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9. Low Magnitude Mechanical Signals Reduce Risk-Factors for Fracture during 90-Day Bed Rest

Author

Muir, J. W, Xia, Y, Holquin, N, Judex, S, Qin, Y, Evans, H, Lang, T, and Rubin, C

Subjects
Aerospace Medicine
Abstract

Long duration spaceflight leads to multiple deleterious changes to the musculoskeletal system, where loss of bone density, an order of magnitude more severe than that which follows the menopause, combined with increased instability, conspire to elevate the risk of bone fracture due to falls on return to gravitational fields. Here, a ground-based analog for spaceflight is used to evaluate the efficacy of a low-magnitude mechanical intervention, VIBE (Vibrational Inhibition of Bone Erosion), as a potential countermeasure to preserve musculoskeletal integrity in the face of disuse. Twenty-six subjects consented to ninety days of six-degree head-down tilt bed-rest. 18 completed the 90d protocol, 8 of which received daily 10-minute exposure to 30 Hz, 0.3g VIBE, applied in the supine position using a vest elastically coupled to the vibrating platform. The shoulder harness induced a load of 60% of the subjects body weight. At baseline and 90d, Qualitative Ultrasound Scans (QUS) of the calcaneus and CT-scans of the hip and spine were performed to measure changes in bone density. Postural control (PC) was assessed through center of pressure (COP) recordings while subjects stood on a force platform for 4 minutes of quiet stance with eyes closed, and again with eyes opened. As compared to control bedrest subjects

Published
2007

10. The anabolic activity of bone tissue, suppressed by disuse, is normalized by brief exposure to extremely low-magnitude mechanical stimuli

Author

Rubin, C, Xu, G, and Judex, S

Subjects
Life Sciences (General)
Abstract

It is generally believed that mechanical signals must be large in order to be anabolic to bone tissue. Recent evidence indicates, however, that extremely low-magnitude (<10 microstrain) mechanical signals readily stimulate bone formation if induced at a high frequency. We examined the ability of extremely low-magnitude, high-frequency mechanical signals to restore anabolic bone cell activity inhibited by disuse. Adult female rats were randomly assigned to six groups: baseline control, age-matched control, mechanically stimulated for 10 min/day, disuse (hind limb suspension), disuse interrupted by 10 min/day of weight bearing, and disuse interrupted by 10 min/day of mechanical stimulation. After a 28 day protocol, bone formation rates (BFR) in the proximal tibia of mechanically stimulated rats increased compared with age-matched control (+97%). Disuse alone reduced BFR (-92%), a suppression only slightly curbed when disuse was interrupted by 10 min of weight bearing (-61%). In contrast, disuse interrupted by 10 min per day of low-level mechanical intervention normalized BFR to values seen in age-matched controls. This work indicates that this noninvasive, extremely low-level stimulus may provide an effective biomechanical intervention for the bone loss that plagues long-term space flight, bed rest, or immobilization caused by paralysis.

Published
2001
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27. Limitations in the use of predominant collagen fiber orientation for inferring loading history in cortical bone

Author

Skedros, J.G., Demes, B., and Judex, S.

Subjects
Bones -- Methods, Bones -- Physiological aspects, Bones -- Testing, Stress (Physiology) -- Methods, Stress (Physiology) -- Measurement, Primates -- Physiological aspects, Anthropology/archeology/folklore
Abstract

Predominant collagen fiber orientation (CFO) is considered to be highly reliable for inferring loading history in bones where obtaining strain data is difficult or impossible. For example, predominant CFO has been used to indirectly establish putative differences in habitual strain mode (e.g., tension, compression) distribution across the femoral necks of chimpanzees and humans (chimps: habitual bending; humans: net compression) (Kalmey and Lovejoy, 2002 Bone). However, few studies have examined the reliability of using this characteristic in this context. The ulnae of rhesus macaques (n=4) and tarsometatarsi (TMT) of chickens (n=7) were obtained from mature animals. The medial ulna and cranial TMT cortices sustain net compression; the lateral ulna and caudal TMT cortices sustain net tension during functional ambulation. Using circularly polarized light, we quantified predominant CFO in the cranial, caudal, medial, and lateral cortices. `Control' bones included horse radio and deer calcanei (habitual bending), and sheep tibiae (torsional loading). Expected results include CFO that is significantly more longitudinal in 'tension' regions vs. oblique-to-transverse CFO in 'compression' regions, and no significant regional differences in torsional loading. The results were unexpected: 1) TMTs: the cranial ('compression') cortex had more longitudinal CFO than the opposing 'tension' cortex, 2) ulnae: the medial vs. lateral ('compression' vs. 'tension') differences were insignificant. In two ulnae, there was evidence of newly deposited bone, suggesting that cortical maturity lags behind growth plate fusion. But this explanation is not parsimonious for the TMTs. These data suggest that significant limitations may exist when using predominant CFO for inferring strain history.

