Tesis sobre el tema "Decellularized matrix"
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Shah, Mickey. "Cardiac Repair Using A Decellularized Xenogeneic Extracellular Matrix". University of Akron / OhioLINK, 2018. http://rave.ohiolink.edu/etdc/view?acc_num=akron1542631193281779.
Texto completoMarengo, Kaitlyn A. "The Incorporation of Decellularized Cardiac ECM into Fibrin Microthreads". Digital WPI, 2017. https://digitalcommons.wpi.edu/etd-theses/843.
Texto completoYoung, Bethany M. "Novel Small Airway Model Using Electrospun Decellularized Lung Extracellular Matrix". VCU Scholars Compass, 2016. http://scholarscompass.vcu.edu/etd/4273.
Texto completoLi, Zhaoying. "Adaptive fabrication of biofunctional decellularized extracellular matrix niche towards complex engineered tissues". Thesis, University of Cambridge, 2017. https://www.repository.cam.ac.uk/handle/1810/270349.
Texto completoD'Angelo, Edoardo. "Decellularized colorectal cancer matrix as bioactive microenvironment for in vitro 3D cancer research". Doctoral thesis, Università degli studi di Padova, 2018. http://hdl.handle.net/11577/3426811.
Texto completoI modelli tumorali tridimensionali (3D) si stanno affacciando sul panorama scientifico con l’obiettivo primario di superare le limitazioni di colture cellulari convenzionali (2D) e modelli animali negli approcci di ricerca clinica. In questa tesi di dottorato, si descrive un innovativo approccio di ingegneria tissutale applicata alla ricerca oncologica mediante il quale, partendo da una biopsia tissutale decellularizzata, si genera un modello organo-tipico 3D bioattivo. Questo modello 3D, ricapitola, in vitro, l’ambiente ultra-strutturale del tessuto nativo come dimostrato da indagini istologiche, immunoistochimiche, di immunofluorescenza e di microscopia elettronica a scansione. L’analisi del proteoma e del secretoma mediante spettrometria di massa ha confermato una differente composizione stromale tra la mucosa colica sana decellularizzata e quella della controparte tumorale (CRC) in termini di proteine strutturali (Collagene 1A1, Collagene 1A2, Collagene 3A1) e di proteine secrete, come la Defensina alfa 3. Abbiamo dimostrato che le nostre matrici 3D mantengono le loro proprietà biologiche dopo il processo di decellularizzazione: mediante la CAM, abbiamo osservato un decremento del potenziale angiogenico della matrice decellularizzata di CRC comparata con la mucosa colica sana, causata da un effetto diretto della Defensina alfa 3. Inoltre, abbiamo dimostrato che dopo 5 giorni di ricellularizzazione con cellule HT-29 (linea stabilizzata di cancro del colon), le matrici tumorali 3D (comparate con le rispettive mucose coliche sane ed il metodo di coltura 2D) hanno indotto una sovra-espressione di IL-8, una chemochina a valle del pathway della Defensina alfa 3, che gioca un ruolo molto importante nella crescita e proliferazione tumorale. In conclusione, avendo dimostrato la capacità dei delle nostre matrici acellulari 3D di mucosa colica sana e CRC di mimare gli stimoli ultra-strutturali e biologici dei rispettivi tessuti nativi, crediamo che questo approccio possa essere un efficace strumento per migliorare il livello delle ricerche precliniche e nei test di screening di farmaci.
KC, Pawan. "Development of a Cardiac Patch with Decellularized Myocardial Tissue and Stem Cells". University of Akron / OhioLINK, 2019. http://rave.ohiolink.edu/etdc/view?acc_num=akron1555413717363006.
Texto completoHansen, Ryan. "Functional and Structural Analysis of Decellularized Liver Tissue Matrix, with Potential Applications in Cancer Tissue Engineering". Case Western Reserve University School of Graduate Studies / OhioLINK, 2017. http://rave.ohiolink.edu/etdc/view?acc_num=case1498650461817088.
Texto completoMiyauchi, Yuya. "A novel three-dimensional culture system maintaining the physiological extracellular matrix of fibrotic model livers accelerates progression of hepatocellular carcinoma cells". Kyoto University, 2018. http://hdl.handle.net/2433/232113.
Texto completoTrignol, Aurélie. "The extracellular matrix as a biomaterial to optimize skeletal muscle regeneration". Thesis, Lyon, 2019. http://www.theses.fr/2019LYSE1029.
