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1	The bioeffect of ultrasound on human chondrocytes Cheng, Yi-Li 29 July 2005 (has links) Animal and clinical studies have shown an acceleration of bone healing by the application of pulsed low-intensity ultrasound (PLIUS). Several studies have reported that pulsed low-intensity ultrasound increase the synthesis of proteoglycan and type II collagen of cultured animal chondrocytes. The objectives of this study were to exam the bioeffect of pulsed low-intensity ultrasound on in vitro cultured human chondrocytes. Human chondrocytes were isolated from the amputated polydactyly digit of six different 1 to 10 years patients and cultured in agarose suspension for 3 days before treatment. PLIUS with intensities of 3.6, 18, 48, 72 and 98 mW/cm2was respectively applied to human chondrocytes for a single 10-min per day treatment. A control group was treated without PLIUS. The results demonstrated that PLIUS-treated human chondrocytes increased the proteoglycan synthesis compared with the control in a time-dependent manner. It is shown that the effect of 48 mW/cm2 is the most potent among a variety of PLIUS intensities tested determined by ELISA method. PLIUS at 48 mW/cm2 also increased type II collagen synthesis by up to 48.5+8.0% of the control determined by western blotting analysis. However, PLIUS has no significant influence on the cell proliferation of human chondrocytes compared with the control. It revealed that the PLIUS can enhance extracellular matrix synthesis. The response to PLIUS of chondrocytes harvested from 1 year old donor was significantly better than that of chondrocytes of 10 years old patient. These observations may lead to a better understanding of the bioeffect of PLIUS on in vitro cultured human chondrovytes. proteoglycan type II collagen ultrasound human chondrocytes
2	Mechanism of cartilage destruction in osteoarthritis Ishiguro, Naoki, Kojima, Toshihisa, Poole, A.Robin 11 1900 (has links) No description available. osteoarthritis matrix metalloproteinase aggrecan type II collagen aggrecanase
3	Estudo das mutações no gene COL2A1 em uma coorte de pacientes com displasias esqueléticas do grupo colagenopatia tipo II segundo critérios clínico-radiológicos / Study of mutations in the COL2A1 gene in a cohort of patients with skeletal dysplasias of type 2 collagenopathy group according to clinical and radiological criteria Silveira, Karina da Costa, 1989- 24 August 2018 (has links) Orientadores: Denise Pontes Cavalcanti, Luciana Cardoso Bonadia / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-24T20:03:03Z (GMT). No. of bitstreams: 1 Silveira_KarinadaCosta_M.pdf: 2998560 bytes, checksum: 286fe3d0377e879226faf2cb88d92569 (MD5) Previous issue date: 2014 / Resumo: As displasias esqueléticas ou osteocondrodisplasias são doenças genéticas que afetam o crescimento e o desenvolvimento do tecido ósseo e cartilaginoso produzindo, em geral, baixa estatura. Mutações em heterozigose no gene COL2A1 são responsáveis por uma série de displasias esqueléticas conhecidas como colagenopatias do tipo II que geralmente apresentam um padrão espondiloepifisário típico. Apesar das mutações no COL2A1 serem, em geral, "privadas", o estudo molecular desse gene em pacientes com fenótipos sugestivos de colagenopatia do tipo II pode contribuir seja para um melhor entendimento das colagenopatias do tipo II seja para refinar, quando possível, a correlação genótipo-fenótipo. O objetivo desse estudo foi investigar o gene COL2A1 numa coorte de pacientes com fenótipo de colagenopatia do tipo II de modo a melhorar o conhecimento sobre essas colagenopatias. Foram estudados 33 pacientes com fenótipo de colagenopatia do tipo II. A análise molecular foi feita por sequenciamento automático bidirecional direto do gene COL2A1, começando pelos domínios relacionados a cada fenótipo seguido de sequenciamento completo das regiões codificantes do gene quando as primeiras foram negativas. Foram identificadas alterações potencialmente deletérias em heterozigose em 23 dos 33 pacientes (69,7%): 18 alterações do tipo missense (11 inéditas, 7 descritas), 4 alterações que alteram sítio de splice (2 inéditas, 2 descritas) e uma deleção inédita. Das mutações do tipo missense encontradas, duas foram recorrentes em 5 pacientes: p.G594E e p.R989C. Ambas as mutações recorrentes foram associadas a fenótipos graves: a p.R989C foi observada em displasia espondiloepifisária congênita (SEDC) grave enquanto que a p.G594E foi associadaa 2 recém-nascidos