Published
2003

32. Genetic and tissue level muscle-bone interactions during unloading and reambulation

Author

Judex, S., Zhang, W., Donahue, L. R., Engin Ozcivici, TR30296, Özçivici, Engin, and Izmir Institute of Technology. Biotechnology and Bioengineering

Subjects
Genetic regulation, Mouse, Quantitative Trait Loci, X-Ray Microtomography, Bone and Bones, Disease Models, Animal, Mice, Hindlimb Suspension, Tissue level, Genetics, Muscle, Animals, Original Article, sense organs, Muscle, Skeletal, Bone, Disuse
Abstract

Little is known about interactions between muscle and bone during the removal and application of mechanical signals. Here, we applied 3wk of hindlimb unloading followed by 3wk of reambulation to a genetically heterogeneous population of 352 adult mice and tested the hypothesis that changes in muscle are associated with changes in bone at the level of the tissue and the genome. During unloading and relative to normally ambulating control mice, most mice lost muscle and cortical bone with large variability across the population. During reambulation, individual mice regained bone and muscle at different rates. Across mice, changes in muscle and trabecular/cortical bone were not correlated to each other during unloading or reambulation. For unloading, we found one significant quantitative trait locus (QTL) for muscle area and five QTLs for cortical bone without overlap between mechano-sensitive muscle and cortical bone QTLs (but some overlap between muscle and trabecular QTLs). The low correlations between morphological changes in muscle and bone, together with the largely distinct genetic regulation of the response indicate that the premise of a muscle-bone unit that co-adjusts its size during (un)loading may need to be reassessed. © 2016, International Society of Musculoskeletal and Neuronal Interactions. All rights reserved., NASA (NAG 9-1499 -- NNX-12AL25G)

42. Low-Intensity Vibration Protects the Weight-Bearing Skeleton and Suppresses Fracture Incidence in Boys With Duchenne Muscular Dystrophy: A Prospective, Randomized, Double-Blind, Placebo-Controlled Clinical Trial.

Author

Bianchi ML, Vai S, Baranello G, Broggi F, Judex S, Hangartner T, and Rubin C

Abstract

The ability of low-intensity vibration (LIV) to combat skeletal decline in Duchenne Muscular Dystrophy (DMD) was evaluated in a randomized controlled trial. Twenty DMD boys were enrolled, all ambulant and treated with glucocorticoids (mean age 7.6, height-adjusted Z -scores [HAZ] of hip bone mineral density [BMD] -2.3). Ten DMD boys were assigned to stand for 10 min/d on an active LIV platform (0.4 g at 30 Hz), while 10 stood on a placebo device. Baseline and 14-month bone mineral content (BMC) and BMD of spine, hip, and total body were measured with DXA, and trabecular bone density (TBD) of tibia with quantitative computed tomography (QCT). All children tolerated the LIV intervention well, with daily compliance averaging 78%. At 14 months, TBD in the proximal and distal tibia remained unchanged in placebo subjects (-1.0% and -0.2%), while rising 3.5% and 4.6% in LIV subjects. HAZ for hip BMD and BMC in the placebo group declined 22% and 13%, respectively, contrasting with no change from baseline (0.9% and 1.4%) in the LIV group. Fat mass in the leg increased 32% in the placebo group, contrasting with 21% in LIV subjects. Across the 14-month study, there were four incident fractures in three placebo patients (30%), with no new fractures identified in LIV subjects. Despite these encouraging results, a major limitation of the study is-despite randomized enrollment-that there was a significant difference in age between the two cohorts, with the LIV group being 2.8y older, and thus at greater severity of disease. In sum, these data suggest that noninvasive LIV can help protect the skeleton of DMD children against the disease progression, the consequences of diminished load bearing, and the complications of chronic steroid use. © 2022 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research., Competing Interests: CTR and SJ have several U.S. and international patents issued on the use of low intensity vibration for the treatment of musculoskeletal injury and disease. CTR is also a founder of Marodyne, Inc., who developed the LIV platform for clinical use as LivMD. No other authors have any conflicts to report., (© 2022 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research.)