Texto completoSkeletal muscle exhibits high capacity for regeneration after an injury that relies on resident stem cells. Muscle regeneration is tightly regulated by both the immune response and other resident cells, as well as by cues from the local extracellular matrix (ECM), contributing to a coordinated repair process. Muscle ECM is a network of structural macromolecules with a large majority of collagens and trophic molecules such as glycosaminoglycans (GAGs). In the skeletal muscle tissue, ECM was overlooked due to its complex organization making investigations difficult. Muscle regenerative ability can be overtaken in large muscle wasting, such as in volumetric muscle loss (VML), leading to fibrosis formation and chronic inflammation. This type of injury predominantly occurs in traumatology and in war-wounded patients, with functional disability despite an optimal treatment. The use of biomaterials could provide the biochemical and physical cues that are missing in this pathologic repair. In this work we have focused on obtaining a biomaterial composed of skeletal muscle ECM. We have tested several decellularization protocols both to preserve the three-dimensional architecture of the muscle ECM and to completely remove cell components in order to avoid a deleterious immune response after implantation. However, the protocol did not allow the preservation of trophic molecules such as GAGs, in the scaffold.“ReGenerating Agents” (RGTA®) are functionally analogous of GAGs with a crucial property to resist enzymatic degradation. They function to restore a proper microenvironment for tissue healing with already a clinical application in skin and corneal repair. We have explored the effects of RGTA® in muscle regeneration using an in vivo model in mouse. At early time of regeneration (day 8), we performed histologic analysis. We showed that regenerating myofibers contained more nuclei in the treated animals, in favor of an increase of progenitor fusion, which has been validated in vitro in myogenic cultures. The number of capillaries was higher in favor of a better angiogenesis. Lipid droplets, a marker of impaired regeneration, were reduced by RGTA® administration. At later time of regeneration (day 28), capillary number was still improved in favor of a durable effect of RGTA® on angiogenesis. RGTA® could be incorporated into biomaterials and are particularly resistant in an inflammatory environment, such as that occurring after a VML injury. Chemokines and growth factors could also be added in ECM-based scaffolds to promote the migration of progenitors that are essential for myofiber neoformation. Therapeutic efficacy of these optimized biomaterials will require to be evaluated in an in vivo model of VML
Pouliot, Robert A. "DEVELOPMENT AND CHARACTERIZATION OF LUNG DERIVED EXTRACELLULAR MATRIX HYDROGELS". VCU Scholars Compass, 2016. http://scholarscompass.vcu.edu/etd/4465.
Texto completoFrench, Kristin Marie. "Microenvironmental stimulation of cardiac progenitor cells". Diss., Georgia Institute of Technology, 2015. http://hdl.handle.net/1853/53867.
Texto completoKuaha, Kunnika. "Environments for zonal cartilage tissue engineering". Thesis, Queensland University of Technology, 2015. https://eprints.qut.edu.au/81992/1/Kunnika_Kuaha_Thesis.pdf.
Texto completoDikina, Anna D. "ENGINEERED CARTILAGE COMPOSED OF MESENCHYMAL STEM CELL CONDENSATES AS MODULES WITH CONTROLLED SHAPE AND SIZE FOR MULTI-TISSUE TYPE CONSTRUCTS, AS MATERIALS FOR CHONDROCONDUCTIVE SCAFFOLDS AND AS MECHANORESPONSIVE TISSUES". Case Western Reserve University School of Graduate Studies / OhioLINK, 2016. http://rave.ohiolink.edu/etdc/view?acc_num=case1459254069.
Texto completoGhanavi, Parisa. "Effects of cartilage dust on cartilage formation in in vitro and in ectopic in vivo models". Thesis, Queensland University of Technology, 2016. https://eprints.qut.edu.au/101499/1/Parisa_Ghanavi_Thesis.pdf.
Texto completoLesieur, Romane. "Ingénierie tissulaire de l'oesophage". Electronic Thesis or Diss., Bordeaux, 2024. http://www.theses.fr/2024BORD0020.
Texto completoUpon removal of a portion of the esophagus, the restoration of the digestive continuity involves the surgical creation of an intrathoracic esophagogastric anastomosis. However, postoperative complications such as lung impairments, fistulas, strictures, graft necrosis, and gastroesophageal reflux are reported. The enhancement of surgical procedures for esophageal replacement has made promising progress by the development of a substitute through tissue engineering that utilizes a decellularized biological esophageal matrix (DEM). The primary objective of this study was to optimize the design of porcine DEM and characterize its biological and mechanical properties. The secondary objective was to cellularize DEM using readily available immune-privileged human mesenchymal stromal cells derived from Wharton's jelly (hMSCs-WJ).Esophageal decellularization was performed according to a protocol based on the dynamic perfusion of chemical and enzymatic solutions through the organ lumen. Histological analysis and residual DNA quantification of the DEM were conducted to determine the efficiency of the decellularization protocol. The ultrastructure of the DEM was analyzed using immunohistochemical (IHC) labeling, and the composition of the extracellular matrix (ECM) protein content was described by mass spectrometry. In-vitro cytotoxicity tests of DEM were conducted following ISO 10993-5 standards. The evaluation of suture retention strength, tensile strength, and bursting pressure of DEM aimed to describe the mechanical behavior of the substitute for clinical use.hMSCs-WJ used for DEM cellularization were extracted from human umbilical cords, and their flow cytometry profiling confirmed the purity of the cell population. The immune response of hMSCs-WJ was quantified after co-culture with peripheral blood mononuclear cells (PBMCs). PBMCs phenotyping assessed the expression of immune markers in contact with hMSCs-WJ, while enzyme-linked immunosorbent assay (ELISA) quantified cytokine release. The proposed DEM cellularization strategy involved the development of cell sheets from hMSCs-WJ. The validation of the cell sheet production protocol involved the characterization of the cellular phenotype by IHC analysis, and the mechanical study of the sheets measured their resistance to perforation.The absence of cellular content and residual DNA quantification in DEM confirmed the efficacy of decellularization according to current validation criteria. The ultrastructure and biological components of the ECM were preserved, and proteomic analysis highlighted protein complexity. Decellularization treatment did not induce DEM toxicity, and the mechanical behavior of DEM was suitable for its use as an esophageal substitute.Culturing hMSCs-WJ as cell sheets promoted the cellularization of the DEM. Once seeded, the sheets retained their cellular phenotype and immune-privileged characteristics. In-vitro tissue remodeling was visible, along with the formation of a new ECM produced by hMSCs-WJ.Characterization of the obtained DEM offered biological complexity and favorable mechanical behavior for its use as an esophageal substitute. DEM was cellularizable with hMSCs-WJ cell sheets, potentially promoting tissue integration and remodeling
Blaudez-Prat, Fanny. "Harnessing the native extracellular matrix to achieve periodontal regeneration". Thesis, Griffith University, 2021. http://hdl.handle.net/10072/405629.
