Diffusional Properties of Articular Cartilage

Leddy, Holly Anne

14 March 2007

Articular cartilage is the connective tissue that lines joints and provides a smooth surface for articulation and shock absorption. Osteoarthritis, the progressive degeneration of cartilage, is a painful, debilitating, and widespread disease, affecting 70% of people over 65. Because cartilage is avascular, molecular transport occurs primarily via diffusion. The goal of these studies was to examine whether cartilage matrix structure and composition have a significant effect on diffusive transport. We hypothesized that diffusion is anisotropic in the surface zone of cartilage where collagen structure is aligned and densely packed. A theoretical model and experimental protocol for fluorescence imaging of continuous point photobleaching (FICOPP) were developed to measure diffusional anisotropy. Significant anisotropy was observed in ligament, a highly ordered collagenous tissue. In less ordered articular cartilage, diffusional anisotropy was dependent on site in the tissue and size of the diffusing molecule. These findings suggest that diffusional transport of macromolecules is anisotropic in collagenous tissues, with higher rates of diffusion along primary orientation of collagen fibers. We hypothesized that structural differences in the pericellular matrix of cartilage (PCM) would lead to differences in diffusive properties as compared to the surrounding extracellular matrix (ECM). We modified the scanning microphotolysis (SCAMP) technique to allow measurement of diffusion coefficients within the PCM. Diffusion coefficients in the PCM were lower than in the adjacent ECM in normal cartilage, but with early stage arthritis, the PCM diffusivity was not different from that of the ECM. These data suggest that breakdown of the PCM is an early step in arthritis development. We hypothesized that compression of cartilage would cause site‐specific diffusivity decreases and diffusional anisotropy increases. We utilized SCAMP and FICOPP to measure diffusion coefficients and diffusional anisotropy in cartilage as it was compressed. We found that diffusivity decreased and anisotropy increased with increasing strain in a site‐specific manner. These findings suggest that the high surface zone strains that lead to low diffusivity and high anisotropy will decrease transport between cartilage and synovial fluid in compressed cartilage. We have shown that matrix structure and composition have a significant effect on diffusive transport in cartilage. / Dissertation

Osteoarthritis

pericellular matrix of cartilage (PCM)

extracellular matrix (ECM)

scanning microphotolysis (SCAMP)

The Influence of Normal Physiological Forces on Porcine Aortic Heart Valves in a Sterile Ex Vivo Pulsatile Organ Culture System

Konduri, Suchitra

17 March 2005

The aortic valve functions in a complex mechanical environment which leads to force dependent cellular and tissue responses. Characterization of these responses provides a fundamental understanding of valve pathogenesis. The aim of this work was to develop an ex vivo organ culture system capable of simulating physiological aortic pressures and flow rates, and study the biological characteristics of native porcine aortic valves cultured in the system. Collagen, sGAG and elastin content of the valve leaflets were measured and cusp morphology, cell phenotype, cell proliferation and apoptosis were examined. Presence of endothelial cells (ECs) on the leaflet surface was also evaluated. The differences in collagen, sGAG and elastin contents were not significant (p greater than0.05) between the cultured and fresh valve leaflets. The cultured valves maintained the structural integrity of the leaflets while preserving the native morphology and cell phenotype. Cell phenotype in leaflets incubated statically under atmospheric conditions decreased compared to fresh and cultured valve leaflets, indicating the importance of mechanical forces in maintaining the natural biology of the valve leaflets. ECs were retained on the surfaces of cultured leaflets with no remodeling of the leaflets. The number of apoptotic cells in the cultured leaflets was significantly (p less than 0.05) less than in the statically incubated leaflets and comparable to fresh leaflets. The sterile ex vivo organ culture system thus maintained the viability and native biological characteristics of the aortic valves that were cultured under dynamic conditions for a period of 48 hours.

