Magnitude Signals is Enabled by a LINCed Nucleus
    (Wiley, 2015-06) Uzer, Gunes; Thompson, William R.; Sen, Buer; Xie, Zhihui; Yen, Sherwin S.; Miller, Sean; Bas, Guniz; Styner, Maya; Rubin, Clinton T.; Judex, Stefan; Burridge, Keith; Rubin, Janet; Physical Therapy, School of Health and Rehabilitation Sciences
    A cell's ability to recognize and adapt to the physical environment is central to its survival and function, but how mechanical cues are perceived and transduced into intracellular signals remains unclear. In mesenchymal stem cells (MSCs), high-magnitude substrate strain (HMS, ≥2%) effectively suppresses adipogenesis via induction of focal adhesion (FA) kinase (FAK)/mTORC2/Akt signaling generated at FAs. Physiologic systems also rely on a persistent barrage of low-level signals to regulate behavior. Exposing MSC to extremely low-magnitude mechanical signals (LMS) suppresses adipocyte formation despite the virtual absence of substrate strain (<0.001%), suggesting that LMS-induced dynamic accelerations can generate force within the cell. Here, we show that MSC response to LMS is enabled through mechanical coupling between the cytoskeleton and the nucleus, in turn activating FAK and Akt signaling followed by FAK-dependent induction of RhoA. While LMS and HMS synergistically regulated FAK activity at the FAs, LMS-induced actin remodeling was concentrated at the perinuclear domain. Preventing nuclear-actin cytoskeleton mechanocoupling by disrupting linker of nucleoskeleton and cytoskeleton (LINC) complexes inhibited these LMS-induced signals as well as prevented LMS repression of adipogenic differentiation, highlighting that LINC connections are critical for sensing LMS. In contrast, FAK activation by HMS was unaffected by LINC decoupling, consistent with signal initiation at the FA mechanosome. These results indicate that the MSC responds to its dynamic physical environment not only with "outside-in" signaling initiated by substrate strain, but vibratory signals enacted through the LINC complex enable matrix independent "inside-inside" signaling.