A longitudinal study of the covariation of skeletal growth with reference to the mandible, the metacarpals, and standing height a thesis submitted in partial fulfillment ... [orthodontics] /

Minkoff, Robert.

January 1959

Thesis (M.S.)--University of Michigan, 1959.

Regulation of chondrocyte growth i̲n̲ v̲i̲t̲r̲o̲

Makower, Anne-Marie.

January 1989

Thesis (doctoral)--Karolinska Institutet, Stockholm, 1989. / Extra t.p. with thesis statement inserted. Includes bibliographical references.

Identification of cartilage-binding peptides and antibody fragments designed for targeted therapy of skeletal growth disorders.

January 2013

骺軟骨板是位於長骨骨骺的一個軟骨結構，其主要功用為使骨骼延伸生長。 若人類骺軟骨板基因出現障礙，骨骼生長往往會受到嚴重的影響，使骨骼變得短小、畸形，造成殘障。此外，一些後天的系統性失調也會損害骺軟骨板的正常運作，導致矮小症。現今常用來醫治骨骼生長障礙的包括重組的人類生長荷爾蒙。然而，它的功效並非顯著，亦帶來很多的副作用；因此，我們希望能尋求更好的醫治方法。 / 近有的研究結果顯示，很多的內分泌及分泌因子能夠刺激骺軟骨板進行軟骨增生。但是，研究者卻往往未能將這些因子轉化及運用作醫療用途，原因是它們通常都是局部性地於骺軟骨板產出及發生效用。倘若以上提及的生長因子能給骺軟骨板的靶子蛋白鏈準確地被帶往骺軟骨板，那麼這些因子便能有效地被利用作治療用途，而其效能亦會給大大提高，副作用也會被減低。因此，我們現在進行研究的首要目標為於採用噬菌體展示和酵母展示方法， 尋找那些能認辨出骺軟骨板的靶子蛋白鏈及單鏈抗體。 / 於噬菌體展示庫裡，我們找出了兩條能認辨出小鼠骨骼軟骨細胞的靶子蛋白鏈 － C1 (RLDPTSYLRTFW) 和 C19 (HDSQLEALIKFM)。然而於體外測試實驗中， 它們對軟骨細胞及細胞外基質只擁有中度的親近性和特異性。此後，於酵母展示庫裡，我們亦發現三條可認辨某骺軟骨板蛋白的單鏈抗體 － 它們的親近性甚高 (達至1 nM)，而其對軟骨組織的特異性也為良好 (它們只認辨軟骨組織，但卻沒能認辨出其他的軟組織，包括腦、心臟、肝臟、肺臟、腎臟、脾臟、小腸及肌肉)。 其後，於小鼠胚胎免疫染色測試實驗中，這些單鏈抗體只亦選擇地認辨軟骨組織。再者，當這些單鏈抗體被注射入小鼠的靜脈中，它們也會準確地停留在軟骨組織裡，顯示出其特異性於體內測試實驗中亦存在。 / 總括而言，利用噬菌體展示和酵母展示方法，我們發現了一些能認辨出骺軟骨板的靶子蛋白鏈及單鏈抗體。這些單鏈抗體擁有對軟骨組織非常高的親近性和特異性。我們預計，若然將這些單鏈抗體和內分泌及分泌因子連結在一起，它們或能成為醫治骨骼生長障礙的新方法。 / The growth plate is a specialized cartilage structure at the ends of long bones that is responsible for bone elongation. Many human genetic disorders of the growth plate impair skeletal growth, often resulting in bones that are severely short and malformed, causing serious disability. Many acquired systemic disorders also impair growth plate function, causing short stature. Currently, recombinant human growth hormone is used to treat growth disorders, but it has limited efficacy for severe diseases and causes significant adverse effects. / Recent studies have identified many endocrine and paracrine factors that are capable of promoting chondrogenesis at the growth plate. However, the development of these molecules into effective therapies has been hampered by their action mechanism; they are produced locally and act locally in the growth plate and thus fail to lend themselves to systemic therapeutic approaches. We envisioned that, if these growth factors could be linked to growth plate-targeting peptides or polypeptides and then administered systemically, these molecules might provide a better treatment strategy for growth disorders because targeting might augment the therapeutic effect on the growth plate but diminish undesirable effects on non-target tissues. Toward this goal, we sought to identify peptides and antibody fragments that bind to cartilage tissue using phage display and yeast display technologies. / We used a phage display library that expressed linear peptides of 12 random amino acids on the phage surface and then selected for binding to murine primary cultured chondrocytes. This approach successfully identified two peptides, namely C1 (RLDPTSYLRTFW) and C19 (HDSQLEALIKFM), which exhibited moderate binding affinity and specificity to chondrocytes and extracellular matrix in vitro. We also used a yeast display library to identify three single-chain variable(scFv) antibody fragments that bound strongly to a growth plate-specific protein(EC50 values less than 1 nM). These antibody fragments demonstrated specific binding in vitro to homogenates of cartilage tissues, but not homogenates of brain, heart, liver, lung, kidney, spleen, small intestine, or muscle. Moreover, they also exhibited tissue-specific binding to cartilage structures in sections of mouse embryos. When these purified antibody fragments were injected intravenously in mice, they localized to cartilage and were not detectable in other tissues, including brain, heart, liver, lung, kidney, spleen, small intestine, or muscle, indicating that the antibody fragments were capable of specifically targeting cartilage tissue in vivo. / In conclusion, we employed phage display and yeast display methods to identify peptides and antibody fragments that bind to cartilage tissues. The selected antibody fragments showed particularly high binding affinity and specificity to cartilage. Conjugating these antibody fragments to endocrine and paracrine signaling molecules has the potential to provide targeted therapy for growth plate disorders. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Cheung, Sao Fong. / Thesis (Ph.D.) Chinese University of Hong Kong, 2013. / Includes bibliographical references (leaves 89-102). / Abstracts also in Chinese.