Flow and pressure waveforms

Porcine aortic valve leaflets

Extracellular matrix components

Cell phenotype

Endothelial cells

Organ culture system

Tissue morphology

Investigations of the Composition-Function Relationships in Normal, Degraded, and Engineered Articular Cartilage Using Epic-Microcomputed Tomography

Palmer, Ashley Wells

22 March 2007

Articular cartilage provides a low-friction surface during normal joint motion and distributes forces to the underlying bone. The extracellular matrix (ECM) composition of healthy cartilage has previously been shown to be an excellent predictor of its mechanical properties. Changes in ECM composition and loss of mechanical function are known to occur with degenerative conditions such as osteoarthritis. Identifying differences in the composition-function relationships of cartilage under different anabolic, catabolic, and homeostatic conditions may thus be a useful approach for identifying factors (e.g. ECM content, distribution, and structure) which are critical to mechanical function. In addition, diagnostic tools capable of monitoring changes in the cartilage ECM may increase our understanding of the effects of ECM changes on composition-functions relationships. The goals of this work were to investigate composition-function relationships in healthy, degraded, and engineered cartilage and to develop a microcomputed tomography-based approach to analyze changes in matrix composition and morphology in articular cartilage. In healthy explants, compressive and shear properties were dependent on both sGAG and collagen content. In contrast, the compressive properties of IL-1stimulated cartilage were dependent on sGAG but not collagen content. To assess changes in sGAG content, EPIC-microcomputed tomography, a 3D contrast-enhanced microcomputed tomography technique was developed. EPIC-microcomputed tomography attenuation was found to be an excellent predictor of sGAG content in IL-1-stimulated cartilage explants and engineered cartilage. In addition, analytical approaches were developed to use EPIC-microcomputed tomography for the in situ analysis of cartilage morphology. EPIC-microcomputed tomography was also used to analyze spatial differences in sGAG accumulation in bilayer engineered cartilage for comparison with the local strain profile. This work underscores the significance of ECM composition and structure in regulating cartilage mechanical properties and validates the use of EPIC-microcomputed tomography as a diagnostic for monitoring sGAG content and potentially for assessing mechanical function in models of degeneration and regeneration.

Articular cartilage

Microcomputed tomography

Cartilage mechanics

Composition-function relationships

Tomography

Acellular matrices derived from differentiating embryonic stem cells

Nair, Rekha

10 November 2009

Embryonic stem cells (ESCs) can differentiate into all somatic cells, and as such, are a promising cell source for therapeutic applications. In vitro, ESCs spontaneously differentiate via the aggregation of cells into embryoid bodies (EBs), which recapitulate aspects of early embryogenesis and harbor a unique reservoir of cues critical for tissue formation and morphogenesis. Embryonic healing responses employ similar intrinsic machinery used for tissue development, and these morphogenic cues may be captured within the EB microenvironment. Recent studies have shown that when injected into injury or defect models in vivo, ESCs synthesize and secrete extracellular factors that ultimately contribute to repair, suggesting that these molecules may be as important for regenerative therapies as functional differentiation of the cells. The overall objective of this project was to develop novel acellular matrices derived from differentiating ESCs undergoing morphogenesis. The central hypothesis was that embryonic matrices contain complex mixtures of extracellular factors that, when isolated, retain bioactivity and enhance wound healing in an adult environment. The overall objective was accomplished by: (1) investigating the production of extracellular matrix (ECM) by differentiating ESCs as a function of differentiation time; (2) assessing the ability of solvents to efficiently decellularize EBs; and (3) evaluating the healing response elicited by acellular matrices derived from EBs in a murine dermal wound healing model. Endogenous ECM synthesis by EBs varied with time and was associated with specific differentiation events. Novel techniques were developed to effectively remove cell components from EBs in order to extract complex, bioactive acellular matrices. EB-derived acellular matrices significantly enhanced the healing of excisional dermal wounds in mice, indicating the potency of extracellular factors synthesized by ESCs. All together, these studies demonstrate that acellular matrices derived from ESCs retain morphogenic factors capable of influencing tissue repair. In addition, this work lays the foundation for future studies to further examine the functional role of endogenous matrix molecules on ESC differentiation and to evaluate the utility of a stem cell-derived matrix for a variety of regenerative medicine applications.

Regenerative medicine

Extracellular matrix

Embryoid bodies

Embryonic stem cells

Dermal wound healing

Tissue engineering

Wound healing

Regeneration (Biology)

Bioactive factors secreted by differentiating embryonic stem cells

Ngangan, Alyssa V.

