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Mechanical Compression (mechanical + compression)

Distribution by Scientific Domains

Life Sciences	57%
Medical Sciences	42%

Selected Abstracts

Modulation of vertebral and tibial growth by compression loading: Diurnal versus full-time loading

JOURNAL OF ORTHOPAEDIC RESEARCH, Issue 1 2005
Ian A. Stokes
Abstract Purpose: This study was designed to determine whether the amount of endochondral growth response to mechanical compression and the underlying growth mechanism differed with night-time or day-time loading, relative to full-time loading. Methods: Mechanical compression (nominally 0.1 MPa stress) was applied across tibial and tail vertebral growth plates of growing Sprague,Dawley rats. Four groups of animals (five per group) were used: 24/24 h (full-time loading); 12/24 h (day-loading); 12/24 h (night-loading); and 0/24 h (sham instrumented). Contralateral tibiae and adjacent vertebrae served as within-animal controls. The animals were euthanized after eight days. Growth plates were processed for quantitative histology to measure 24-h growth, total and BrdU-positive proliferative zone chondrocyte counts, and hypertrophic chondrocytic enlargement in the growth direction. Results: Growth as a percentage of within-animal control averaged 82% (full-time); 93% (day-loading); 90% (night-loading); 100% (sham) for vertebrae. For proximal tibiae it averaged 70% (full-time); 84% (day-loading); 86% (night-loading); 89% (sham). Reduced amount of hypertrophic chondrocytic enlargement explained about half of this effect in full-time loaded growth plates, but was not significantly altered in half-time loaded growth plates. The remaining variation in growth was apparently explained by reduced total numbers of proliferative zone chondrocytes. These findings indicate that sustained compression loading suppressed growth more than intermittent loading at both anatomical locations. © 2004 Orthopaedic Research Society. Published by Elsevier Ltd. All rights reserved. [source]

Iliac vein compression syndrome: An underdiagnosed cause of lower extremity deep venous thrombosis,

JOURNAL OF HOSPITAL MEDICINE, Issue 7 2010
Ami Naik BS
Abstract Iliac vein compression syndrome (CS) is a rare cause of deep venous thrombosis. It is caused by an anatomic anomaly in which the right common iliac artery overlies the left common iliac vein causing mechanical compression. Subsequent endothelial changes within the vessels have the potential to spur thrombus formation. Aggressive diagnostic and therapeutic interventions must be implemented upon suspicion to avoid long-term complications. We report on a 19 year old male who presented with ICS. We discuss the clinical presentation, diagnosis, and current treatment options. Journal of Hospital Medicine 2010. © 2010 Society of Hospital Medicine. [source]

Renaut bodies in nerves of the trunk of the African elephant, Loxodonta africana

JOURNAL OF MORPHOLOGY, Issue 5 2007
Kirsti Witter
Abstract Renaut bodies are loosely textured, cell-sparse structures in the subperineurial space of peripheral nerves, frequently found at sites of nerve entrapment. The trunk of the elephant is a mobile, richly innervated organ, which serves for food gathering, object grasping and as a tactile organ. These functions of the trunk lead to distortion and mechanical compression of its nerves, which can therefore be expected to contain numerous Renaut bodies. Samples of the trunk wall of an adult African elephant (Loxodonta africana) were examined histologically using conventional staining methods, immunohistochemistry, and lectin histochemistry. Architecture of nerve plexuses and occurrence of Renaut bodies in the elephant trunk were compared with those in tissues surrounding the nasal vestibule of the pig. Prominent nerve plexuses were found in all layers of the elephant trunk. Almost all (81%) nerve profiles contained Renaut bodies, a basophilic, discrete subperineurial layer resembling cushions around the nerve core. In contrast, Renaut bodies were seen in only 15% of nerve profiles in the porcine nasal vestibule. Within Renaut bodies, fusiform fibroblasts and round, ruff-like cells were placed into a matrix of acidic glycosaminoglycans with delicate collagen and very few reticular fibers. The turgor of this matrix is thought to protect nerves against compression and shearing strain. Renaut bodies are readily stained with alcian blue (pH 2.5) favorably in combination with immunohistochemical markers of nerve fibers. They should be regarded as a physiological response to repeated mechanical insults and are distinct from pathological alterations. alterations. J. Morphol., 2007. © 2007 Wiley-Liss, Inc. [source]

Morphological and molecular changes in denture-supporting tissues under persistent mechanical stress in rats