Published
2022
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43. Modeling stem cell nucleus mechanics using confocal microscopy.

Author

Kennedy Z, Newberg J, Goelzer M, Judex S, Fitzpatrick CK, and Uzer G

Subjects
Animals, Chromatin metabolism, Elasticity, Lamin Type A metabolism, Male, Mice, Inbred C57BL, Microscopy, Atomic Force, RNA, Small Interfering metabolism, Mice, Cell Nucleus metabolism, Microscopy, Confocal, Models, Biological, Stem Cells cytology
Abstract

Nuclear mechanics is emerging as a key component of stem cell function and differentiation. While changes in nuclear structure can be visually imaged with confocal microscopy, mechanical characterization of the nucleus and its sub-cellular components require specialized testing equipment. A computational model permitting cell-specific mechanical information directly from confocal and atomic force microscopy of cell nuclei would be of great value. Here, we developed a computational framework for generating finite element models of isolated cell nuclei from multiple confocal microscopy scans and simple atomic force microscopy (AFM) tests. Confocal imaging stacks of isolated mesenchymal stem cells were converted into finite element models and siRNA-mediated Lamin A/C depletion isolated chromatin and Lamin A/C structures. Using AFM-measured experimental stiffness values, a set of conversion factors were determined for both chromatin and Lamin A/C to map the voxel intensity of the original images to the element stiffness, allowing the prediction of nuclear stiffness in an additional set of other nuclei. The developed computational framework will identify the contribution of a multitude of sub-nuclear structures and predict global nuclear stiffness of multiple nuclei based on simple nuclear isolation protocols, confocal images and AFM tests., (© 2021. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published
2021
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44. Dose-dependent effects of pharmaceutical treatments on bone matrix properties in ovariectomized rats.

Author

Karim L, Kwaczala A, Vashishth D, and Judex S

Abstract

As both anabolic and anti-catabolic osteoporosis drugs affect bone formation and resorption processes, they may contribute to bone's overall mechanical behavior by altering the quality of the bone matrix. We used an ovariectomized rat model and a novel fracture mechanics approach to investigate whether treatment with an anabolic (parathyroid hormone) or anti-catabolic (alendronate) osteoporosis drugs will alter the organic and mineral matrix components and consequently cortical bone fracture toughness. Ovariectomized (at 5 months age) rats were treated with either parathyroid hormone or alendronate at low and high doses for 6 months (age 6-12 months). Specifically, treatment groups included untreated ovariectomized controls (n = 9), high-dose alendronate (n = 10), low-dose alendronate (n = 9), high-dose parathyroid hormone (n = 10), and low-dose parathyroid hormone (n = 9). After euthanasia, cortical microbeams from the lateral quadrant were extracted, notched, and tested in 3-point bending to measure fracture toughness. Portions of the bone were used to measure changes in the 1) organic matrix through quantification of advanced glycation end-products (AGEs) and non-collagenous proteins, and 2) mineral matrix through assessment of mineral crystallinity. Compared to the ovariectomized group, rats treated with high doses of parathyroid hormone and alendronate had significantly increased cortical bone fracture toughness, which corresponded primarily to increased non-collagenous proteins while there was no change in AGEs. Additionally, low-dose PTH treatment increased matrix crystallinity and decreased AGE levels. In summary, ovariectomized rats treated with pharmaceutical drugs had increased non-collagenous matrix proteins and improved fracture toughness compared to controls. Further investigation is required for different doses and longer treatment periods., Competing Interests: None of the authors have conflicts of interest to disclose., (© 2021 The Authors.)