Texto completoThesis (PhD Doctorate)
Doctor of Philosophy (PhD)
School of Medicine & Dentistry
Griffith Health
Full Text
Trevisan, Caterina. "Decellularised matrix and stem cells to rebuild damaged muscle: an innovative approach of regenerative medicine". Doctoral thesis, Università degli studi di Padova, 2018. http://hdl.handle.net/11577/3424881.
Texto completoIl muscolo scheletrico ha un’intrinseca capacità rigenerativa grazie all’attività svolta dalle cellule satelliti. In presenza di danni estesi però tali capacità rigenerative possono essere compromesse. In queste situazioni un approccio di medicina rigenerativa può costituire una soluzione promettente. Questo progetto è focalizzato sull’ernia diaframmatica congenita, patologia neonatale caratterizzata da un’incompleta formazione del diaframma, con incidenza di 1 su 2,500-3,000 neonati e un alto tasso di mortalità. Attualmente, il materiale più usato per il riparo dell’ernia è il politetrafluoroetilene (Gore-Tex[R]), tuttavia il suo utilizzo può causare effetti collaterali, come la ricorrenza dell’ernia e malformazioni della cassa toracica. Grande interesse è stato rivolto a soluzioni di ingegneria tissutale, come l’uso di matrici extracellulari decellularizzate. Quando trapiantate in vivo esse riescono ad integrarsi in maniera fisiologica con il tessuto nativo e reclutano cellule staminali, modulando il loro comportamento verso un processo rigenerativo. Lo scopo di questo progetto è caratterizzare un approccio di ingegneria tissutale basato sull’uso di matrici decellularizzate come soluzione alternativa all’attuale metodo per il riparo l’ernia. L’obiettivo è chiudere il difetto sul diaframma ed indurne la rigenerazione. In vivo, abbiamo creato il primo modello murino di ernia diaframmatica e abbiamo riparato il difetto usando una matrice decellularizzata. Il politetrafluoroetilene espanso (ePTFE) è stato usato come controllo. Il trapianto di matrici decellularizzate non ha causato rigetto o ricorrenza dell’ernia, a differenza degli animali trattati con ePTFE. Inoltre, ePTFE ha indotto una reazione da corpo estraneo che era completamente assente negli animali trattati con la matrice biologica. Ci siamo poi concentrati su tre aspetti fondamentali della rigenerazione: la formazione di nuovo tessuto muscolare, angiogenesi e re-innervazione. In tutti i casi la matrice biologica ha dimostrato di essere migliore di quella sintetica. La prolungata attivazione della rigenerazione muscolare insieme ai processi angiogenici e di re-innervazione indotti dalla matrice extracellulare si sono tradotti in un generale miglioramento delle funzioni diaframmatiche rispetto a quanto ottenuto negli animali con ePTFE. Nonostante i risultati positivi, la matrice extracellulare non era in grado di indurre una completa rigenerazione del difetto. Perciò abbiamo messo a punto una tecnica di ingegneria tissutale per ricreare in vitro tessuti diaframmatici ricellularizzando matrici decellularizzate con precursori muscolari umani. Lo scopo era di ottenere dei possibili costrutti paragonabili al muscolo scheletrico da usare per il riapro dell’ernia in modo da stimolare maggiormente la generazione di nuove miofibre e migliorare la funzionalità tissutale. I precursori muscolari umani erano in grado di attecchire sulla matrice decellularizzata, di ripopolarla in tutto il suo spessore e di differenziare dando origine a miotubi attivi metabolicamente. Inoltre, una sottopopolazione di cellule manteneva le caratteristiche tipiche delle cellule satelliti, dimostrando di saper rispondere in vitro ad un danno. Visti i risultati positivi ottenuti usando la matrice decellularizzata, il passaggio successivo per avvicinarsi alla cinica è rappresentato dall’utilizzo di modelli animali più grandi. Inoltre, la ricellularizzazione potrebbe essere migliorata grazie a stimolazione meccanica, a sistemi di perfusione e all’aggiunta di altri tipi cellulari (cellule endoteliali e neurali) con lo scopo di ottenere un costrutto più completo per possibili applicazioni pre-cliniche e cliniche. Infine, le due parti di questo progetto potrebbero essere unite in futuro riparando il difetto sul diaframma usando matrici biologiche ricellularizzate al fine di favorire la rigenerazione e ridurre gli svantaggi legati all’uso delle matrici sintetiche.
