Bibliografías temáticas / Articular cartilage

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Literatura académica sobre el tema "Articular cartilage"

Autor: Grafiati
Publicado: 4 de junio de 2021
Última modificación: 9 de junio de 2025

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Artículos de revistas sobre el tema "Articular cartilage"

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Wardale, R. J., and V. C. Duance. "Quantification and immunolocalisation of porcine articular and growth plate cartilage collagens." Journal of Cell Science 105, no. 4 (August 1, 1993): 975–84. http://dx.doi.org/10.1242/jcs.105.4.975.

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The collagens of growth plate and articular cartilage from 5–6 month old commercial pigs were characterised. Growth plate cartilage was found to contain less total collagen than articular cartilage as a proportion of the dry weight. Collagen types I, II, VI, IX and XI are present in both growth plate and articular cartilage whereas type X is found exclusively in growth plate cartilage. Types III and V collagen could not be detected in either cartilage. Type I collagen makes up at least 10% of the collagenous component of both cartilages. There are significant differences in the ratios of the quantifiable collagen types between growth plate and articular cartilage. Collagen types I, II, and XI were less readily extracted from growth plate than from articular cartilage following pepsin treatment, although growth plate cartilage contains less of the mature collagen cross-links, hydroxylysyl-pyridinoline and lysyl-pyridinoline. Both cartilages contain significant amounts of the divalent reducible collagen cross-links, hydroxylysyl-ketonorleucine and dehydro-hydroxylysinonorleucine. Immunofluorescent localisation indicated that type I collagen is located predominantly at the surface of articular cartilage but is distributed throughout the matrix in growth plate. Types II and XI are located in the matrix of both cartilages whereas type IX is predominantly pericellular in the calcifying region of articular cartilage and the hypertrophic region of the growth plate. Collagen type VI is located primarily as a diffuse area at the articular surface.
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Wardale, R. J., and V. C. Duance. "Characterisation of articular and growth plate cartilage collagens in porcine osteochondrosis." Journal of Cell Science 107, no. 1 (January 1, 1994): 47–59. http://dx.doi.org/10.1242/jcs.107.1.47.

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The articular and growth plate cartilages of osteochondrotic pigs were examined and compared with those from clinically normal animals. Both types of osteochondrotic cartilage showed considerable localised thickening apparently due to a lack of ossification. Histological examination of cartilage lesions demonstrated a breakdown in the normal pattern of chondrocyte maturation. Articular cartilage lesions lacked mature clones of chondrocytes in the calcifying region. Growth plate cartilage showed an accumulation of disorganised hypertrophic chondrocytes rather than the well-defined columns seen in normal tissue. The overall percentages of collagen in osteochondrotic lesions from both articular and growth plate cartilage were significantly reduced compared with levels in unaffected cartilage. There were substantial increases in the proportion of type I collagen in lesions from both osteochondrotic articular and growth plate cartilages and a reduction in the proportion of type II collagen. Type X collagen was detected in osteochondrotic but not normal articular cartilage. The proportion of type X collagen was unchanged in osteochondrotic growth plate cartilage. The levels of the collagen cross-links, hydroxylysylpyridinoline, hydroxylysyl-ketonorleucine and dehydrohydroxylysinonorleucine were radically reduced in samples from osteochondrotic growth-plate cartilage lesions when compared with normal tissue. Less dramatic changes were observed in articular cartilage although there was a significant decrease in the level of hydroxylysylketonorleucine in osteochondrotic lesions. Immunofluorescence examination of osteochondrotic lesions showed a considerable disruption of the organisation of the collagenous components within both articular and growth-plate cartilages. Normal patterns of staining of types I and VI collagen seen at the articular surface in unaffected tissue were replaced by a disorganised, uneven stain in osteochondrotic articular cartilage lesions. Incomplete removal of cartilage at the ossification front of osteochondrotic growth plate was demonstrated by immunofluorescence staining of type IX collagen. Type X collagen was produced in the matrix of the calcifying region of osteochondrotic articular cartilage by small groups of hypertrophic chondrocytes, but was not detected in normal articular cartilage. The distribution of type X collagen was unchanged in osteochondrotic growth plate cartilage.
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Gong, Huchen, Yutao Men, Xiuping Yang, Xiaoming Li, and Chunqiu Zhang. "Experimental Study on Creep Characteristics of Microdefect Articular Cartilages in the Damaged Early Stage." Journal of Healthcare Engineering 2019 (November 13, 2019): 1–9. http://dx.doi.org/10.1155/2019/8526436.