JOURNAL OF ORAL REHABILITATION, Issue 12 2008
M. TSURUOKA
Summary, The purpose of this study was to determine the effects of mechanical compression on the palatal mucosa using an experimental palatal base. The palatal base was either pressed onto (stress group) or not pressed onto (fit group) rat palatal mucosa. Blood flow was measured and the animals were sacrificed 6,72 h later for analysis. The expression of heat shock protein 70 (HSP70), vascular endothelial growth factor (VEGF) and proliferation cell nuclear antigen (PCNA) was characterized by immunohistochemical staining. For morphometric analysis, connective tissues were divided into bone side and epithelial side tissues. The ratio of PCNA-positive cells (PCNA score) was calculated, and the expressions of mRNA encoding HSP70 and VEGF was evaluated. Whereas blood flow in the stress group showed ischaemia, none was found in the fit group. Proliferation cell nuclear antigen scores on the bone side were higher than on the epithelial side in the stress group (P < 0·05). Heat shock protein 70- and VEGF-positive cells were observed under compression conditions, particularly in the periosteum. In the stress group, the expressions of mRNA encoding HSP70 and VEGF were highest at 12 h (P < 0·05). These results suggest that mechanical compression of the palatal plate induces ischaemia, and that cells in the underlying denture-supporting tissue, which includes the periosteum, synthesize HSP70 and VEGF to maintain homeostasis under these conditions. [source]

Intervertebral disc cell response to dynamic compression is age and frequency dependent,

JOURNAL OF ORTHOPAEDIC RESEARCH, Issue 6 2009
Casey L. Korecki
Abstract The maintenance of the intervertebral disc extracellular matrix is regulated by mechanical loading, nutrition, and the accumulation of matrix proteins and cytokines that are affected by both aging and degeneration. Evidence suggests that cellular aging may lead to alterations in the quantity and quality of extracellular matrix produced. The aims of this study were to examine the role of loading and maturation (a subset of aging), and the interaction between these two factors in intervertebral disc cell gene expression and biosynthesis in a controlled 3D culture environment. Cells were isolated from young (4,6 months) and mature (18,24 months) bovine caudal annulus fibrosus and nucleus pulposus tissue. Isolated cells were seeded into alginate and dynamically compressed for 7 days at either 0.1, 1, or 3 Hz or maintained as a free-swelling control. After 7 days, DNA and sulfated glycosaminoglycan contents were analyzed along with real time, quantitative reverse transcription-polymerase chain reaction analysis for collagen types I and II, aggrecan, and matrix metalloproteinase-3 gene expression. Results suggest that maturation plays an important role in intervertebral disc homeostasis and influences the cell response to mechanical loading. While isolated intervertebral disc cells responded to mechanical compression in 3D culture, the effect of loading frequency was minimal. Altered cellular phenotype and biosynthesis rates appear to be an attribute of the cell maturation process, potentially independent of changes in cellular microenvironment associated with lost nutrition and disc degeneration. Mature cells may have a decreased capacity to create or retain extracellular matrix components in response to mechanical loading compared to young cells. © 2008 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 27: 800,806, 2009 [source]

Localization and changes of intraneural inflammatory cytokines and inducible-nitric oxide induced by mechanical compression

JOURNAL OF ORTHOPAEDIC RESEARCH, Issue 4 2005
Shigeru Kobayashi
Abstract Study design: Investigation of intraneural inflammation induced by mechanical compression. Objectives: In order to investigate the mechanism of neuropathy, this study used a median nerve compression model in dogs. Immunohistochemistry was used to examine the localization and changes of inflammatory cytokines and nitric oxide (NO). Summary of background data: The manifestation of pain at sites of inflammation has a close relationship with the release of mediators from macrophages such as interleulin-1 (IL-1) and tumor necrosis factor-, (TNF-,), as well as with NO. However, the mediators involved in inflammation of nerve due to mechanical compression remain almost unknown. Methods: In this study, the median nerve of dogs was compressed with a clip for three weeks to observe the changes caused by compression. Immunohistochemistry was done by the avidin-biotin-peroxidase complex method to observe the changes of T cells (CD45) and macrophages (Mac-1) after compression. Antibodies against IL-,, TNF-,, and inducible nitric oxide synthesis (i-NOS) were used to examine the localization and changes of these mediators caused by nerve compression. Results: In control animals, resident T cells were detected, but there were no macrophages. IL-1, was positive in the Schwann cells and vascular endothelial cells. However, no cells showed TNF-, or i-NOS positively. After nerve compression, numerous T cells and macrophages appeared among the demyelinized nerve fibers. The macrophages were positive for IL-1,, TNF-, and i-NOS. Conclusion: Inflammatory cytokines and NO may be involved in intraneural inflammatory changes arising from mechanical compression. Such mediators may be of importance in the manifestation of neuropathy. © 2005 Orthopaedic Research Society. Published by Elsevier Ltd. All rights reserved. [source]