07 July 2011

Current therapeutic strategies to stimulate endogenous angiogenic processes within injured tissue areas are typically based on introducing exogenous pro-angiogenic molecules or cell populations. Stem cell transplantation for angiogenic therapy aims to deliver populations of cells that secrete angiogenic factors and/or engraft in the new branching vasculature within the damaged tissue. Utilizing stem or progenitor cells has been shown to induce a rather robust angiogenic response despite minimal repopulation of the host vasculature, suggesting that stem cells may provide paracrine factors that transiently induce endogenous angiogenesis of tissues undergoing regeneration. Early differentiating embryonic stem cell (ESC) aggregates, referred to as embryoid bodies (EBs), can undergo vasculogenic differentiation, and also produce extracellular matrix and growth factors that induce proliferation, differentiation, and tissue morphogenesis. Taken together, the ESC extracellular environment may be an effective means by which to manipulate cell behavior. Thus, the objective of this project was to harness morphogens derived from ESCs undergoing differentiation and analyze their bioactive potential. To examine the expression of extracellular factors within EBs, gene expression arrays in conjunction with a variety of analytical tools were utilized to gain an understanding of the importance of extracellular factors in ESC differentiation. Furthermore, the soluble fraction of secreted factors contained within EB-conditioned media was compared to the matrix-associated factors produced by EBs, which led to the development of novel ESC-derived matrices via mechanical acellularization methods. Acellular embryonic stem cell-derived matrices demonstrated the retention of bioactive factors that impacted aspects of angiogenesis. In conclusion, extracellular factors were modulated in response to the progression of EB differentiation and can further be harnessed via acellularization techniques, in order to deliver bioactive ESC-secreted factors in a cell-free manner.

Angiogenesis

Extracellular matrix

Growth factors

Embryonic stem cells

Stem cells

Stem cells Research

Embryonic stem cells Research

Neovascularization

Aligned Fibrillar Collagen Matrices for Tissue Engineering / Ausgerichtete Kollagenfibrillenmatrices für das Tissue Engineering

Lanfer, Babette

18 May 2010

The desire for repair of tissue defects and injury is the major need prompting research into tissue engineering. Engineering of anisotropic tissues requires production of ordered substrates that orient cells preferentially and support cell viability and differentiation. Towards this goal, this thesis investigated methodologies to align extracellular matrix structures in vitro to guide stem/progenitor cell behaviour for tissue regeneration. Aligned collagen fibrils were deposited on planar substrates from collagen solutions streaming through a microfluidic channel system. Collagen solution concentration, degree of gelation, shear rate and pre-coating of the substrate were demonstrated to determine the orientation and density of the immobilized fibrils. The degree of collagen fibril orientation increased with increasing flow rates of the solution while the matrix density increased at higher collagen solution concentrations and on hydrophobic polymer pre-coatings. Additionally, the length of the immobilized collagen fibrils increased with increasing solution concentration and gelation time. Aligned collagen matrices were refined by incorporating the glycosaminoglycan heparin to study multiple extracellular matrix components in a single system. Multilineage (osteogenic/adipogenic/chondrogenic) differentiation of mesenchymal stem and progenitor cells was maintained by the aligned structures. Most noticeable was the observation that during osteogenesis, aligned collagen substrates choreographed ordered matrix mineralization. Likewise, myotube assembly of C2C12 cells was profoundly influenced by aligned topographic features resulting in enhanced myotube organization and length. Neurites from neural stem cells were highly oriented in the direction of the underlying fibrils. Neurite outgrowth was enhanced on aligned collagen compared to non-aligned collagen or poly-D-lysine substrates, while neural differentiation and cell survival were not influenced by the type of substrate. Using the new method to align collagen type I, the interior walls of cellulose hollow fiber membranes were coated with longitudinally aligned collagen fibrils to fabricate an advanced guidance conduit for nerve regeneration. First cell culture experiments showed that the tubes coated with aligned collagen supported viability and adherence of spinal cord-derived neurospheres. Together, these results demonstrate the feasibility of aligned collagen matrices as a versatile platform to control cell behaviour towards tissue regeneration. Ultimately, the new method to align collagen fibrils and to coat hollow membranes may become an integral component of tissue engineering, working synergistically with other emerging techniques to promote functional tissue replacements.

tissue engineering

collagen

extracellular matrix

alignment

biopolymers

shear flow

Geweberekonstruktion

Kollagen

Ausrichtung

Biopolymere

Extrazelluläre Matrix

ddc:620

rvk:ZM 7070

Μελέτη μακρομορίων του εξωκυττάριου χώρου : οργάνωση και ρόλος τους κατά την ανάπτυξη του πρώιμου εμβρύου