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Traumatic joint injury is known to cause cartilage deterioration and osteoarthritis. In order to study the mechanical mechanism of damage evolution on articular cartilage, taking the fresh porcine articular cartilage as the experimental samples, the creep experiments of the intact cartilages and the cartilages with different depth defect were carried out by using the noncontact digital image correlation technology. And then, the creep constitutive equations of cartilages were established. The results showed that the creep curves of different layers changed exponentially and were not coincident for the cartilage sample. The defect affected the strain values of the creep curves. The creep behavior of cartilage was dependent on defect depth. The deeper the defect was, the larger the strain value was. The built three-parameter viscoelastic constitutive equation had a good correlation with the experimental results and could predict the creep performance of the articular cartilage. The creep values of the microdefective cartilage in the damaged early stage were different from the diseased articular cartilage. These findings pointed out that defect could accelerate the damage of cartilage. It was helpful to study the mechanical mechanism of damage evolution.
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Wansin, Yew, Mohd Juzaila Abd Latif Yew, Sharifah Majedah Idrus Alhabshi, Amaluddin Mahmud, and Mohammed Rafiq Abdul Kadri. "Correlation of Biomechanical Properties and Grayscale of Articular Cartilage using Low-Field Magnetic Resonance Imaging." International Journal of Engineering & Technology 7, no. 4.26 (November 30, 2018): 1–5. http://dx.doi.org/10.14419/ijet.v7i4.26.22128.

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Osteoarthritis is a joint disease that caused by the progression of degenerative articular cartilage tissue. The degeneration of the articular cartilage resulted in alteration of the biomechanical properties. Magnetic resonance imaging (MRI) has become the most potential imaging technique to assess the condition of the articular cartilage. However, most of the previous studies of articular cartilage were performed using high-field MRI units. Therefore, this study aimed to examine the correlation between the biomechanical properties of articular cartilage and the image grayscale using low-field MRI. Cartilage specimens extracted from bovine femoral head were scanned using 0.2 T MRI to obtain the cartilage image. The MRI image was characterized based on the intensity of grayscale. Indentation test was then conducted on the specimen to characterize the cartilage biphasic properties of elastic modulus and permeability. The cartilage grayscale values were moderately correlated with cartilage biphasic elastic modulus and higher correlation was observed with the permeability. These could indicate the potential application of low-field MRI to evaluate the biomechanical properties of articular cartilage.Â
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Chetina, E. V., and E. V. Chetina. "Inhibition of activity of collagen degradation in cartilage of patients with osteoarthrosis byactivation of glycolysis." Osteoporosis and Bone Diseases 14, no. 1 (April 15, 2011): 8–12. http://dx.doi.org/10.14341/osteo201118-12.

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Aim. To study the effect of glycolysis activators deferrioxamine (DFO), CoCl2, V(SO4)2 and mimosine on collagen cleavage activity by collagenase in osteoarthritic (OA) articular cartilage explants. Materials and methods. 32 OA articular cartilages obtained after arthroplasty were examined in the study. Cartilages were cultured in the presence of 10-50μM DFO, CoCl2, V(SO4)2 or mimosine. Collagen cleavage activity was measured by ELISA. Inhibition of protein or DNA synthesis in the presence of [3H]-labeled proline or thymidine, respectively, was used for evaluation of examined agent toxicity. Results. Glycolysis activators DFO, CoCl2, V(SO4)2 or mimosine were capable of inhibiting type II collagen cleavage activity in OA articular cartilage explants. The examined agents have shown no toxic effect in the concentrations used. Conclusion. Glycolysis activation in articular chondrocytes may offer a means of inhibiting articular cartilage destruction in OA patients.
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Li, Yefu, and Lin Xu. "Advances in understanding cartilage remodeling." F1000Research 4 (August 28, 2015): 642. http://dx.doi.org/10.12688/f1000research.6514.1.