com fenótipo de SEDC-letal. Para todas as mutações novas, a análise in silico, estudo em controles e/ou dos pais confirmaram a patogenicidade de todas elas. Concluindo, os resultados deste estudo permitiram a identificação de 14 mutações novas no gene COL2A1 e um melhor refinamento da correlação genótipo-fenótipo / Abstract: Skeletal dysplasias are genetic disorders that affect the growth and development of the bone and cartilage tissues producing, in general, short stature. Heterozygous mutations in the COL2A1 gene are responsible for a number of skeletal dysplasias that usually exhibit a pattern spondyloepiphyseal and are called type II collagenopathies. Although the mutations in COL2A1 are usually privates, molecular studies of this gene in patients with suggestive phenotypes can contribute to a better understanding of the type II collagenopathies. The aim of this study was to sequence the COL2A1 in a cohort of patients with type II collagenopathy phenotypes in order to refine the knowledge regarding the genotype-phenotype correlation. Thus, 33 patients with suggestive phenotype were studied. The molecular analysis was performed by automated Sanger bidirectional sequencing of the COL2A1 gene, starting with the domains related to each phenotype followed by whole sequencing of the gene coding regions when the first ones were negative. Potentially deleterious changes in heterozygosity were identified in 23 of 33 patients (69.7 %): 18 missense changes (11 undescribed), 4 changes that modify the splice site (2 undescribed) and a new deletion. The pathogenicity of the undescribed changes were confirmed by in silico analysis, study of control individuals and/or of the respective parents. Among the found missense mutations, two were recurrent and associated with severe phenotypes. These mutations, p.G594E and p.R989C, were found in five patients. The R989C change was observed in three children presenting a phenotype of spondyloepiphyseal dysplasia congenita (SEDC), which follow up showed a pattern of severe SEDC featured by severe disproportioned short stature with coxa vara and kyphoscoliosis. The G594E change was associated with two newborns presenting also a SEDC phenotype, however with lethal evolution. In conclusion, the results of this study allowed the identification of 14 new mutations in COL2A1 gene and a better refinement of the genotype-phenotype correlation / Mestrado / Ciencias Biomedicas / Mestra em Ciências Médicas Osteocondrodisplasias Colágeno tipo II Osteochondrodysplasias Type II collagen
4	Evaluation of Chitosan as a Cell Scaffolding Material for Cartilage Tissue Engineering Nettles, Dana Lynn 14 December 2001 (has links) Current articular cartilage tissue engineering endeavors, using synthetic polymers as scaffolds, have been somewhat successful. However, the use of these materials has not yielded a satisfactory, functional replacement for articular cartilage. Therefore, this project focuses on an alternative to these materials, chitosan, which is a naturally occurring biopolymer. The first project objective was to fabricate and analyze bulk, porous chitosan scaffolds, based on total porosity, average pore diameter, mechanical integrity, and degradation susceptibility. Secondly, scaffolds were evaluated in terms of their ability to support neochondrogenesis, including assessments of cell attachment and viability, cell morphology, and the biosynthesis of proteoglycan and type-II collagen-rich extracellular matrix. Results indicated that chitosan scaffolds possessing an interconnecting, porous structure could be easily created through a simple freezing and lyophilization process, and these scaffolds did support neochondrogenesis. Results suggest chitosan may be a useful alternative to synthetic polymers for use in cartilage tissue engineering applications. Chondrocyte Biomaterial Biocompatible Polymers Proteoglycan Type-II Collagen