Published
2021
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45. Reporting Guidelines for Whole-Body Vibration Studies in Humans, Animals and Cell Cultures: A Consensus Statement from an International Group of Experts.

Author

van Heuvelen MJG, Rittweger J, Judex S, Sañudo B, Seixas A, Fuermaier ABM, Tucha O, Nyakas C, Marín PJ, Taiar R, Stark C, Schoenau E, Sá-Caputo DC, Bernardo-Filho M, and van der Zee EA

Abstract

Whole-body vibration (WBV) is an exercise modality or treatment/prophylaxis method in which subjects (humans, animals, or cells) are exposed to mechanical vibrations through a vibrating platform or device. The vibrations are defined by their direction, frequency, magnitude, duration, and the number of daily bouts. Subjects can be exposed while performing exercises, hold postures, sitting, or lying down. Worldwide, WBV has attracted significant attention, and the number of studies is rising. To interpret, compare, and aggregate studies, the correct, complete, and consistent reporting of WBV-specific data (WBV parameters) is critical. Specific reporting guidelines aid in accomplishing this goal. There was a need to expand existing guidelines because of continuous developments in the field of WBV research, including but not limited to new outcome measures regarding brain function and cognition, modified designs of WBV platforms and attachments (e.g., mounting a chair on a platform), and comparisons of animal and cell culture studies with human studies. Based on Delphi studies among experts and using EQUATOR recommendations, we have developed extended reporting guidelines with checklists for human and animal/cell culture research, including information on devices, vibrations, administration, general protocol, and subjects. In addition, we provide explanations and examples of how to report. These new reporting guidelines are specific to WBV variables and do not target research designs in general. Researchers are encouraged to use the new WBV guidelines in addition to general design-specific guidelines.

Published
2021
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46. Towards reporting guidelines of research using whole-body vibration as training or treatment regimen in human subjects-A Delphi consensus study.

Author

Wuestefeld A, Fuermaier ABM, Bernardo-Filho M, da Cunha de Sá-Caputo D, Rittweger J, Schoenau E, Stark C, Marin PJ, Seixas A, Judex S, Taiar R, Nyakas C, van der Zee EA, van Heuvelen MJG, and Tucha O

Subjects
Adult, Aged, Delphi Technique, Expert Testimony, Female, Human Body, Humans, Male, Middle Aged, Research, Surveys and Questionnaires, Physical Therapy Modalities, Vibration therapeutic use
Abstract

Background: Whole-body vibration (WBV) is a method utilizing vibrating platforms to expose individuals to mechanical vibration. In its various applications, it has been linked to improved muscular, skeletal, metabolic, or cognitive functioning, quality of life, and physiological parameters such as blood pressure. Most evidence concerning WBV is inconclusive and meta-analytical reviews may not readily produce insights since the research has a risk of misunderstandings of vibration parameters and incomplete reporting occurs. This study aims at laying an empirical foundation for reporting guidelines for human WBV studies to improve the quality of reporting and the currently limited comparability between studies., Method: The Delphi methodology is employed to exploit the integrated knowledge of WBV experts to distil the specific aspects of WBV methodology that should be included in such guidelines. Over three rounds of completing online questionnaires, the expert panel (round 1/2/3: 51/40/37 experts respectively from 17 countries with an average of 19.4 years of WBV research experience) rated candidate items., Results: A 40-item list was established based on the ratings of the individual items from the expert panel with a large final consensus (94.6%)., Conclusion: The final consensus indicates comprehensiveness and valuableness of the list. The results are in line with previous guidelines but expand these extensively. The present results may therefore serve as a foundation for updated guidelines for reporting human WBV studies in order to improve the quality of reporting of WBV studies, improve comparability of studies and facilitate the development of WBV study designs., Competing Interests: The authors have declared that no competing interests exist.

Published
2020
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47. Two-dimensional graphene oxide-reinforced porous biodegradable polymeric nanocomposites for bone tissue engineering.