Bones--Diseases--Treatment

Bones--Growth

Cartilage--Growth

Bone Diseases--therapy

Bone Development

Cartilage--growth & development

Regulation of chondrocyte growth i̲n̲ v̲i̲t̲r̲o̲

Makower, Anne-Marie.

January 1989

Thesis (doctoral)--Karolinska Institutet, Stockholm, 1989. / Extra t.p. with thesis statement inserted. Includes bibliographical references.

Chondrocyte : a target for the treatment of osteoarthritis

Lin, Zhen

January 2007

[Truncated abstract] Osteoarthritis (OA) is the most common form of arthritis, characterized by progressively degeneration of articular cartilage. Chondrocyte is the only cell type in articular cartilage tissue and responsible for cartilage matrix turnover. This thesis focuses on the biological and genetic behaviors of human chondrocyte and potential therapeutic strategies that target on chondrocyte. Chondrocytes have been used for the tissue-engineered cartilage construction, especially in articular cartilage repair. The technique of chondrocyte-base tissue engineering utilizes in vitro propagated chondrocytes combined with several manufactured biomaterials to regenerate cartilage tissue. Although these technologies have been successfully applied in clinic, the biological characteristics of chondrocyte during in vitro propagation and after implantation remain unclear. This thesis reviewed the present studies of chondrocyte biology and its potential uses in tissue engineering. Particularly, chondrocytes have been shown to de-differentiate into fibroblastic-cells when they are exposed to inflammatory conditions or cultured on monolayer in vitro. This thesis investigated the gene expression profile of chondrocytes when they are cultured and serially passaged on monolayer in vitro. Human chondrocytes obtained from OA patients were cultured up to passage 6. Twenty-eight chondrocyte associated genes were measured by Real-time PCR. The results showed that a number of genes were changed in expression levels at various stages of passage as indications of chondrocyte de-differentiation. Chondrocytes derived from OA patients or normal donors exhibited a very similar gene expression pattern. Interestingly, transcription factor Sox-9, which plays a key role in chondrogenesis remained unchanged with increasing passage number, indicating that the de-differentiation process of chondrocyte is reversible. This thesis also focused on the development of novel pharmacological approaches for OA that target on articular chondrocyte. The clinical feature, etiology, pathogenesis, diagnostic approaches, conventional and potential future treatments for OA were briefly reviewed in this thesis. ... The effects of natural compounds on chondrocyte gene expression, proteoglycan degradation and nitric oxide production were measured. The results showed that parthenolide, a NF-kB inhibitor, regulated chondrocyte function by suppressing the up-regulation of gene expression of inflammatory factors and matrix proteinases induced by lipopolysaccharide, and down-regulating COX-2 expression. Parthenolide was able to reduce proteoglycan degradation in human chondrocytes, but had no effect on nitric oxide production. These results suggest that parthenolide mediates inflammatory-activated NF-kB pathway, and subsequently reduces inflammatory response, prevents cartilage destruction and relieves pain, and hence may be useful for OA treatment.

Cartilage -- Growth

Cartilage cells

Osteoarthritis

Tissue engineering

Chondrocyte

Cartilage

Osteoarthritis

Effects of ¹⁵³samarium-ethylenediaminetetramethylene phosphonate on physeal and articular cartilage in juvenile rabbits /

Essman, Stephanie Christine.

January 2003

Thesis (M.S.)--University of Missouri--Columbia, 2003. / "December 2003." Typescript. Vita. Includes bibliographical references (leaves 84-96). Also issued on the Internet.

Effects of ¹⁵³samarium-ethylenediaminetetramethylene phosphonate on physeal and articular cartilage in juvenile rabbits

Essman, Stephanie Christine.