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Cartilage remodeling is currently among the most popular topics in osteoarthritis research. Remodeling includes removal of the existing cartilage and replacement by neo-cartilage. As a loss of balance between removal and replacement of articular cartilage develops (particularly, the rate of removal surpasses the rate of replacement), joints will begin to degrade. In the last few years, significant progress in molecular understanding of the cartilage remodeling process has been made. In this brief review, we focus on the discussion of some current “controversial” observations in articular cartilage degeneration: (1) the biological effect of transforming growth factor-beta 1 on developing and mature articular cartilages, (2) the question of whether aggrecanase 1 (ADAMTS4) and aggrecanase 2 (ADAMTS5) are key enzymes in articular cartilage destruction, and (3) chondrocytes versus chondron in the development of osteoarthritis. It is hoped that continued discussion and investigation will follow to better clarify these topics. Clarification will be critical for those in search of novel therapeutic targets for the treatment of osteoarthritis.
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Hayes, Anthony J., John Whitelock, and James Melrose. "Regulation of FGF-2, FGF-18 and Transcription Factor Activity by Perlecan in the Maturational Development of Transitional Rudiment and Growth Plate Cartilages and in the Maintenance of Permanent Cartilage Homeostasis." International Journal of Molecular Sciences 23, no. 4 (February 9, 2022): 1934. http://dx.doi.org/10.3390/ijms23041934.

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The aim of this study was to highlight the roles of perlecan in the regulation of the development of the rudiment developmental cartilages and growth plate cartilages, and also to show how perlecan maintains permanent articular cartilage homeostasis. Cartilage rudiments are transient developmental templates containing chondroprogenitor cells that undergo proliferation, matrix deposition, and hypertrophic differentiation. Growth plate cartilage also undergoes similar changes leading to endochondral bone formation, whereas permanent cartilage is maintained as an articular structure and does not undergo maturational changes. Pericellular and extracellular perlecan-HS chains interact with growth factors, morphogens, structural matrix glycoproteins, proteases, and inhibitors to promote matrix stabilization and cellular proliferation, ECM remodelling, and tissue expansion. Perlecan has mechanotransductive roles in cartilage that modulate chondrocyte responses in weight-bearing environments. Nuclear perlecan may modulate chromatin structure and transcription factor access to DNA and gene regulation. Snail-1, a mesenchymal marker and transcription factor, signals through FGFR-3 to promote chondrogenesis and maintain Acan and type II collagen levels in articular cartilage, but prevents further tissue expansion. Pre-hypertrophic growth plate chondrocytes also express high Snail-1 levels, leading to cessation of Acan and CoI2A1 synthesis and appearance of type X collagen. Perlecan differentially regulates FGF-2 and FGF-18 to maintain articular cartilage homeostasis, rudiment and growth plate cartilage growth, and maturational changes including mineralization, contributing to skeletal growth.
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Sharifi, Ali Mohammad, Ali Moshiri, and Ahmad Oryan. "Articular cartilage." Current Orthopaedic Practice 27, no. 6 (2016): 644–65. http://dx.doi.org/10.1097/bco.0000000000000425.

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Hayes, Donald W., Randall L. Brower, and Kelly J. John. "Articular Cartilage." Clinics in Podiatric Medicine and Surgery 18, no. 1 (January 2001): 35–53. http://dx.doi.org/10.1016/s0891-8422(23)01166-7.

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McCarty, Eric C. "Articular Cartilage." Clinics in Sports Medicine 36, no. 3 (July 2017): i. http://dx.doi.org/10.1016/s0278-5919(17)30039-x.

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Tesis sobre el tema "Articular cartilage"

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Getgood, Alan Martin John. "Articular cartilage tissue engineering." Thesis, University of Cambridge, 2010. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.608764.

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Gratz, Kenneth R. "Biomechanics of articular cartilage defects." Diss., Connect to a 24 p. preview or request complete full text in PDF format. Access restricted to UC campuses, 2007. http://wwwlib.umi.com/cr/ucsd/fullcit?p3284116.

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Thesis (Ph. D.)--University of California, San Diego, 2007.<br>Title from first page of PDF file (viewed January 9, 2008). Available via ProQuest Digital Dissertations. Vita. Includes bibliographical references.
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Arkill, Kenton Paul. "Mass transport in articular cartilage." Thesis, University of Exeter, 2005. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.421565.

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Burgin, Leanne Victoria. "Impact loading of articular cartilage." Thesis, University of Aberdeen, 2003. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.288339.