5	Biomarkers of Knee Joint Healing in Adolescents with Anterior Cruciate Ligament Injuries Ek Orloff, Lisa 25 February 2022 (has links) Objective: Anterior cruciate ligament (ACL) injuries are increasing in adolescents and increase the risk for early-onset knee osteoarthritis (OA). Biomarkers can be a non-invasive measure to assess physiological properties following knee injury or trauma. The objective of this thesis was to i) perform a systematic review to determine the most studied biomarkers of knee healing following ACL reconstruction (ACLR), and age of these patients, and ii) explore the feasibility of measuring these biomarkers in adolescents with ACL injuries. Design: Studies were included if i) participants underwent ACLR, and ii) at least one biomarker of healing was measured. Participant age, sample(s) collected, and biomarker(s) studied were recorded. Interleukin-6 (IL-6), c-terminal crosslinking telopeptide of type II collagen (CTX-II) and procollagen type II collagen propeptide (PIICP) were then measured using ELISA in adolescents prior to ACLR in urine (u) and synovial fluid (sf). Spearman’s Rho (rs) coefficients were calculated to determine the association between uCTX-II/sfCTX-II, and uIL-6/sfIL-6. A ratio of PIICP: CTX-II was calculated to represent the ratio of cartilage synthesis to degradation. Results: The review produced six studies evaluating healing following ACLR. IL-6 and CTX-II were the most studied (3/6 studies), and only one study included adolescents (age 19.6±4.5). Due to multiple undetectable biomarker levels, we could only report rs for uCTX-II/sfCTX-II (rs = -.200, p-value = .800, n=4). We also reported a ratio for sfPIICP: sfCTX-II (23.06 ±19.23). Conclusion: Exploring biomarkers in adolescents was motivated by their unique physiology due to puberty, and this was the first study to do so. The findings from this pilot study indicate that further analysis is required to determine optimal sample preparation. This will allow for reliable results while studying the feasibility of these biomarkers during ACLR recovery. This insight can ensure more informed decision making by clinicians clearing patients for return-to-activity. Adolescents Anterior Cruciate Ligament (ACL) Articular Cartilage Degradation Interleukin-6 (IL-6)
6	Effect of Fluid Flow on Tissue-Engineered Cartilage in a Novel Bioreactor Gemmiti, Christopher V. 10 November 2006 (has links) Due to its relative avascularity, low cellularity and lack of an undifferentiated cell reservoir, articular cartilage has a limited capacity for self-repair when damaged through trauma or disease. Articular cartilage impairment and the resultant reduced joint function affects millions of people at a substantial cost. In the U.S. alone, over 20 million adults are afflicted with osteoarthritis, costing more than $65 billion per year in health care and lost wages. Surgical techniques have been developed to address small, focal lesions, but more critical sized defects remain without a viable solution. Tissue engineering strategies produce cartilage-like constructs in vitro containing living cells in the hope of replacing damaged cartilage and restoring joint function. However, these constructs lack both sufficient integration into the surrounding tissue following implantation and the mechanical properties capable of withstanding the demanding and complex in vivo loading environment. Our central hypothesis is that exposure of engineered cartilage to fluid-induced shear stress increases the collagen content and mechanical properties (tensile and compressive). The overall objective of this project is to modulate the matrix composition and mechanical properties of engineered cartilage to be more like native tissue using a novel bioreactor. Improving the matrix components and mechanical stability of the tissue to be more similar to that of native tissue may aid in integration into a defect in vivo. The central hypothesis was proven in that shear stress potently altered the matrix composition, gene expression and mechanical properties of both thick and thin engineered cartilage. Modulation was found to be highly dependent on shear stress magnitude, duration, and waveform and affected different matrix constituents and mechanical properties in disparate ways. Our overall objective was satisfied on the basis that the bioreactor created stronger engineered tissues, but with the caveat that the tissues showed an increase in presence of type I collagen. Such an effect would be undesirable for articular cartilage engineered tissues, but could be very beneficial in fibrocartilaginous tissues such as that found in the temporomandibular joint. In conclusion, the novel bioreactor system provides a flexible platform technology for the study of three-dimensional engineered tissues, not just articular cartilage. Type I collagen Type II collagen Young's modulus Dynamic modulus Unconfined compression
7	Arthritogenic and immunogenic properties of modified autoantigens / Lundberg, Karin, January 2005 (has links) Diss. (sammanfattning) Stockholm : Karolinska institutet, 2005. / Härtill 4 uppsatser.