Γιακουμάκη, Αναστασία

22 September 2009

Οι πρωτεογλυκάνες αλληλεπιδρούν μεταξύ τους και με άλλα μορφορυθμιστικά μόρια όπως γλυκοπρωτεΐνες και ιντεγκρίνες, καθώς επίσης και με αυξητικούς παράγοντες. Μεγάλο μέρος των ποικίλων λειτουργιών των πρωτεογλυκανών συνδέεται με τις γλυκοζαμινογλυκανικές αλυσίδες (GAGs) τους. Για να μελετήσουμε τη λειτουργία των πρωτεογλυκανών κατά την ανάπτυξη του πρώιμου εμβρύου όρνιθας χρησιμοποιήσαμε το β-D-xyloside, έναν εξειδικευμένο αναστολέα της βιοσύνθεσης των πρωτεογλυκανών και ειδικότερα της πρόσδεσης των αλυσίδων γλυκοζαμινογλυκανών στον πρωτεϊνικό κορμό των πρωτεογλυκανών. Χαμηλές συγκεντρώσεις β-xyloside που είναι γνωστό ότι αναστέλλουν την προσθήκη θειϊκής χονδροϊτίνης αλλά όχι της θειϊκής ηπαράνης στον πρωτεϊνικό κορμό, αποτελούν ένα χρήσιμο εργαλείο για τη μελέτη του ρόλου των πρωτεογλυκανών. Τα πρότυπα των πρωτεϊνών στα έμβρυα που μεταχειρίστηκαν με β-xyloside έδειξαν μετατόπιση των ραδιενεργών κορυφών σε μικρότερη μοριακή μάζα που φαίνεται να οφείλεται στη μείωση του μεγέθους πρωτεογλυκανών. Ήταν αξιοσημείωτο στα αποτελέσματά μας ότι το β-xyloside μετέβαλλε τη μορφή της πρωτεογλυκάνης θειϊκής χονδροϊτίνης decorin προς χαμηλότερα μοριακά βάρη ενώ δε φάνηκε να επηρεάζει το μέγεθος της πρωτεογλυκάνης θειϊκής ηπαράνης perlecan. Στα έμβρυα που μεταχειρίστηκαν με β-xyloside περισσότερη πρωτεϊνη συντέθηκε στα έμβρυα του σταδίου ΧΙΙ (μορίδιο), σε σχέση με αυτά του σταδίου ΗΗ2 (αρχή πρωτογενούς αύλακας/πρώιμο γαστρίδιο), συγκρινόμενα με τα αντίστοιχα έμβρυα μάρτυρες. Αυτό θα μπορούσε να αντανακλά μια επιταχυνόμενη κινητοποίηση και/ή μια μετάφραση των ωογενετικών μεταγράφων στα έμβρυα του σταδίου ΧΙΙ, όταν διαταράχτηκε ο μεταβολισμός των πρωτεογλυκανών. Η απορρύθμιση πρωτεογλυκανών, τροποποιώντας τη λειτουργικότητα και επηρεάζοντας το επίπεδο έκφρασής τους, είχε ως αποτέλεσμα την αδυναμία του πρώιμου εμβρύου να δομήσει την εξωκυττάρια ύλη φυσιολογικά. Το αποτέλεσμα ήταν η κατάρρευση της τυπικής αρχιτεκτονικής του πρώιμου εμβρύου στα πειράματά μας. Πρωτεογλυκάνες θειϊκής χονδροϊτίνης φαίνεται να χρειάζονται για την οργάνωση του σταδίου του βλαστιδίου της όρνιθας. Για την επαγωγή του νευρικού συστήματος φάνηκε να χρειάζονται πρωτεογλυκάνες θειϊκής χονδροϊτίνης/δερματάνης που έχουν συγκεντρωθεί από το στάδιο πριν την έναρξη των μορφογενετικών κινήσεων της γαστριδίωσης και η συνεχής βιοσύνθεση των πρωτεογλυκανών είναι απαραίτητη για τη μορφογένεση του νευρικού σωλήνα. Μελετήσαμε επίσης το πρότυπο κατανομής της συνδετικής πρωτεϊνης πρωτεογλυκανών με ανοσοφθορισμό και ανοσοκατακρήμνιση και το ρόλο αυτής της γλυκοπρωτεϊνης με τη χρήση αντισωμάτων έναντι αυτής. Η συνδετική πρωτεΐνη μεσολαβεί στην πρόσδεση στο υαλουρονικό οξύ πρωτεογλυκανών όπως οι aggrecan, neurocan, versican και brevican δημιουργώντας σταθερά σύμπλοκα στην εξωκυττάρια ύλη. Η αναγνώριση των μορφών της συνδετικής πρωτεΐνης 1 (LP1, 48kDa) και συνδετικής πρωτεΐνης 2 (LP2, 44kDa) στο πρώιμο έμβρυο ήταν επίσης ένα ενδιαφέρον εύρημα των πειραμάτων μας. Είναι γνωστό ότι συνδυασμοί των LP1 και LP2 δημιουργούν πιο σταθερά σύμπλοκα απ’ ότι μόνο του το καθένα από τα δύο μόρια αυτά. Αυτό φαίνεται και από τα πειράματά μας που δείχνουν ότι η aggrecan (180kDa) φαίνεται να συν-κατακρημνίζεται με τις συνδετικές πρωτεΐνες LP1 και LP2. Τα πειράματα ανοσοφθορισμού έδειξαν ότι η συνδετική πρωτεΐνη αρχίζει να εκφράζεται στο στάδιο του βλαστιδίου και επιδεικνύει μια διαφορική έκφραση χωρο-χρονικά κατά την ανάπτυξη του πρώιμου εμβρύου υποδεικνύοντας ότι είναι σημαντική στην κυτταρική μετανάστευση και διαφοροποίηση κυττάρων και στη μορφογένεση ιστών και οργάνων. Αυτό επιβεβαιώθηκε και από τη μελέτη του ρόλου της, στην επόμενη σειρά πειραμάτων μας με τη χρήση μονοκλωνικού αντισώματος έναντι αυτής. Η αναστολή της λειτουργίας της συνδετικής πρωτεϊνης με τη χρήση αντισωμάτων έναντι αυτής έδειξε ότι αυτή η πρωτεϊνη φαίνεται να είναι σημαντική στην οργάνωση της νευρικής πλάκας και τη μορφογένεση του νευρικού σωλήνα, στη μορφογένεση του καρδιακού σωλήνα, του εντέρου, στο σχηματισμό της ραχιαίας αορτής και στην επιθηλιοποίηση των σωμιτών. / Proteoglycans participate in cellular interactions via modulating the effects of growth factors or with other mechanisms in early embryo. The majority of the functions of proteoglycans are associated with the glycosaminoglycan (GAG) chains. We used β-D-xyloside, an inhibitor of