Prewitz, Marina. "Decellularised extracellular matrices as instructive microenvironments for bone marrow derived stem cells". Doctoral thesis, Saechsische Landesbibliothek- Staats- und Universitaetsbibliothek Dresden, 2012. http://nbn-resolving.de/urn:nbn:de:bsz:14-qucosa-86334.
Texto completoBrew, Leah. "Development of a crosslinkable hydrogel derived from placental tissue". Thesis, Queensland University of Technology, 2019. https://eprints.qut.edu.au/127976/1/Leah_Brew_Thesis.pdf.
Texto completoXu, Yi-yu y 許乙雨. "HGF/Heparin-immobilized Decellularized Liver Matrix for Liver Tissue Engineering". Thesis, 2016. http://ndltd.ncl.edu.tw/handle/67194164724342289200.
Texto completo國立臺灣大學
生物產業機電工程學研究所
104
In order to overcome the shortage of organ donation and injury of patients after partial hepatectomy (PH) treatment, we aimed at developing a liver film for hepato-cytes regeneration through liver tissue engineering. In this study, a HGF/heparin-immobilized decellularized liver matrix film (HGF/heparin complex coated on DLM film) was developed for hepatocytes regeneration in liver injury. In the result, (1) the amounts of immobilized heparin on DLM film was 30 μg/cm2 when the initial heparin concentrations were 1 mg/mL. (2) The relative cell viability and albu-min synthesis of the hepatocytes on HGF/heparin-immobilized DLM film was 20-30 % and 20 % superior than on normal dish at 3 days of culture, respectively. (3) The lactate dehydrogenase activity of the D-galactosamine-induced injury of hepatocytes on hepa-rin-immobilized DLM film cultures was 10 milliunits/mL, which was 50 % lower than that in the D-galactosamine-induced injury of hepatocytes on normal dish cultures, and albumin synthesis can recover to the same level as non-toxic hepatocytes cultured on normal dish. The HGF/heparin-immobilized DLM film showed highly potential in maintaining hepatocyte culture and also in repairing injured hepatocytes from D-galactosamine. It is believed that this HGF/heparin-immobilized DLM film has promising potential for hepatocyte transplantation, and could be applied for future use in liver tissue engineering.
Lee, Kuang-Min y 李光閔. "Decellularized Liver Matrix as Substrates for Hepatocyte Rescue in Acute Liver Toxicity". Thesis, 2018. http://ndltd.ncl.edu.tw/handle/cye24k.
Texto completo國立臺灣大學
生物產業機電工程學研究所
106
More and more scholars believe that the pathological changes of cirrhosis are a series of gradual clinical stages rather than a single disease. In the beginning, chronic hepatitis can lead to hepatocyte necrosis, and then if it is not controlled in time, it will evolve into liver fibrosis, which eventually causes the liver to become hard and form liver cirrhosis. However, such a cirrhosis process is irreversible, and the current treatment can only stop or slow down the damage of the liver. In addition, cirrhosis has long been one of the common causes of death in the adult population of the world, so the treatment of cirrhosis has been studied in the field of biomedicine. The previous study shows that the decellularized liver matrix-film can promote the recovery of D-galactosamine-induced injured hepatocytes. Therefore, in this study, we proposed a novel hypothesis that the injection of liver extracellular matrix into the fibrotic liver via the hepatic portal vein, may be an effective treatment for patients with cirrhosis. First, we developed a three-dimensional porous biomaterial by mixing liver extracellular matrix (LECM) and gelatin-hydroxyphenylpropionic acid (Glt-HPA). Then we cultured injured hepatocytes (Treated by GaIN, CHCl3, CCl4, repesctively) in the above-mentioned biomaterials with LECM-containing medium, the viability and functionality of injured hepatocytes was determined thereafter. In the result: (1) After 3 days culture of primary rat hepatocytes in Glt-HPA:LECM = 4:6, the secretion of albumin was about 50% and 20% higher than that in Glt-HPA:LECM = 5:5 and Glt-HPA (without LECM), separately; (2) After 5 days culture, the albumin secretion of the D-galactosamin-induced injury of hepatocytes in Glt-HPA-LECM (4:6) with the LECM-containing medium cultures was 2 times superior to that in Glt-HPA without the LECM-containing medium cultures (Negative). Also, the lactate dehydrogenase (LDH) activity of the GaIN-induced injury of hepatocytes in Glt-HPA-LECM (4:6) with the LECM-containing medium cultures was reduced to be similar to the non-injured hepatocytes in Glt-HPA with normal medium cultures (Blank). (3) After 5 days culture, the albumin secretion of the CHCl3-induced injury of hepatocytes in Glt-HPA-LECM (4:6) with the LECM-containing medium cultures was 1 time superior to Negative condition. Also, the LDH activity of the GaIN-induced injury of hepatocytes in Glt-HPA-LECM (4:6) with the LECM-containing medium cultures was reduced to be lower than Blank. (4) After 5 days culture, the albumin secretion of the CCl4-induced injury of hepatocytes in Glt-HPA-LECM (4:6) with the LECM-containing medium cultures was 12 % superior to Negative condition. Also, the LDH activity of the GaIN-induced injury of hepatocytes in Glt-HPA-LECM (4:6) with the LECM-containing medium cultures was reduced to be similar to Blank. In summary, Glt-HPA-LECM as a three-dimensional porous substrate showed high potential in increasing cell viability and albumin secretion of the primary hepatocyte. Furthermore, the LECM-containing medium did have the effect of restoring the activity of damaged hepatocytes and delaying the toxicity. Such results are believed to be of great significance for the future treatment of clinical cirrhosis and liver tissue engineering.