January 2003

Thesis (M.S.)--University of Missouri--Columbia, 2003. / "December 2003." Typescript. Vita. Includes bibliographical references (leaves 84-96). Also issued on the Internet.

Predicting Articular Cartilage Constituent Material Properties Following In Vitro Growth Using a Proteoglycan-Collagen Mixture Model

Stender, Michael

01 March 2011

A polyconvex continuum-level proteoglycan Cauchy stress function was developed based on the continuum electromechanical Poisson-Boltzmann unit cell model for proteoglycan interactions. The resulting proteoglycan model was combined with a novel collagen fibril model and a ground substance matrix material to create a polyconvex constitutive finite element model of articular cartilage. The true collagen fibril modulus , and the ground substance matrix shear modulus , were varied to obtain the best fit to experimental tension, confined compression, and unconfined compression data for native explants and explants cultured in insulin-like growth factor-1 (IGF-1) and transforming growth factor-β1 (TGF-β1). Results indicate that culture in IGF-1 results in a weakening of the COL fibers compared to native explants, and culture in TGF-β1 results in a strengthening of the COL fibers compared to native explants. These results elucidate the biomechanical changes in collagen fibril modulus, and ground matrix shear modulus following in vitro culture with IGF-1 and TGF-β1. Understanding the constitutive effects of growth factor stimulated culture may have applications in AC repair and tissue engineering.

Articular Cartilage

Finite Element Modeling

Cartilage growth

Collagen Fiber Modulus.

Biomechanical Engineering

Mechanical Engineering

Cell and tissue engineering of articular cartilage via regulation and alignment of primary chondrocyte using manipulated transforming growth factors and ECM proteins : effect of transforming growth factor-beta (TGF-β1, 2 and 3) on the biological regulation and wound repair of chondrocyte monolayers with and without presence of ECM proteins

Khaghani, Seyed Ali

January 2010

Articular cartilage is an avascular and flexible connective tissue found in joints. It produces a cushioning effect at the joints and provides low friction to protect the ends of the bones from wear and tear/damage. It has poor repair capacity and any injury can result pain and loss of mobility. One of the common forms of articular cartilage disease which has a huge impact on patient's life is arthritis. Research on cartilage cell/tissue engineering will help patients to improve their physical activity by replacing or treating the diseased/damaged cartilage tissue. Cartilage cell, called chondrocyte is embedded in the matrix (Lacunae) and has round shape in vivo. The in vitro monolayer culture of primary chondrocyte causes morphological change characterized as dedifferentiation. Transforming growth factor-beta (TGF-β), a cytokine superfamily, regulates cell function, including differentiation and proliferation. The effect of TGF-β1, 2, 3, and their manipulated forms in biological regulation of primary chondrocyte was investigated in this work. A novel method was developed to isolate and purify the primary chondrocytes from knee joint of neonate Sprague-Dawley rat, and the effect of some supplementations such as hyaluronic acid and antibiotics were also investigated to provide the most appropriate condition for in vitro culture of chondrocyte cells. Addition of 0.1mg/ml hyaluronic acid in chondrocyte culture media resulted an increase in primary chondrocyte proliferation and helped the cells to maintain chondrocytic morphology. TGF-β1, 2 and 3 caused chondrocytes to obtain fibroblastic phenotype, alongside an increase in apoptosis. The healing process of the wound closure assay of chondrocyte monolayers were slowed down by all three isoforms of TGF-β. All three types of TGF-β negatively affected the strength of chondrocyte adhesion. TGF-β1, 2 and 3 up regulated the expression of collagen type-II, but decreased synthesis of collagen type-I, Chondroitin sulfate glycoprotein, and laminin. They did not show any significant change in production of S-100 protein and fibronectin. TGF-β2, and 3 did not change expression of integrin-β1 (CD29), but TGF-β1 decreased the secretion of this adhesion protein. Manipulated TGF-β showed huge impact on formation of fibroblast like morphology of chondrocytes with chondrocytic phenotype. These isoforms also decreased the expression of laminin, chondroitin sulfate glycoprotein, and collagen type-I, but they increased production of collagen type-II and did not induce synthesis of fibronectin and S-100 protein. In addition, the strength of cell adhesion on solid surface was reduced by manipulated TGF-β. Only manipulated form of TGF-β1 and 2 could increase the proliferation rate. Manipulation of TGF-β did not up regulate the expression of integrin-β1 in planar culture system. The implications of this R&D work are that the manipulation of TGF-β by combination of TGF-β1, 2, and 3 can be utilized in production of superficial zone of cartilage and perichondrium. The collagen, fibronectin and hyaluronic acid could be recruited for the fabrication of a biodegradable scaffold that promotes chondrocyte growth for autologous chondrocyte implantation or for formation of cartilage.