proteoglycan synthesis and specifically of GAG attachment to proteoglycan core proteins, to study proteoglycan functions in early chick embryo development. Low concentrations of β-xyloside which are known to affect differentially chondroitin but not heparan sulfate proteoglycan biosynthesis have provided a convenient tool for altering proteoglycan production. The protein patterns of xyloside-treated embryos showed a shift of radioactive peaks to lower molecular mass which could be attributed to the reduction of proteoglycan size as was demonstrated by chondroitinase ABC/AC II treatments. It was notable in our data that β-xyloside altered the chondroitin sulfate proteoglycan decorin to lower molecular mass while it did not seem to affect the size of the heparin sulfate proteoglycan perlecan. More protein was synthesized from xyloside-treated embryos at stage XII (morula) than from embryos at stage HH2 (initial primitive streak/early gastrula) when compared to the controls. This could have reflected an accelerated translation and/or mobilization of oogenetic transcripts in embryos at stage XII when proteoglycan metabolism was disrupted. Misregulation of proteoglycans by modulating the functionality of the protein and by influencing their expression level resulted in an inability of the early embryo to assemble a stable extracellular matrix that would have been normally produced. These changes were associated with the collapse of the typical blastula architecture and inhibition of the induction of mesoderm in the chick embryo. Induction of neuroectoderm required proteoglycans assembled before the initiation of gastrulation movements. However, sustained proteoglycan biosynthesis was required for the morphogenetic movements to form the neural tube and the rest of the embryonic axis. We also studied the spatiotemporal distribution pattern of link protein by immunofluorescence and immunoprecipitation and the role of this glycoprotein by blocking antibodies in the early chick embryo. The recognition of the link protein 1 (LP1, 48 kDa) and link protein 2 (LP2, 44 kDa) types was an important finding of our study. Link protein links several proteoglycans, such as aggrecan to hyaluronan, creating stable aggregates in the extracellular matrix and has a general function in the organization of the extracellular matrix. It is known that combinations of LP1 and LP2 create more stable complexes than the individual link protein molecule. This was also shown in our experiments, in that aggrecan (180kDa) co-precipitated with LP1 and LP2. Our immunofluorescent experiments showed that link protein expression was first detectable at the blastula stage (st. XIII) and its presence may be fundamental as the first extracellular matrix starts to assemble before the initiation of the first major cellular migrations during the gastrula stage. Link protein influorescence was strong in the cells ingressing through the primitive streak and in the migrating cells in embryos at stage HH3 (intermediate streak/mid-gastrula). At stage HH4 (definitive streak/late gastrula), link protein fluorescence was strong at the apical surface of the neural plate. At stage HH4-5 (head process), link protein fluorescence was strong at the apical surface of the neural folds, notochord and endoderm. At stage HH13 (19 somites), link protein fluorescence was intense in the encephalic vesicles, in the extracellular matrix, in the lumen of encephalic vesicles, intense in migrating neural crest cells, neural tube and in notochord, strong in gut lower wall, hard tube and dorsal aorta wall, intense in dermomyotome and strong in sclerotome in somites. By stage HH17 (29 somites), link protein fluorescence was strong in neuroepithelium and extracellular matrix in the lumen of the diencephalon, strong in neural crest cells, in the intraretinal space in the eye, in myocardium and endocardium, in dorsal aorta, in dermomyotome, the outer surface of pharyngeal arches wall of aortic arches and intense in thyroid rudiment. Inhibition of function of link protein by blocking antibodies showed that link protein was important in neuroepithelial tissue organization and neural tube closure, in normal differentiation of the neural tube to form the brain, in the morphogenesis of the heart tube, the dorsal aorta and gut and in somite epithelialization.