Tseng, Chen-Han y 曾琛涵. "Application of Decellularized Adipose Tissue/Silk Fibroin Matrix and Microspheres in Adipose Tissue Engineering". Thesis, 2013. http://ndltd.ncl.edu.tw/handle/47831236297898866830.
Texto completo國立臺灣大學
醫學工程學研究所
101
The soft tissue defects caused by congenital malformation, trauma, tumor removal and other various reasons affect the patient''s psychology and interpersonal relationship, so it has been gaining popularity for Plastic and Reconstructive Surgery. Due to advances in medicine, the emphasis on the requirements of the quality of medical care and physical appearance is increasing, and it also increases the demand for medical cosmetic. However, current challenge of adipose tissue engineering failed to maintain volume of adipose after transplantation, so it is important to find the soft fillers that have both functionality and aesthetics. In the study, we used decellularized porcine adipose matrix and silk fibroin as composite materials for scaffolds. The loss of the ECM content mixed in the scaffolds was slowed down by cross-linking. Eighty percentage collagen and thirty percentage GAG contents were retained after removing most cells and lipids from porcine adipose tissue. These bioactive contents have been proved to induce cell differentiation, and hydrolyzed silk fibroin also has the ability to promote cell proliferation. In addition, both of these materials have high biocompatibility, and they can increase the overall mechanical properties after blending. In vitro experiments, we observed that 3T3-L1 and adipose stem cells attached to the composite scaffolds successfully, and their GAG content increased 30 % to 45 % after culture several days, and there was remarkable difference between the composite scaffolds and the silk fibroin scaffolds. In vivo experiments, we observed that adipose matrix-silk fibroin composite microspheres were more effective to promote adipose stem cells proliferation and differentiation than silk fibroin microspheres. There are great potentials for the application of these hybrid materials in dermal fillers and soft tissue regeneration.
Fuetterer, Lydia. "Optimization and Biological Characterization of Decellularized Adipose Tissue Scaffolds for Soft Tissue Reconstruction". Thesis, 2014. http://hdl.handle.net/1974/8600.
Texto completoThesis (Master, Chemical Engineering) -- Queen's University, 2014-01-30 12:25:22.044
Lin, Yu-Heng y 林鈺恆. "The Effects of Decellularization Treatment on the Components,Structure and Cell Growth of A Decellularized Vascular Matrix". Thesis, 2017. http://ndltd.ncl.edu.tw/handle/22003231643759188025.
Texto completo國立陽明大學
生物醫學工程學系
105
Decellularized blood vessels provide better biocompatibility than synthetic scaffolds. Nevertheless, decellularization tends to disrupt ultrastructure and the components of ECM, which in turn affects the mechanical properties and the ability of cell proliferation and migration in the scaffolds, especially for treatments by chemical agents. This study investigates the effects of ultrasound, perfusion and different medium for decellularization processes on the preservation of ECM components, DNA removal, and the viability of seeded cells on the decellularized scaffolds. Many kinds of scaffolds with various decellularization levels were tested for cell seeding to confirm whether the scaffolds are suitable for cell growth. The quantification of ECM components and DNA are measured by biochemical assay. The ultrastructure of the scaffold were observed by SEM and by histological staining. The growth of cells are examined by the reduction level of alamarblue and Live/Dead staining. The results show that ultrasound treatment together with medium perfusion can promote decellularization efficiency. Using a hydrophilic solution of Pluronic C as perfusion medium, more than 85 % of the nucleus can be removed within 3 days, compared to 50% of nucleus removal rate of use water as a perfusion medium.The decellularized matrix treated by pluronic C solution was also less damaged. For cell seeding tests on flat scaffolds, it is found that the scaffold treated by pluronic solutions show best results for cell proliferation compared to scaffolds which are either with insufficient DNA removal rate or with the ECM structure too severely damaged scaffolds treated by Pluronic B and C is with a lot of nucleus removed meanwhile with some matrix retained. This might explain its superior performance observed in the cell seeding tests. This is possibly due to the fact that using a Pluronic solution as decellularization medium can effecting remove DNA while keep the composition and ultrastructure of the ECM properly preserved.