Author

Farshid B, Lalwani G, Mohammadi MS, Sankaran JS, Patel S, Judex S, Simonsen J, and Sitharaman B

Subjects
Animals, Bone and Bones cytology, Cell Line, Mice, Porosity, Biodegradable Plastics chemistry, Biodegradable Plastics pharmacology, Bone and Bones metabolism, Graphite chemistry, Graphite pharmacology, Materials Testing, Nanocomposites chemistry, Tissue Engineering
Abstract

This study investigates the mechanical properties and in vitro cytotoxicity of two-dimensional (2D) graphene oxide nanoribbons and nanoplatelets (GONRs and GONPs) reinforced porous polymeric nanocomposites. Highly porous poly(propylene fumarate) (PPF) nanocomposites were prepared by dispersing 0.2 wt % single- and multiwalled SONRs (SWGONRs and MWGONRs) and GONPs. The mechanical properties of scaffolds were characterized using compression testing and in vitro cytocompatibility was assessed using QuantiFlour assay for cellularity and PrestoBlue assay for cell viability. Immunofluorescence was used to assess collagen-I expression and deposition in the extracellular matrix. Porous PPF scaffolds were used as a baseline control and porous single and multiwalled carbon nanotubes (SWCNTs and MWCNTs) reinforced nanocomposites were used as positive controls. Results show that incorporation of 2D graphene nanomaterials leads to an increase in the mechanical properties of porous PPF nanocomposites with following the trend: MWGONRs > GONPs > SWGONRs > MWCNTs > SWCNTs > PPF control. MWGONRs showed the best enhancement of compressive mechanical properties with increases of up to 26% in compressive modulus (i.e., Young's modulus), ~60% in yield strength, and ~24% in the ultimate compressive strength. Addition of 2D nanomaterials did not alter the cytocompatibility of porous PPF nanocomposites. Furthermore, PPF nanocomposites reinforced with SWGONRs, MWGONRs, and GONPs show an improvement in the adsorption of collagen-I compared to PPF baseline control. The results of this study show that 2D graphene nanomaterial reinforced porous PPF nanocomposites possess superior mechanical properties, cytocompatibility, and increased protein adsorption. The favorable cytocompatibility results opens avenues for in vivo safety and efficacy studies for bone tissue engineering applications. © 2019 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 107A: 1143-1153, 2019., (© 2019 Wiley Periodicals, Inc.)

Published
2019
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48. Absence of complement factor H alters bone architecture and dynamics.

Author

Alexander JJ, Sankaran JS, Seldeen KL, Thiyagarajan R, Jacob A, Quigg RJ, Troen BR, and Judex S

Subjects
Actins metabolism, Animals, Biomarkers, Bone Resorption genetics, Bone Resorption metabolism, Bone Resorption pathology, Bone and Bones diagnostic imaging, Bone and Bones pathology, Complement Factor H genetics, Complement Factor H metabolism, Fluorescent Antibody Technique, Immunohistochemistry, Mice, Mice, Knockout, Osteoblasts immunology, Osteoblasts metabolism, Osteoclasts immunology, Osteoclasts metabolism, Phenotype, X-Ray Microtomography, Bone and Bones immunology, Bone and Bones metabolism, Complement Factor H immunology
Abstract

Complement system is an important arm of the immune system that promotes inflammation. Complement Factor H (FH) is a critical regulator of the alternative complement pathway. Its absence causes pathology in different organs resulting in diseases such as age related macular degeneration and dense deposit disease. Recent studies suggest that the complement system plays a role in bone development and homeostasis. To determine the role of FH in bone architecture, we studied the FH knockout (fh-/-) mice. 3D reconstructions of femur from 16 week old fh-/- mice reveal significant changes, such as decreased BV/TV (4.5%, p < 0.02), trabecular number (22%, p < 0.01), tissue mineral density (16%, p < 0.04), and increased marrow area (16% p < 0.01), compared to their wild type (WT) counterparts. Kidney function and histology remained normal indicating that bone changes occurred prior to kidney dysfunction. Next we examined cultured osteoblasts and osteoclasts isolated from bone marrow. FH is expressed ubiquitously in the osteoblasts and in the cytoplasm of osteoclasts. The changes caused by absence of FH include: increase in number of osteoblasts (362%) and osteoclasts (342%), increase in RNA (180%) and protein expression of cathepsin K and increased osteoclast function (pit formation, 233%). Actin rearrangement in both osteoblasts and osteoclasts was altered, with a loss of integrity of the F-actin ring at the periphery of the osteoclasts. For the first time our studies demonstrate a direct role of FH in the maintenance of bone structure and function and is highlighted as a promising therapeutic target in bone diseases., (Copyright © 2018 Elsevier GmbH. All rights reserved.)