Πρωτεογλυκάνες

Γλυκοζαμινογλυκάνες

Συνδετική πρωτεΐνη

Πρώιμο έμβρυο

Εξωκυττάρια ύλη

Όρνιθα

581.756

Early development

Chick development

Proteoglycans

Glycosaminoglycans

Link protein

Extracellular matrix

Effects of Endogenous and Exogenous Hormones on the Female Breast : With Special Reference to the Expression of Proteoglycans

Hallberg, Gunilla

January 2011

This thesis aims to study the effects of endogenous and exogenous hormones and mammographic breast density (BD) on cellular markers in non-cancerous female breast tissue. Women on the waiting list for breast reduction plastic surgery were recruited (n = 79), and randomized to 2 months of hormone therapy or no therapy before surgery. The women had a mammogram and a needle biopsy 2 months before surgery and tissue samples were obtained at the operation. In premenopausal women, estrogen receptor (ER)α levels were associated with age (p = 0.0002), were similar in the follicular and luteal phases of the menstrual cycle and were higher in parous than in nulliparous women (p = 0.009). Current smokers had lower PR levels than non-smokers (p = 0.019). Women on oral contraception had lower ERα (p = 0.048) and PR (p = 0.007) levels than women in the follicular phase. The ERα levels did not differ significantly between postmenopausal estrogen and estrogen-progestogen users, but PR levels were lower among estrogen-progestogen users (p = 0.03). We found lower expression of the genes for decorin and syndecans 1 and 4 in the luteal phase than in the follicular phase, among parous women. Protein levels of the androgen receptor, syndecan-4 and decorin was lower in premenopausal women who were using oral contraceptives (OC) than in those in the follicular phase (p = 0.002 - 0.02), whereas no significant differences between OC use and the luteal phase were found. In premenopausal women, BD was negatively associated with age and body mass index but was similar for the menstrual phases. Breast density was associated with genetic expression of the androgen receptor and remained significant after adjustment for age (rs = 0.56; p = 0.04). After adjustement for age, breast density was also marginally associated with expression of the caspase 3 gene (0.55; 0.053). However, protein levels of caspase 3 was negatively associated (-0.61; 0.03).