Kao, Yun-Chu y 高韻筑. "The Effects of Decellularization Treatment on the Components, Structure and Cell Growth of A Decellularized Vascular Matrix". Thesis, 2016. http://ndltd.ncl.edu.tw/handle/2dzb6y.
Texto completo國立陽明大學
生物醫學工程學系
104
Decellularized blood vessels provide better biocompatibility than synthetic scaffolds. Nevertheless, decellularization tends to disrupt ultrastructure and the components of ECM, which in turn affects the mechanical properties and the ability of cell proliferation and migration in the scaffolds, especially for treatments by chemical agents. This study investigates the effects of ultrasound and perfusion for decellularization processes on the preservation of ECM components, DNA removal, and the viability of seeded cells on the decellularized scaffolds. Three kinds of scaffolds with various decellularization levels were tested for cell seeding to confirm whether the scaffolds are suitable for cell growth. The quantification of ECM components and DNA are measured by biochemical assay. The growth of cells are examined by the reduction level of alamarblue and observed by SEM and Live/Dead staining. The results show that ultrasound with perfusion can effectively promote decellularization efficiency. Using NaOH or PS-1 as perfusion medium, the nucleus can be removed for more than 70 % within 3 hours, which would take for at least 5 days by using regular chemical agents, such as Triton X-100. Together with some post processing, like treated by DNase/RNase, could remove more than 98% nucleus and with the ECM ultrastructure better preserved. For cell seeding tests on flat scaffolds, it is found that the TX-100 scaffold shows best results for cell attachment. Compared to scaffolds which are either with insufficient DNA removal rate or with the ECM structure too severely damaged, scaffolds treated by TX-100 is with 80% nucleus removed meanwhile with some matrix retained. This might explain its superior performance observed in the cell seeding tests. It is also found that the cell growth is poor for static cultured tubular cell seeding scaffolds. To improve cell growth, the mass transfer problem needed to be resolved.
CASTALDO, CLOTILDE. "Development of a biological scaffold from adult human skin for cardiovascular repair and regeneration". Doctoral thesis, 2019. http://hdl.handle.net/11573/1252299.
Texto completoTURNER, ALLISON EUGENIA BOGART. "Matrix-Derived Microcarriers for Adipose Tissue Engineering". Thesis, 2010. http://hdl.handle.net/1974/6214.
Texto completoThesis (Master, Chemical Engineering) -- Queen's University, 2010-12-01 14:28:14.628
Matoug-Elwerfelli, M., H. Nazzal, E. M. Raif, Stacy-Paul Wilshaw, F. Esteves y M. Duggal. "Ex-vivo recellularisation and stem cell differentiation of a decellularised rat dental pulp matrix". 2020. http://hdl.handle.net/10454/18375.
Texto completoImplementing the principles of tissue engineering within the clinical management of non-vital immature permanent teeth is of clinical interest. However, the ideal scaffold remains elusive. The aim of this work was to assess the feasibility of decellularising rat dental pulp tissue and evaluate the ability of such scaffold to support stem cell repopulation. Rat dental pulps were retrieved and divided into control and decellularised groups. The decellularisation protocol incorporated a low detergent concentration and hypotonic buffers. After decellularisation, the scaffolds were characterised histologically, immunohistochemistry and the residual DNA content quantified. Surface topography was also viewed under scanning electron microscopy. Biocompatibility was evaluated using cytotoxicity assays utilising L-929 cell line. Decellularised scaffolds were recellularised with human dental pulp stem cells up to 14 days in vitro. Cellular viability was assessed using LIVE/DEAD stain kit and the recellularised scaffolds were further assessed histologically and immunolabelled using makers for odontoblastic differentiation, cytoskeleton components and growth factors. Analysis of the decellularised scaffolds revealed an acellular matrix with histological preservation of structural components. Decellularised scaffolds were biocompatible and able to support stem cell survival following recellularisation. Immunolabelling of the recellularised scaffolds demonstrated positive cellular expression against the tested markers in culture. This study has demonstrated the feasibility of developing a biocompatible decellularised dental pulp scaffold, which is able to support dental pulp stem cell repopulation. Clinically, decellularised pulp tissue could possibly be a suitable scaffold for use within regenerative (reparative) endodontic techniques.
Prewitz, Marina. "Decellularised extracellular matrices as instructive microenvironments for bone marrow derived stem cells". Doctoral thesis, 2011. https://tud.qucosa.de/id/qucosa%3A25975.
Texto completoSantos, Pedro Miguel Gameiro dos. "Decellularized fetal muscle bioscaffolds as a tool to study the role of Laminin-211 in the MuSC niche". Master's thesis, 2021. http://hdl.handle.net/10451/48088.