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Impact loads have been implicated in the initiation of secondary osteoarthritis but in the absence of defined injury this is difficult to rest rigorously.  The response to controlled impacts of samples of cartilage and bone in isolation and together, may yield valuable insights into how tissue properties may influence degenerative changes associated with osteoarthritis. A rigid instrumented drop tower was constructed and interfaced to a LabVIEW software oscilloscope modified to capture and store data to disk.  Controlled impact loads were applied to cores of articular cartilage, both isolated and in situ on the underlying bone or bonded to substrates of different material properties.  Bovine tissue from the carpometacarpal joint and human cartilage from elderly femoral heads was used.  The response of the samples was investigated in terms of a dynamic stiffness, energy absorbed and coefficient of restitution.  In addition the quasistatic modulus was measured from compression tests in order to compare the values for the stiffness of cartilage and bone at different rates of stress and strain.  Composition analysis was then performed on human cartilage samples to investigate if there was any correlation between the biochemical constituents and mechanical factors. The dynamic stiffness of the cartilage samples was governed by peak stress and did not show a high sensitivity to strain rate.  Cartilage had good force attenuating properties in situ on bone and the substrates.  The greater volume of the stiffer underlying substrate dominated the response of the composite samples.  For the human cartilage samples the dynamic stiffness was most correlated to percentage collagen whereas the quasistatic modulus was most correlated with water content.  Overall the biochemical composition was a poor predictor of stiffness which indicates the importance of interactions between the matrix constituents in the tissue response to an applied load.
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Rowles, Christopher. "Visualisation of Articular Cartilage Microstructure." Thesis, Curtin University, 2016. http://hdl.handle.net/20.500.11937/52984.

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This thesis developed image processing techniques enabling the detection and segregation of biological three dimensional images into its component features based upon shape and relative size of the features detected. The work used articular cartilage images and separated fibrous components from the cells and background noise. Measurement of individual components and their recombination into a composite image are possible. Developed software was used to analyse the development of hyaline cartilage in developing sheep embryos.
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Girdler, N. M. "The role of mandibular condylar cartilage in articular cartilage repair." Thesis, King's College London (University of London), 1995. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.309110.

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Chan, Alex Dart Ming. "Neurogenic modulation of articular cartilage degeneration." Thesis, National Library of Canada = Bibliothèque nationale du Canada, 1999. http://www.collectionscanada.ca/obj/s4/f2/dsk2/ftp02/NQ41123.pdf.

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Covert, Rebeccah Jean. "Durability evaluation of articular cartilage prostheses." Diss., Georgia Institute of Technology, 2003. http://hdl.handle.net/1853/17596.

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Goldsmith, Andrew Alan John. "Biphasic modelling of synthetic articular cartilage." Thesis, University of Bath, 1996. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.321846.

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Ardill, Jennifer Maureen. "Optical measurement of articular cartilage roughness." Thesis, Queen's University Belfast, 1994. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.241325.

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Libros sobre el tema "Articular cartilage"

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Smith, David W., Bruce S. Gardiner, Lihai Zhang, and Alan J. Grodzinsky. Articular Cartilage Dynamics. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-13-1474-2.

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Cole, Brian J., and M. Mike Malek. Articular Cartilage Lesions. New York, NY: Springer New York, 2004. http://dx.doi.org/10.1007/978-0-387-21553-2.

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E, Kuettner Klaus, Schleyerbach Rudolf, and Hascall Vincent C, eds. Articular cartilage biochemistry. New York: Raven Press, 1986.

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Athanasiou, K. A. Articular cartilage tissue engineering. San Rafael, Calif. (1537 Fourth Street, San Rafael, CA 94901 USA): Morgan & Claypool Publishers, 2010.

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Gahunia, Harpal K., Allan E. Gross, Kenneth P. H. Pritzker, Paul S. Babyn, and Lucas Murnaghan, eds. Articular Cartilage of the Knee. New York, NY: Springer New York, 2020. http://dx.doi.org/10.1007/978-1-4939-7587-7.

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Argatov, Ivan, and Gennady Mishuris. Contact Mechanics of Articular Cartilage Layers. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-20083-5.

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Rodrìguez-Merchán, E. Carlos, ed. Articular Cartilage Defects of the Knee. Milano: Springer Milan, 2012. http://dx.doi.org/10.1007/978-88-470-2727-5.