breast tissue

proteoglycans

mammographic density

oral contraceptives

androgen receptor

proliferation

apoptosis

extracellular matrix

premenopausal

Obstetrics and gynaecology

Obstetrik och gynekologi

Matrix-Derived Microcarriers for Adipose Tissue Engineering

TURNER, ALLISON EUGENIA BOGART

01 December 2010

In vivo, adipose tissue demonstrates only a limited capacity for self-repair, and the long-term treatment of subcutaneous defects remains an unresolved clinical problem. With the goal of regenerating healthy tissues, many tissue-engineering strategies have pointed to the potential of implementing three-dimensional (3-D), cell-seeded scaffolds for soft tissue augmentation and wound healing. In particular, microcarriers have shown promise as both cell expansion substrates and injectable cell-delivery vehicles for these applications. However, limited research has investigated the engineering of tissue-specific microcarriers, designed to closely mimic the native extracellular matrix (ECM) composition. In this work, methods were developed to fabricate microcarriers from decellularized adipose tissue (DAT) via non-cytotoxic protocols. Characterization by microscopy confirmed the efficacy of the fabrication protocols in producing stable beads, as well as the production of a microporous surface topography. The mean bead diameter was 934 ± 51 μm, while the porosity was measured to be 29 ± 4 % using liquid displacement. Stability and swelling behavior over 4 weeks indicated that the DAT-based microcarriers were effectively stabilized with the non-cytotoxic photochemical crosslinking agent rose bengal, with only low levels of protein release measured within a simulated physiological environment. In cell-based studies, the DAT-based microcarriers successfully supported the proliferation and adipogenic differentiation of human adipose-derived stem cells (hASCs) in a dynamic spinner flask system, with a more favorable response observed in terms of adhesion, proliferation, and adipogenesis on the DAT-based microcarriers relative to gelatin control beads. More specifically, dynamically-cultured hASCs on DAT-based microcarriers demonstrated greater lipid loading, as well as higher glycerol-3-phosphate dehydrogenase (GPDH) activity, a key enzyme involved in triacylglycerol biosynthesis, at 7 days and 14 days in culture in an inductive medium. Overall, the results indicated that the DAT-based microcarriers provided a uniquely supportive environment for adipogenesis. Established microcarrier sterility and injectability further support the broad potential of these tissue-specific microcarriers as a novel, adipogenic, clinically-translatable strategy for soft tissue engineering. / Thesis (Master, Chemical Engineering) -- Queen's University, 2010-12-01 14:28:14.628

Adipose Tissue Engineering

Extracellular Matrix

Decellularized Adipose Tissue

Tissue-Specific Microcarrier

Adipose-Derived Stem Cell

Dynamic Cell Culture

Adipogenesis

Biomaterial

The von Hippel-Lindau protein and collagen IV alpha 2 : an insight into the mechanisms by which the von Hippel-Lindau protein regulates extracellular matrix assembly and function

Ramlal, Nishant.

January 2008

The von Hippel-Lindau (VHL) disease is a hereditary cancer syndrome that is transmitted in an autosomal dominant manner. The disease is characterized by the formation of highly angiogenic tumors in many organs but the main causes of mortality are renal cell carcinomas and hemangioblastomas. Mutations in the VHL protein are responsible for the pathogenesis of the disease. VHL associates with elongin Band C to form the VBC complex. The cullin 2 protein (CUL2) and ring box protein 1 (RBX1) also associate with the VBC complex to form an E3 ubiquitin ligase involved in the ubiquitination and subsequent degradation of the hypoxia inducible transcription factor (HIF2alpha). Mutations in VHL that abrogate its E3 ligase activity lead to increased levels ofHIF2alpha and the subsequent accumulation of pro-proliferative and pro-angiogenic HIF2alpha target genes. VHL also has an important function in the regulation of extracellular matrix (ECM) assembly which is independent of its HIF2alpha regulation pathway. VHL's regulation of ECM assembly was shown to have important consequences for tumor angiogenesis and cell invasion. It was shown to be necessary for the proper assembly of a fibronectin matrix and was most recently found to interact with collagen IV alpha 2 (COL4A2). The aim of this thesis is to further characterize the VHL-COL4A2 interaction. VHL was shown to interact directly and specifically to COL4A2 and is necessary for proper COL4A2 matrix assembly. The association of VHL with COL4A2 appears to be independent of its functions as an E3 ubiquitn ligase and CUL2 was identified as part of the VBC complex that associates with collagen IV (COL4). Furthermore, a strategy to identify the binding site of VHL on COL4A2 has been employed and is in progress. These experiments represent the beginning of investigations into the novel interaction between VHL and COL4A2.

Carcinoma, Renal Cell -- metabolism.

Extracellular Matrix -- metabolism.

Collagen Type IV -- metabolism.