Modulation of vertebral and tibial growth by compression loading: Diurnal versus full-time loading

Pathology of lumbar nerve root compression Part 1: Intraradicular inflammatory changes induced by mechanical compression

JOURNAL OF ORTHOPAEDIC RESEARCH, Issue 1 2004
Shigeru Kobayashi
Study design: This study is to investigate the intraradicular inflammation induced by mechanical compression using in vivo model. Objectives: The relationship between the intraradicular edema and nerve fiber degeneration induced by mechanical compression was determined in the nerve root. Summary of background data: Recently some studies reported that mechanical compression increased microvascular permeability of the endoneurial capillaries and resulted in an intraradicular inflammation. These changes may be an important factor of the pathogenesis of radiculopathy. However, the natural courses of the intraradicular inflammation after mechanical compression are still poorly understood. Methods: In dogs, laminectomy was performed at L7 and the seventh nerve root was exposed to compression at 7.5 gram force (gf) clipping power. The animals were evaluated at 1 and 3 weeks after clipping. After the appropriate period of nerve root compression, Evans blue albumin (EBA) was injected intravenously. The nerve root sections were divided into two groups. The sections were used to investigate the status of the blood,nerve barrier function under the fluorescence microscope. The other sections were used for light and transmission electron microscopic study. Results: After 1 and 3 weeks, intraradicular edema was observed not only at the site of compression but also in the peripheral zone of a compressed anterior root and in the central zone of a compressed posterior root. The evidence of active Wallerian degeneration was also seen in the area of intraradicular edema. In addition, the nerve roots showing Wallerian degeneration were infiltrated by inflammatory cells, such as macrophages and mast cells. Conclusions: Inflammatory reaction, such as Wallerian degeneration, breakdown of blood,nerve barrier and appearance of macrophage, may be deeply involved in radiculitis arising from mechanical compression, and these factors seem to be important in the manifestation of radiculopathy. © 2003 Orthopaedic Research Society. Published by Elsevier Ltd. All rights reserved. [source]

SURGICAL TREATMENT OF GLOSSOPHARYNGEAL NEURALGIA: A 10 YEAR EXPERIENCE

JOURNAL OF THE PERIPHERAL NERVOUS SYSTEM, Issue 1 2002
F. Rychlicki
First described by Weisenburg in 1910, glossopharyngeal neuralgia is paroxysmal, lighting, excruciating pain referred to the posterior lingual region, tonsillar pillar, throat, external auditory canal and pinna. It is much less frequently encountered than trigeminal neuralgia with a reported relative frequency of the order of 1%. It is often secondary to neoplastic processes of the oropharyngeal region but can also be caused by mechanical compression of abnormal vessels on the nerve root. Less frequently it is of essential or idiophatic origin. Between 1990 and 2000, operations were performed at our Institute on 3 patients, all women ranging in age from 61 to 80 years, with glossopharyngeal neuralgia. All the patients had been taking caramazepine with only temporary initial improvement and in 2 cases parenteral feeding had been necessary before admission. The first 2 patients were submitted to percutaneous thermocoagulation rhizotomy of the inferior petrous ganglion of Andersch at the jugular foramen, the third to open procedure consisting in vascular decompression of the ninth nerve in posterior fossa. The follow-up ranges from 2 to 10 years. The results were excellent or very good in all cases at the time of evaluation. The authors emphasize the role of surgical therapy in glossopharyngeal neuralgia when medical therapy fails. [source]

Effects of mechanical loading on collagen propeptides processing in cartilage repair

JOURNAL OF TISSUE ENGINEERING AND REGENERATIVE MEDICINE, Issue 1 2010
Rosmarie Hardmeier
Abstract Injured articular cartilage has poor reparative capabilities and if left untreated may develop into osteoarthritis. Unsatisfactory results with conventional treatment methods have brought as an alternative treatment the development of matrix autologous chondrocyte transplants (MACTs). Recent evidence proposes that the maintenance of the original phenotype by isolated chondrocytes grown in a scaffold transplant is linked to mechanical compression, because macromolecules, particularly collagen, of the extracellular matrix have the ability to ,self-assemble'. In load-bearing tissues, collagen is abundantly present and mechanical properties depend on the collagen fibre architecture. Study of the active changes in collagen architecture is the focus of diverse fields of research, including developmental biology, biomechanics and tissue engineering. In this review, the structural model of collagen assembly is presented in order to understand how scaffold geometry plays a critical role in collagen propeptide processing and chondrocyte development. When physical forces are applied to different cell-based scaffolds, the resulting specific twist of the scaffolds might be accompanied by changes in the fibril pattern synthesis of the new collagen. The alteration in the scaffolds due to mechanical stress is associated with cellular signalling communication and the preservation of N-terminus procollagen moieties, which would regulate both the collagen synthesis and the diameter of the fibre. The structural difference would also affect actin stabilization, cytoskeleton remodelling and proteoglycan assembly. These effects seemed to be dependent on the magnitude and duration of the physical stress. This review will contribute to the understanding of mechanisms for collagen assembly in both a natural and an artificial environment. Copyright © 2009 John Wiley & Sons, Ltd. [source]