Texto completoA matriz extracelular é o componente não celular de todos os tecidos. Esta estrutura detém não só funções de suporte das células, mas também é um importante mediador de todos os processos biológicos necessários para o correto desenvolvimento dos organismos assim como na manutenção da homeostase. Cada tecido ou órgão apresenta uma matriz extracelular com uma composição distinta. Várias moléculas constituem esta matriz, e é a natureza modelar destas que permite a formação de estruturas com diferentes propriedades mecânicas e bioquímicas, permitindo uma grande diversidade funcional. O desenvolvimento de uma matriz extracelular específica para cada tecido resulta da interação entre células e microambiente, sendo um processo altamente dinâmico e em constante remodelação. A matriz extracelular pode ser dividida em duas principais categorias: a matriz intersticial e as membranas basais. A matriz intersticial é principalmente associada ao tecido conjuntivo e é constituída por proteínas como os colagénios intersticiais, a elastina, fibronectina e proteoglicanos. Estas moléculas atuam com substrato para as células, mas estão envolvidas também na regulação da adesão, migração, proliferação e diferenciação celular. As membranas basais localizam-se mais proximamente das células e devido a isso têm grande influência em como estas interpretam o seu meio. As membranas basais são constituídas essencialmente por colagénio tipo IV, lamininas, nidogénio e perlecan. À semelhança da matriz intersticial, regulam também processos celulares como a proliferação, diferenciação, migração, polarização e sobrevivência ou apoptose. As células recebem informação acerca do seu meio exterior através de recetores membranares. A matriz extracelular é um fator chave para o correto desenvolvimento de todos os tecidos. A miogénese do músculo esquelético é um exemplo de um processo altamente dependente de sinalização da matriz extracelular. O desenvolvimento do músculo inicia-se cedo durante a embriogénese dos vertebrados com a formação do sómitos. Estas estruturas crescem e desenvolvem-se originando o dermomiótomo. O dermomiótomo possui os percursores miogénicos que irão dar origem ao músculo esquelético. No estádio 8.5 o dermomiótomo “desepiteliza” e células musculares estaminais migram para o espaço abaixo dando origem ao miótomo, iniciando-se assim a miogénese do músculo esquelético. No miótomo desenvolvem-se os mioblastos que proliferam e fundem dando origem aos miotubos. Nesta etapa tanto a presença de fibronectina como de lamininas é crucial para o correto desenvolvimento destas estruturas. No miótomo, as células presentes sofrem diferentes processos reorganizacionais transformando-se em miofibras primárias. A miogénese primária ou embrionária ocorre entre o estádio 11.5 até ao 14.5, a partir do qual se inicia a miogénese secundária ou fetal que decorrer até ao nascimento. Esta fase de miogénese é caracterizada pelo aparecimento das miofibras. Durante a miogénese primária formam-se as miofibras primárias que estabelecem o padrão corporal do músculo esquelético. A miogénese secundária é caracterizada pelo aumento da massa muscular. Este crescimento pode ser dividido em duas fases: células musculares estaminais (Pax7-positivas) podem produzir novos mioblastos que fundem entre si (crescimento por hiperplasia) contribuindo para a formação de miofibras secundárias enquanto outras se diferenciam e fundem com as miofibras primárias levando ao seu crescimento (hipertrofia mediada por células). A ação conjunta destas duas fases leva a um crescimento tanto em número como em tamanho das fibras musculares. Para que este processo ocorra corretamente a presença de laminina-211 parece ser fulcral. A contribuição da matriz extracelular é muito importante para o desenvolvimento dos tecidos e devido a isso, quando esta se encontra perturbada, pode dar origem a diversas patologias. Quando a laminina-211 não está presente o desenvolvimento esquelético muscular é severamente afetado, dando origem à distrofia muscular congénita merosina-negativa (MDC1A), uma das distrofias musculares mais comuns na Europa. Esta condição é provocada por mutações no gene LAMA2, responsável pela codificação da cadeia α2 da laminina-221 e -221 levando à produção de uma proteína não funcional. Os portadores desta doença manifestam diversos sintomas como atrofia e hipotonia muscular, mas também o sistema nervoso parece ser afetado, entre outros sistemas de órgãos. Não existem ainda tratamentos eficazes para esta doença e a maioria do conhecimento existente é proveniente de informação pós-natal, não se conhecendo ainda o momento em que se origina esta condição nem os processos moleculares por detrás da mesma. Estudos anteriores no nosso laboratório revelaram que a origem desta doença poderá ser in utero durante a miogénese secundária, onde a ausência de laminina-211 parece levar a uma depleção precoce das células musculares estaminais, não permitindo que ocorra o crescimento das massas musculares. Este trabalho tem como objetivo acrescentar conhecimento acerca das dinâmicas celulares durante o desenvolvimento fetal desta doença e para isso foi utilizado o modelo de ratinho dyW/ dyW durante o estádio fetal 18.5. Inicialmente começou-se por caracterizar a composição da matriz extracelular de ratinhos normais e distróficos, recorrendo a imuno-histoquímica e western blot. Esta comparação parece demonstrar que a ausência de laminina-211 nos ratinhos distróficos poderá afetar também outras proteínas presentes na matriz extracelular. O colagénio I sofre um aumento de cerca de 3 vezes nos ratinhos mutantes. O aumento desta proteína está documentado em ratinhos após