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1964-, Hendrich Christian, Nöth Ulrich 1967-, and Eulert Jochen, eds. Cartilage surgery and future perspectives. Berlin: Springer, 2003.

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D, Brandt Kenneth, ed. Cartilage changes in osteoarthritis. Indianapolis, Ind: Indiana University School of Medicine, 1990.

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F, Stoltz J., ed. Mechanobiology: Cartilage and chondrocyte. Amsterdam: IOS Press, 2006.

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Capítulos de libros sobre el tema "Articular cartilage"

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Flik, Kyle R., Nikhil Verma, Brian J. Cole, and Bernard R. Bach. "Articular Cartilage." In Cartilage Repair Strategies, 1–12. Totowa, NJ: Humana Press, 2007. http://dx.doi.org/10.1007/978-1-59745-343-1_1.

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Pavelka, Margit, and Jürgen Roth. "Articular Cartilage." In Functional Ultrastructure, 294–95. Vienna: Springer Vienna, 2010. http://dx.doi.org/10.1007/978-3-211-99390-3_151.

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Smith, David W., Bruce S. Gardiner, Lihai Zhang, and Alan J. Grodzinsky. "Cartilage Tissue Homeostasis." In Articular Cartilage Dynamics, 65–243. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-1474-2_2.

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Smith, David W., Bruce S. Gardiner, Lihai Zhang, and Alan J. Grodzinsky. "Cartilage Tissue Dynamics." In Articular Cartilage Dynamics, 245–309. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-1474-2_3.

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Smith, David W., Bruce S. Gardiner, Lihai Zhang, and Alan J. Grodzinsky. "Introduction to Articular Cartilage." In Articular Cartilage Dynamics, 1–63. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-1474-2_1.

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Smith, David W., Bruce S. Gardiner, Lihai Zhang, and Alan J. Grodzinsky. "Lubrication, Friction, and Wear in Diarthrodial Joints." In Articular Cartilage Dynamics, 311–59. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-1474-2_4.

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Smith, David W., Bruce S. Gardiner, Lihai Zhang, and Alan J. Grodzinsky. "A Systems Approach to Articular Cartilage." In Articular Cartilage Dynamics, 361–428. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-1474-2_5.

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Smith, David W., Bruce S. Gardiner, Lihai Zhang, and Alan J. Grodzinsky. "Osmotic Pressure, Solid Stress, and the Diffuse Double Layer." In Articular Cartilage Dynamics, 429–67. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-1474-2_6.

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Smith, David W., Bruce S. Gardiner, Lihai Zhang, and Alan J. Grodzinsky. "Theory for Modeling Articular Cartilage." In Articular Cartilage Dynamics, 469–560. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-1474-2_7.

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Langworthy, Michael J., Fred R. T. Nelson, and Richard D. Coutts. "Basic Science." In Articular Cartilage Lesions, 3–12. New York, NY: Springer New York, 2004. http://dx.doi.org/10.1007/978-0-387-21553-2_1.

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Actas de conferencias sobre el tema "Articular cartilage"

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Iorizzo, Tyler, Maryem Mahhou, Santana Wright, James Childs, Ilya Yaroslavsky, Gregory Altshuler, and Anna Yaroslavsky. "Laser induced changes in articular cartilage." In Photonic Diagnosis, Monitoring, Prevention, and Treatment of Infections and Inflammatory Diseases 2025, edited by Tianhong Dai, Mei X. Wu, and Jürgen Popp, 27. SPIE, 2025. https://doi.org/10.1117/12.3047683.

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Goyal, Neeru, and Madhur Gupta. "A Study of Osteoarthritic Human Femoral Articular Cartilage Osteoarthritic Femoral Articular Cartilage." In Annual International Conference on Microscopic and Macroscopic Anatomy. Global Science & Technology Forum (GSTF), 2014. http://dx.doi.org/10.5176/2382-6096_cmma14.10.

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Zueger, Benno J., Beat Ott, P. M. Mainil-Varlet, Thomas Schaffner, Jean-Francois Clemence, Heinz P. Weber, and Martin Frenz. "Laser soldering of articular cartilage." In BiOS 2001 The International Symposium on Biomedical Optics, edited by R. Rox Anderson, Kenneth E. Bartels, Lawrence S. Bass, C. Gaelyn Garrett, Kenton W. Gregory, Abraham Katzir, Nikiforos Kollias, et al. SPIE, 2001. http://dx.doi.org/10.1117/12.427791.