Rho kinase,dependent activation of SOX9 in chondrocytes

ARTHRITIS & RHEUMATISM, Issue 1 2010
Dominik R. Haudenschild
Objective The transcription factor SOX9 directly regulates the expression of the major proteoglycans and collagens comprising the cartilage extracellular matrix. The DNA binding activity and cellular localization of SOX9 is controlled through posttranslational modifications, including phosphorylation. The activity of Rho kinase (ROCK) has profound effects on the actin cytoskeleton, and these effects are instrumental in determining the phenotype and differentiation of chondrocytes. However, the mechanisms linking ROCK to altered chondrocyte gene expression remain unknown. The purpose of the present study was to test for a direct interaction between ROCK and SOX9. Methods Human SW1353 chondrosarcoma cells were transfected with constructs coding for RhoA, ROCK, Lim kinase, and SOX9. The interaction between ROCK and SOX9 was tested on purified proteins, and was verified within a cellular context using induced overexpression and activation of the Rho pathway. The effects of SOX9 transcriptional activation were quantified with a luciferase reporter plasmid containing SOX9 binding sites from the COL2A1 enhancer element. Results SOX9 was found to contain a consensus phosphorylation site for ROCK. In vitro, ROCK directly phosphorylated SOX9 at Ser181, and the overexpression of ROCK or the activation of the RhoA pathway in SW1353 chondrosarcoma cells increased SOX9Ser181 phosphorylation. ROCK caused a dose-dependent increase in the transcription of a SOX9-luciferase reporter construct, and increased phosphorylation and nuclear accumulation of SOX9 protein in response to transforming growth factor , treatment and mechanical compression. Conclusion These results demonstrate a new interaction that directly links ROCK to increased cartilage matrix production via activation of SOX9 in response to mechanical and growth factor stimulation. [source]

A sodium dodecyl sulfate,polyacrylamide gel electrophoresis,liquid chromatography tandem mass spectrometry analysis of bovine cartilage tissue response to mechanical compression injury and the inflammatory cytokines tumor necrosis factor , and interleukin-1,

ARTHRITIS & RHEUMATISM, Issue 2 2008
Anna L. Stevens
Objective To compare the response of chondrocytes and cartilage matrix to injurious mechanical compression and treatment with interleukin-1, (IL-1,) and tumor necrosis factor , (TNF,), by characterizing proteins lost to the medium from cartilage explant culture. Methods Cartilage explants from young bovine stifle joints were treated with 10 ng/ml of IL-1, or 100 ng/ml of TNF, or were subjected to uniaxial, radially-unconfined injurious compression (50% strain; 100%/second strain rate) and were then cultured for 5 days. Pooled media were subjected to gel-based separation (sodium dodecyl sulfate,polyacrylamide gel electrophoresis) and analysis by liquid chromatography tandem mass spectrometry, and the data were analyzed by Spectrum Mill proteomics software, focusing on protein identification, expression levels, and matrix protein proteolysis. Results More than 250 proteins were detected, including extracellular matrix (ECM) structural proteins, pericellular matrix proteins important in cell,cell interactions, and novel cartilage proteins CD109, platelet-derived growth factor receptor,like, angiopoietin-like 7, and adipocyte enhancer binding protein 1. IL-1, and TNF, caused increased release of chitinase 3,like protein 1 (CHI3L1), CHI3L2, complement factor B, matrix metalloproteinase 3, ECM-1, haptoglobin, serum amyloid A3, and clusterin. Injurious compression caused the release of intracellular proteins, including Grp58, Grp78, ,4-actinin, pyruvate kinase, and vimentin. Injurious compression also caused increased release and evidence of proteolysis of type VI collagen subunits, cartilage oligomeric matrix protein, and fibronectin. Conclusion Overload compression injury caused a loss of cartilage integrity, including matrix damage and cell membrane disruption, which likely occurred through strain-induced mechanical disruption of cells and matrix. IL-1, and TNF, caused the release of proteins associated with an innate immune and stress response by the chondrocytes, which may play a role in host defense against pathogens or may protect cells against stress-induced damage. [source]