611

The role of PPARgamma in cartilage growth and development using cartilage-specific PPARgamma knockout mice

Monemdjou, Roxana

07 1900

Le cartilage est un tissu conjonctif composé d’une seule sorte de cellule nommée chondrocytes. Ce tissu offre une fondation pour la formation des os. Les os longs se développent par l'ossification endochondral. Ce processus implique la coordination entre la prolifération, la différenciation et l'apoptose des chondrocytes, et résulte au remplacement du cartilage par l'os. Des anomalies au niveau du squelette et des défauts liés à l’âge tels que l’arthrose (OA) apparaissent lorsqu’il y a une perturbation dans l’équilibre du processus de développement. À ce jour, les mécanismes exacts contrôlant la fonction et le comportement des chondrocytes pendant la croissance et le développement du cartilage sont inconnus. Le récepteur activateur de la prolifération des peroxysomes (PPAR) gamma est un facteur de transcription impliqué dans l'homéostasie des lipides. Plus récemment, son implication a aussi été suggérée dans l'homéostasie osseuse. Cependant, le rôle de PPARγ in vivo dans la croissance et le développement du cartilage est inconnu. Donc, pour la première fois, cette étude examine le rôle spécifique de PPARγ in vivo dans la croissance et le développement du cartilage. Les souris utilisées pour l’étude avaient une délétion conditionnelle au cartilage du gène PPARγ. Ces dernières ont été générées en employant le système LoxP/Cre. Les analyses des souris ayant une délétion au PPARγ aux stades embryonnaire et adulte démontrent une réduction de la croissance des os longs, une diminution des dépôts de calcium dans l’os, de la densité osseuse et de la vascularisation, un délai dans l’ossification primaire et secondaire, une diminution cellulaire, une perte d’organisation colonnaire et une diminution des zones hypertrophiques, une désorganisation des plaques de croissance et des chondrocytes déformés. De plus, la prolifération et la différenciation des chondrocytes sont anormales. Les chondrocytes et les explants isolés du cartilage mutant démontrent une expression réduite du facteur de croissance endothélial vasculaire (VEGF)-A et des éléments de production de la matrice extracellulaire. Une augmentation de l’expression de la métalloprotéinase matricielle (MMP)-13 est aussi observée. Dans les souris âgées ayant une délétion au PPARγ, y est aussi noté des phénotypes qui ressemblent à ceux de l’OA tel que la dégradation du cartilage et l'inflammation de la membrane synoviale, ainsi qu’une augmentation de l’expression de MMP-13 et des néoépitopes générés par les MMPs. Nos résultats démontrent que le PPARγ est nécessaire pour le développement et l’homéostasie du squelette. PPARγ est un régulateur essentiel pour la physiologie du cartilage durant les stades de croissance, de développement et de vieillissement. / Cartilage, a connective tissue composed of chondrocytes, provides an intermediate template on which bones are formed. Long bones develop through endochondral ossification, involving coordination between chondrocyte proliferation, differentiation and apoptosis, resulting in bone replacing cartilage. Disturbances in this balance results in skeletal abnormalities, and age-related defects including osteoarthritis (OA). The exact mechanisms that control chondrocyte function and behaviour during growth and development are unknown. Peroxisome proliferator-activated receptor (PPAR) gamma, a transcription factor involved in lipid homeostasis, has recently been suggested to be involved in bone homeostasis. However, PPARγ’s role in cartilage growth and development in vivo is unknown. Therefore, for the first time, this study examines PPARγ’s specific in vivo role in cartilage growth and development using cartilage-specific PPARγ knockout (KO) mice. Conditional KO mice were generated using LoxP/Cre system. Histomorphometric analyses of embryonic and adult mutant mice demonstrate reduced long bone growth, calcium deposition, bone density, vascularity, and delayed primary and secondary ossification. Mutant growth plates are disorganized with abnormal chondrocyte shape, proliferation and differentiation, reduced cellularity, loss of columnar organization, and shorter hypertrophic zones. Isolated mutant chondrocytes and cartilage explants show decreased vascular endothelial growth factor (VEGF)-A and extracellular matrix (ECM) production product expression, and increased matrix metalloproteinase (MMP)-13 expression. Aged mutant mice exhibit accelerated OA-like phenotypes, and enhanced cartilage degradation, synovial inflammation, MMP-13 and MMP-generated neoepitope expression. Our data demonstrate that PPARγ is required for normal skeletal development and homeostasis, and is a critical regulator of cartilage health and physiology in early growth and development and aging.

PPARgamma

Osteoarthritis

Knockout mice

Cartilage growth and development

Aging

Chondrogenesis

Endochondral ossification

Arthrose

Souris ayant une délétion au PPARgamma

Ossification endochondral

Formation du cartilage

Vieillissement