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Yang, Xiao-Hong, Timon Cheng-Yi Liu, Shao-Jie Liu, Jian-Rong Tan, Yan Shen, and Pie-Hong Liang. "Photobiomodulation on Articular Cartilage Repair." In 2007 IEEE/ICME International Conference on Complex Medical Engineering. IEEE, 2007. http://dx.doi.org/10.1109/iccme.2007.4381919.

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Murakami, Teruo, Nobuo Sakai, Yoshinori Sawae, Itaru Ishikawa, Natsuko Hosoda, Emiko Suzuki, and Jun Honda. "Biomechanical Aspects of Natural Articular Cartilage and Regenerated Cartilage." In In Commemoration of the 1st Asian Biomaterials Congress. WORLD SCIENTIFIC, 2008. http://dx.doi.org/10.1142/9789812835758_0028.

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Tadepalli, Srinivas C., Kiran H. Shivanna, Vincent A. Magnotta, and Nicole M. Grosland. "Semi-Automated Patient Specific Hexahedral Mesh Generation of Articular Cartilage." In ASME 2009 Summer Bioengineering Conference. American Society of Mechanical Engineers, 2009. http://dx.doi.org/10.1115/sbc2009-205797.

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Articular cartilage is a critical component in the movement of one bone against another. It possesses unique chemical properties allowing it to serve as a bearing surface, capable of transferring loads from one bone to another while simultaneously allowing the load bearing surfaces to articulate with low friction. Patient-specific finite element (FE) models incorporating articular cartilage provide insight into articular joint mechanics [1, 2]. To date, the methods/tools available to create accurate FE mesh definitions of the articular cartilage are limited. Semi-automated morphing methods have been developed, but many intermediate steps have to be performed to get the final cartilage mesh definition [3]. Commercially available software [4] is capable of generating tetrahedral/shell/pyramid element based meshes of the cartilage from the underlying bony surface, but hexahedral meshes are preferred over tetrahedral meshes [5]. IA-FEMesh currently provides the ability to project a pre-defined set of elements a uniform distance [6]. This technique has been adopted in several models [1, 2]. Cartilage does not necessarily exist as such; rather the thickness of the cartilage is non-uniform and varies over the surface. Consequently an accurate representation of the articular cartilage is crucial for an accurate contact FE analysis. The goal of this study was to develop an algorithm that will aid in the generation of anatomically accurate cartilage FE mesh definitions in a reliable manner based on patient-specific image data.
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Melas, I. N., A. D. Chairakaki, A. Mitsos, Z. Dailiana, C. G. Provatidis, and L. G. Alexopoulos. "Modeling signaling pathways in articular cartilage." In 2011 33rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society. IEEE, 2011. http://dx.doi.org/10.1109/iembs.2011.6090630.

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Ardill, Jennifer M., N. J. Barton, W. G. Kernohan, and R. A. B. Mollan. "Quantitative assessment of articular cartilage roughness." In OE/LASE'93: Optics, Electro-Optics, & Laser Applications in Science& Engineering, edited by Halina Podbielska. SPIE, 1993. http://dx.doi.org/10.1117/12.155722.

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Kumar, Rajesh, Catharina Davies, Jon Drogset, and Magnus Lilledahl. "Multiphoton microscopy of osteoarthritic articular cartilage." In Novel Techniques in Microscopy. Washington, D.C.: OSA, 2017. http://dx.doi.org/10.1364/ntm.2017.nw4c.4.

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10

Rennie, A. C., and W. G. Sawyer. "Tribological Investigation of Porcine Articular Cartilage." In World Tribology Congress III. ASMEDC, 2005. http://dx.doi.org/10.1115/wtc2005-64382.