Published
2018
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49. Differential Efficacy of 2 Vibrating Orthodontic Devices to Alter the Cellular Response in Osteoblasts, Fibroblasts, and Osteoclasts.

Author

Judex S and Pongkitwitoon S

Abstract

Modalities that increase the rate of tooth movement have received considerable attention, but direct comparisons between devices are rare. Here, we contrasted 2 mechanical vibratory devices designed to directly transfer vibrations into alveolar bone as a means to influence bone remodeling. To this end, 3 cells types intimately involved in modulating tooth movements-osteoblasts, periodontal ligament fibroblasts, and osteoclasts-were subjected to in vitro vibrations at bout durations prescribed by the manufacturers. As quantified by an accelerometer, vibration frequency and peak accelerations were 400% and 70% greater in the VPro5 (Propel Orthodontics) than in the AcceleDent (OrthoAccel Technologies) device. Both devices caused increased cell proliferation and gene expression in osteoblasts and fibroblasts, but the response to VPro5 treatment was greater than for the AcceleDent. In contrast, the ability to increase osteoclast activity was device independent. These data present an important first step in determining how specific cell types important for facilitating tooth movement respond to different vibration profiles. The device that engendered a higher vibration frequency and larger acceleration (VPro5) was superior in stimulating osteoblast and fibroblast cell proliferation/gene expression, although the duration of each treatment bout was 75% shorter than for the AcceleDent., Competing Interests: Declaration of Conflicting Interests: The author(s) declared the following potential conflicts of interest with respect to the research, authorship, and/or publication of this article: Professor Judex holds (provisional) patents on the effect of vibrations in biologic systems.

Published
2018
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50. Low-Intensity Vibration Improves Muscle Healing in a Mouse Model of Laceration Injury.

Author

Corbiere TF, Weinheimer-Haus EM, Judex S, and Koh TJ

Abstract

Recovery from traumatic muscle injuries is typically prolonged and incomplete, leading to impaired muscle and joint function. We sought to determine whether mechanical stimulation via whole-body low-intensity vibration (LIV) could (1) improve muscle regeneration and (2) reduce muscle fibrosis following traumatic injury. C57BL/6J mice were subjected to a laceration of the gastrocnemius muscle and were treated with LIV (0.2 g at 90 Hz or 0.4 g at 45 Hz for 30 min/day) or non-LIV sham treatment (controls) for seven or 14 days. Muscle regeneration and fibrosis were assessed in hematoxylin and eosin or Masson's trichrome stained muscle cryosections, respectively. Compared to non-LIV control mice, the myofiber cross-sectional area was larger in mice treated with each LIV protocol after 14 days of treatment. Minimum fiber diameter was also larger in mice treated with LIV of 90 Hz/0.2 g after 14 days of treatment. There was also a trend toward a reduction in collagen deposition after 14 days of treatment with 45 Hz/0.4 g ( p = 0.059). These findings suggest that LIV may improve muscle healing by enhancing myofiber growth and reducing fibrosis. The LIV-induced improvements in muscle healing suggest that LIV may represent a novel therapeutic approach for improving the healing of traumatic muscle injuries., Competing Interests: Conflicts of Interest: Timothy J. Koh and Stefan Judex have a patent pending regarding the application of vibrations for therapeutic treatment. Eileen M. Weinheimer-Haus and Thomas F. Corbiere certify that he or she, or a member of his or her immediate family, has no funding or commercial associations (e.g., consultancies, stock ownership, equity interest, patent/licensing arrangements, etc.) that might pose a conflict of interest in connection with the submitted article.

Published
2018
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