8	Multifactorial Media Analysis via Design of Experiment for Type II Collagen in Primary Rabbit Chondrocytes Velez Toro, Javier A 01 January 2021 (has links) Osteoarthritis is a prevalent disease that affects the articular cartilage of the joints. Millions of people suffer worldwide and it is a major cause of disability in the United States. Current research for treatments of osteoarthritis are studying tissue-engineered cartilage in vitro generated by articular chondrocytes. A challenge faced in vitro for cartilage tissue engineering is the failure of chondrocytes to produce adequate expression of type II collagen. Surprisingly, the media commonly used in vitro lacks 14 vitamins and minerals present in the physiological environment of chondrocytes. Therefore, studying the interactions between micronutrients and chondrocytes may help in potentially increasing the amount of type II collagen expressed by these cells. This project studied the combinatorial effects of vitamins and minerals in defined chondrogenic media on type II collagen expression. Linolenic acid was determined to have predominantly negative effects on chondrogenesis and Vitamin B7 to have beneficial effects. Multiple vitamins and minerals displayed significant interactions, both positive and negative. osteoarthritis rabbit chondrocytes design of experiment cartilage tissue engineering type II collagen vitamins and minerals
9	Dégradation du collagène dans le cartilage équin par la cathepsine K Noé, Beatriz 08 1900 (has links) Type II collagen, which gives the cartilage its tensile strength, is destroyed in osteoarthritis (OA). Cathepsin K is recognized as capable of cleaving type II collagen, however, the regulation of its activity in the cartilage is little known. Our hypothesis is that the activity of cathepsin K in cartilage is measured by an ELISA specific to cathepsin K cleavage site. A new specific ELISA (C2K77) was developed and tested by measuring the activity of the exogenous cathepsin K. The ELISA C2K77 was then used to measure the activity of the endogenous cathepsin K in equine articular cartilage explants cultured with or without stimulation (IL-1β, TNF-α, Oncostatin M (OSM) and LPS). Then the activity of cathepsin K was compared to that of MMPs (C1,2C ELISA) in the cartilage explants and in the freshly harvested cartilage. A significant difference was observed between normal cartilage and cartilage digested with cathepsin K (p˂0.01). There was no significant difference in the content of C2K77 between the control group and the groups stimulated while the content of C1,2C was increased by the combination of IL-1β and OSM (p = 0.002) and TNF-α and OSM (p˂0.0001). The new ELISA C2K77 demonstrates the ability to measure the activity of cathepsin K and revealed that there is a difference between the regulation of cathepsin K and MMP in articular cartilage. / Le collagène de type II, qui confère au cartilage articulaire sa résistance à la tension, est détruit dans l’arthrose. La cathepsine K est reconnue comme pouvant cliver le collagène de type II. Cependant, la régulation de son activité dans le cartilage est peu connue. Notre hypothèse est que l’activité de la cathepsine K dans le cartilage est mesurable par une ELISA spécifique au site de clivage de la cathepsine K. Une nouvelle ELISA spécifique (C2K77) a été développée et testée en mesurant l’activité de la cathepsine K exogène. L’ELISA C2K77 a ensuite été utilisée pour mesurer l’activité de la cathepsine K endogène dans des explants de cartilage articulaire équin mis en culture avec ou sans stimulations (IL-1β, TNF-α, oncostatine M (OSM) et le LPS). Puis l’activité de la cathepsine K a été comparée à celle des MMPs (avec l’ELISA C1,2C) dans les explants de cartilage et dans le cartilage fraichement récolté. Une différence significative a été observée entre le cartilage normal et le cartilage digéré avec la cathepsine K exogène (p˂0.01). Il n’y avait aucune différence significative dans la quantité de C2K77 entre le groupe control et les groupes stimulés tandis que la quantité de C1,2C a été augmenté par la combinaison de l’IL-1β et de l’OSM (p=0.002) et du TNF-α et de l’OSM (p˂0.0001). La nouvelle ELISA C2K77 démontre la capacité de mesurer l’activité de la cathepsine K et a permis de voir qu’il y a une différence entre la régulation de la cathepsine K et des MMPs. cathepsine K collagène de type II MMPs ELISA OA cartilage cytokines équin cathepsin K type II collagen Osteoarthritis equine