o nascimento e em associação a fibronectina, é responsável por processos inflamatórios e formação de tecido fibrótico (um dos principais sintomas da MDC1A), o que poderá indicar que este sintoma, apesar de não ser observado morfologicamente no feto, poderá iniciar-se ainda in utero. No entanto, contrariamente ao expectável, os nossos resultados parecem indicar que existe uma menor quantidade de fibronectina nos ratinhos mutantes. As lamininas parecem também sofrer uma diminuição em quantidade. Após a caracterização da matriz extracelular de ambos os genótipos, propusemo-nos criar um sistema que permitisse estudar a contribuição relativa das duas fontes de laminina-211 (células e matriz extracelular) para o normal desenvolvimento do músculo esquelético. Esta proteína já está presente no nicho das miofibras quando a nova onda de células musculares estaminais entra no programa miogénico. No entanto, estas células parecem também ser capazes de produzir laminina-211 e assim contribuir para a construção do seu nicho. O conhecimento da contribuição relativa de cada uma destas fontes para o normal desenvolvimento do músculo esquelético poderá permitir identificar e desta forma desenvolver terapias para determinados momentos fulcrais para este processo. A descelularização é uma técnica que permite a produção de matrizes extracelulares com uma composição semelhante à do tecido nativo sem a presença de células. Estas matrizes mantêm assim não só a composição química, mas também as suas propriedades mecânicas, o que permite uma maior aproximação ao in vivo, apresentando assim várias aplicações terapêuticas. Utilizando esta técnica testámos diferentes protocolos com objetivo de produzir uma matriz descelularizada que mantivesse uma composição semelhante à do músculo inteiro, mas sem células presentes. A utilização do detergente SDS a baixa concentração, em conjunto com outros compostos, permitiu manter na matriz extracelular a maioria das proteínas testadas (especialmente laminina-211) e apenas uma reduzida quantidade de conteúdo celular. No entanto, as matrizes descelularizadas parecem apresentar uma ligeira diminuição na quantidade de proteínas presentes após o protocolo de descelularização. Posteriormente estas matrizes descelularizadas foram cultivadas com células C2C12. Estas células são mioblastos pertencentes a uma linha celular imortalizada originada a partir de células satélite pós-lesão de ratinho, apresentando assim características de células musculares estaminais. A contagem do número de células, após 8 dias em ambos os genótipos, permitiu chegar à conclusão que estas matrizes eram capazes albergar e manter estas células. Os nossos resultados parecem mostrar uma tendência para a presença de um menor número de células nas matrizes descelularizadas mutantes, demonstrando que a ausência de laminina-211 poderá de alguma forma dificultar a adesão ou proliferação das células C2C12. Estas células são capazes de infiltrar nas matrizes e até de contrai-las, mudando-lhes a forma. As células parecem também adquirir propriedades características de células musculares diferenciadas (alinhamento e afunilamento dos núcleos) assim como também produzem e secretam diferentes proteínas da matriz extracelular como fibronectina, lamininas e especialmente laminina-211. Estes resultados podem indicar que células poderão ter a capacidade de recuperar um nicho incompleto como é o caso da MDC1A. Este trabalho permitiu estabelecer um sistema in vitro, que quando otimizado, poderá representar uma nova abordagem para a aquisição de conhecimento acerca das dinâmicas moleculares desta doença durante os estádios fetais, e no futuro, ajudar no desenvolvimento de novas terapias.
The extracellular matrix (ECM) plays a crucial role in myogenesis and when disrupted can originate various conditions. When laminin-211 is not present skeletal muscle development is severely impaired leading to Merosin-deficient congenital dystrophy type 1A (MDC1A). Previous works in our group shed some light on the possible origin of this condition occurring during in utero development, when secondary myogenesis is undergoing. The absence of laminin-211 seems to lead to an early depletion of the muscle stem cell pool impairing myogenesis. In this work we used embryonic day (E) 18.5 fetus of the dyW/dyW mice model and characterized the main ECM proteins in both wild-type and mutant mice. The comparison of both genotypes showed that the absence of laminin α2 may somehow perturb other proteins expression. After characterization, we aimed to produce a system that allowed to study the relative contribution of both sources of laminin-211 (ECM and cells) during skeletal muscle development. We decellularized fetal skeletal muscle, producing a decellularized matrix (dECM) with a similar composition to the native tissue (most importantly laminin-211) but depleted of cellular con-tent. A low concentration SDS treatment, among other component, was optimized to better fulfill this compromise. The dECMs of both genotypes were seeded with C2C12 myoblasts and the cell number and protein production were analyzed. Our results show a tendency to have fewer cells in the mutant dECMs, suggesting that the absence of laminin-211 may difficult C2C12 cells adhesion/proliferation. These cells were able to colonize and contract the dECMs and express different ECM proteins, including laminin-211, opening the possibility for cells to be able to recover a defective niche. This work results in the production of an in vitro model representing a possible novel approach to better understand the molecular dynamics of MDC1A and, in the future, the potential development of new therapies.