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This poster examines the tribological properties and effective elastic modulus of porcine articular cartilage plugs. Two methods of obtaining an effective elastic modulus are explored for the different initial material conditions during the indentation loading and unloading. The average values of coefficient of friction varied from 0.04–0.14, but ended with a steady-state average of 0.06. It was validated that increasing pressure during sliding produces an increase in friction coefficient. From a contact model fit to the loading region of the indentation curve, effective elastic modulus had an average value of 300 MPa, which agrees with existing literature. From an examination of the linear portion of the unloading region of the indentation curve, the effective elastic modulus was an average of 8.9 MPa. A preliminary explanation for this is that before loading, a bulk material is present, but pressure effects could evacuate some of the interstitial fluid, leaving in the unloading curve an effective matrix without fluid.
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Informes sobre el tema "Articular cartilage"

1

Huard, Johnny. Articular Cartilage Repair Through Muscle Cell-Based Tissue Engineering. Fort Belvoir, VA: Defense Technical Information Center, March 2011. http://dx.doi.org/10.21236/ada552048.

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de Sousa, Eduardo, Renata Matsui, Leonardo Boldrini, Leandra Baptista, and José Mauro Granjeiro. Mesenchymal stem cells for the treatment of articular cartilage defects of the knee: an overview of systematic reviews. INPLASY - International Platform of Registered Systematic Review and Meta-analysis Protocols, December 2022. http://dx.doi.org/10.37766/inplasy2022.12.0114.

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Review question / Objective: Population: adults (aged between 18 and 50 years) with traumatic knee lesions who underwent treatment with mesenchymal stem cells; Intervention: defined by the treatment with mesenchymal stem cells; The comparison group: treatment with autologous chondrocytes or microfracture treatments; Primary outcome: formation of cartilage neo tissue in the defect area, determined by magnetic resonance imaging (MRI) or by direct visualization in second-look knee arthroscopy.; Secondary outcomes: based on clinical scores such as visual analog scale (VAS) for pain, Western Ontario and McMaster universities score (WOMAC), knee society score (KSS), Tegner and Lysholm.
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Guede-Rojas, Francisco, Alexis Benavides-Villanueva, Sergio Salgado-González, Cristhian Mendoza, Gonzalo Arias-Álvarez, and Claudio Carvajal-Parodi. Effect of strength training on knee proprioception in patients with knee osteoarthritis. A systematic review and meta-analysis protocol. INPLASY - International Platform of Registered Systematic Review and Meta-analysis Protocols, May 2023. http://dx.doi.org/10.37766/inplasy2023.5.0102.

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Review question / Objective: To analyze the effect of strength training (ST) on knee proprioception in patients with knee osteoarthritis (KOA). Condition being studied: KOA is a chronic and degenerative joint disease characterized by articular cartilage loss, marginal bone hypertrophy, and inflammatory involvement of periarticular tissue of the knee. Symptoms of KOA are pain, stiffness, reduced range of motion, and muscle weakness, although proprioception may also be affected, contributing to the associated functional limitation.
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Cao, Siyang, Yihao Wei, Huihui Xu, Jian Weng, Tiantian Qi, Fei Yu, Su Liu, Ao Xiong, Peng Liu, and Hui Zeng. Crosstalk between Ferroptosis and Chondrocytes in Osteoarthritis: A Systematic Review of in-vivo and in-vitro Studies. INPLASY - International Platform of Registered Systematic Review and Meta-analysis Protocols, March 2023. http://dx.doi.org/10.37766/inplasy2023.3.0044.

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Review question / Objective: For the sake of better apprehending the nexus between ferroptosis and chondrocytes in osteoarthritis (OA), proffering novel insights and opening-up new orientation for in-depth research in both pre-clinical and clinical settings, it is warranted to initiate one rigorous and robust systematic review (SR) based upon up-to-date in-vivo and in-vitro research advances on this topic. To the best our knowledge, no SRs concerning ferroptosis and chondrocytes in OA have been published thus far. Condition being studied: Osteoarthritis (OA) is the most common form of arthritis, which menaces 7% of the human population globally. With the aged tendency of population and higher rates of obesity, the incidence of OA is anticipated to proliferate, which will entail a mounting impact and major challenges for global health care and each country’s public health systems unavoidably. In virtue of the onset of OA is mighty knotty, its etiology and underlying molecular mechanisms have not been expressly expounded. However, the salient role that cartilage degeneration acts in the progression of OA has been widely acknowledged. Chondrocytes are consequential for the safeguard of cartilage homeostasis and the functional integrity of the articular cartilage. Once the homeostatic equilibrium of the extracellular matrix (ECM) synthesis and degradation is smashed, OA comes up.
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