10	Identification et caractérisation des principaux fragments du collagène de type II du cartilage équin, produit in vitro par l'enzyme cathepsine K Théroux, Kathleen 12 1900 (has links) La dégradation protéolytique du collagène de type II est considérée comme étant un facteur majeur dans le processus irréversible de dégradation de la matrice cartilagineuse lors d’ostéoarthrose. Outre les collagénases de la famille des métaloprotéinases de la matrice (MMP-1, -8, -13), la cathepsine K est parmi les seules enzymes susceptibles de dégrader la triple hélice intacte du collagène de type II, devenant ainsi un élément pertinent pour les recherches sur l’ostéoarthrose. L’objectif à court terme de notre étude consiste en l’identification et la caractérisation de sites de clivage spécifiques de la cathepsine K sur le collagène de type II équin. La technique d’électrophorèse SDS-PAGE 1D permet la visualisation des produits de digestion et la validation des résultats de la caractérisation moléculaire des fragments protéolytiques. La caractérisation est réalisée en combinant la digestion trypsique précédant l’analyse HPLC-ESI/MS. Les résultats ont permis d’établir les sites, présents sur la carte peptidique de la molécule de collagène de type II équin, des 48 résidus prolines (P) et 5 résidus lysines (K) supportant une modification post-traductionnelle. De plus, 6 fragments majeurs, différents de ceux produits par les MMPs, sont observés par SDS-PAGE 1D puis confirmés par HPLC-ESI/MS, correspondant aux sites suivants : F1 [G189-K190], F2 [G252-P253], F3 [P326-G327], F4 [P428-G429], F5 [P563-G564] et F6 [P824-G825]. Le fragment F1 nouvellement identifié suggère un site de clivage différent de l’étude antérieure sur le collagène de type II bovin et humain. L’objectif à long terme serait le développement d’anticorps spécifiques au site identifié, permettant de suivre l’activité protéolytique de la cathepsine K par immunohistochimie et ÉLISA, dans le cadre du diagnostic de l’ostéoarthrose. / The proteolytic degradation of type II collagen is believed to be mainly an irreversible event in the process of cartilage matrix degradation in osteoarthritis. Cathepsin K is the most active enzyme protease outside the matrix metalloproteinase (MMP) family (MMP 13, -8, -1) capable of degrading the intact triple helical type II collagen. The short term objective of our study was to characterize the specific cleavage sites of CK on type II collagen. Our long term goal is to develop antibodies specific to these sites to develop biomarkers to detect it’s cleavage, for the early diagnosis of OA. Thus, in order to achieve our first goal, Cathepsin K cleavage of equine type II collagen was first examined by SDS-PAGE electrophoresis. Molecular characterization of proteolytic fragments, and therefore cleavage sites, was performed using tryptic digestion followed by LC-ESI/MS analysis to establish a comprehensive peptide map which was used as a template to identify specific proteolytic cleavage by cathepsin K. Comprehensive peptide mapping provided information on post-translational modifications and permitted the identification of 48 proline (P) and 5 lysine (K) residues that were subject to post translational modification. Six major fragments were observed on 1D SDS-PAGE and confirmed by HPLC-ESI/MS including F1 [189-190], F2 [252-253], F3 [326-327], F4 [428-429], F5 [563-564] and F6 [824-825]. The observed F1 fragment showed that cleavage was three residues N-terminal to the site reported previously for bovine type II collagen. These new findings will be used to develop new analytical methods to quantify biomarkers associate to equine type II collagen degradation in osteoarthritis patient and/or to support the development of new treatments. Cathepsine K Cathepsin K Cheval Horse Collagénase Collagène de type II Type II collagen HPLC-ESI/MS Ostéoarthrose Osteoarthritis Peptides

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