Global ETD Search

451	Myocardial angiogenesis aspects on endogenous determinants and effects of stimulation / Broberg, Agneta Månsson, January 2009 (has links) Diss. (sammanfattning) Stockholm : Karolinska institutet, 2009. / Härtill 4 uppsatser.
452	An immunohistochemical analysis of regenerating cellular material in two distinct models of skeletal muscle injury Sarathy, Apurva 14 November 2011 (has links) Tourniquet mediated Ischemia Reperfusion (I/R) injury causes damage to skeletal muscle, often resulting in prolonged functional impairment. The current study utilizes immunohistochemistry (IHC) to determine whether the controlled release of the anabolic factor, insulin-like growth factor-I (IGF-I), from the biodegradable PEGylated fibrin gel matrix can facilitate the recovery of skeletal muscle from I/R. Treatment groups following a 2-hour tourniquet applied to the limb of 6-9 month rats, included intramuscular injections of saline, PEGylated fibrin gel (PEG-Fib) only and IGF-I conjugated to PEGylated fibrin gel (PEG-Fib-IGF). Expression of the myogenic regulatory factors MyoD and myogenin detected via IHC in the PEG-Fib-IGF group was significantly lower compared to the saline group, showing a 1.4±0.8% nuclear co-localization for MyoD and a 2.0±0.8% nuclear co-localization for myogenin at 14 days of recovery. The saline group showed higher values, 31.4±4.4% and 44.1±7.3% for MyoD and myogenin nuclear co-localization respectively. A significantly greater percentage, 88.8±3.7% of Desmin positive myofibers was seen at 14 days of recovery, while a lower percentage of fibers expressing neonatal myosin, 7.7±2.7% was seen in the PEG-Fib-IGF group compared to the saline treatment group. These results indicate that IGF-I delivered intramuscularly via PEGylated fibrin gel, functions therapeutically in skeletal muscle recovery, from I/R mediated damage. In a separate injury model that deals with volumetric muscle loss, IHC analyses were performed to test the efficacy of a novel tissue engineering strategy utilizing extracellular matrix (ECM) as a scaffold. In this model, also called the defect model, a 1.0 X 1.0 cm piece of the lateral gastrocnemius was removed and replaced with a muscle-derived ECM. The constructs were then seeded with bone marrow derived cells (BMSCs), adipose derived stem cells (ADSCs) or the peroneal nerve was relocated to the area of the ECM implant. 42 days post recovery IHC analysis was performed on the ECM implants. The quantification of desmin-positive regenerating myofibers bearing centrally located nuclei, showed significantly greater values in the top, middle and bottom region of the ECM implants that received peroneal nerve relocation, when compared to the experimental group that received the ECM implant alone. Blood vessel density increases were seen within the middle region of the ECM implant groups that received BMSC+Nerve treatment and the bottom region of the ECM implant groups that received ADSC+Nerve treatment. Thus, these results corroborate the therapeutic effect of peroneal nerve relocation, which stimulated an increase in myofiber regeneration and vascular maintenance within the construct. / text Ischemia reperfusion PEGylated fibrin biomatrix Insulin like growth factor-I Growth factor-I Mesenchymal stem cells Extracellular matrix Immunohistochemistry Skeletal muscle injury Skeletal muscle recovery
453	Development of hydrodynamically engineered cartilage in response to insulin-like growth factor-1 and transforming growth factor-beta1: formation and role of a type I collagen-based fibrous capsule Yang, Yueh-Hsun 20 September 2013 (has links) Articular cartilage which covers the surfaces of synovial joints is designed to allow smooth contact between long bones and to absorb shock induced during joint movement. Tissue engineering, a means of combining cells, biomaterials, bioreactors and bioactive agents to produce functional tissue replacements suitable for implantation, represents a potential long-term strategy for cartilage repair. The interplay between environmental factors, however, gives rise to complex culture conditions that influence the development of tissue-engineered constructs. A fibrous capsule that is composed of abundant type I collagen molecules and resembles fibrocartilage usually forms at the outer edge of neocartilage, yet the understanding of its modulation by environmental cues is still limited. Therefore, this dissertation was aimed to characterize the capsule formation, development and function through manipulation of biochemical parameters present in a hydrodynamic environment while a chemically reliable media preparation protocol for hydrodynamic cultivation of tissue-engineered cartilage was established. To this end, a novel wavy-wall bioreactor (WWB) that imparts turbulent flow-induced shear stress was employed as the model system and polyglycolic acid scaffolds seeded with bovine primary chondrocytes were cultivated under varied biochemical conditions. The results demonstrated that tissue morphology, biochemical composition and mechanical strength of hydrodynamically engineered cartilage were maintained as the serum content decreased by 80% (from 10% to 2%). Transient exposure of the low-serum constructs to exogenous insulin-like growth factor-1 (IGF-1) or transforming growth factor-β1 (TGF-β1) further accelerated their development in comparison with continuous treatment with the same bioactive molecules. The process of the capsule formation was found to be activated and modulated by the concentration of serum which contains soluble factors that are able to induce fibrotic processes and the capsule development was further promoted by fluid shear stress. Moreover, the capsule formation in hydrodynamic cultures was identified as a potential biphasic process in response to concentrations of fibrosis-promoting molecules such as TGF-β. Comparison between the capsule-containing and the capsule-free constructs, both of which had comparable tissue properties and were produced by utilizing the WWB system in combination with IGF-1 and TGF-β1, respectively, showed that the presence of the fibrous capsule at the construct periphery effectively improved the ability of engineered cartilage to integrate with native cartilage tissues, but evidently compromised its tissue homogeneity. Characterization of the fibrous capsule and elucidation of the conditions under which it is formed provide important insights for the development of tissue engineering strategies to fabricate clinically relevant cartilage tissue replacements that possess optimized tissue homogeneity and properties while retaining a minimal capsule thickness required to enhance tissue integration. Cartilage tissue engineering Fibrous capsule Hydrodynamic Wavy-walled bioreactor Insulin-like growth factor-1 Transforming growth factor-beta1 Articular cartilege Tissue engineering
454	Regulation of collagen type I production by ionizing radiation and transforming growth factor-β1 in primary human skin fibroblasts derived from early stage breast cancer patients in relation to acute radiation-induced toxicity Wang, Ying Wang Unknown Date No description available. Collagen type I Fibroblast Radiation Breast Cancer Transforming growth factor Radiation Therapy Vascular endothelial growth factor Matrix metalloproteinase Tissue inhibitor of metalloproteinase Cathepsin K
455	Annexin A1 im chronischen Nierenversagen / Annexin A1 in chronic renal failure Neymeyer, Hanna January 2013 (has links) Die Expansion des renalen Tubulointerstitiums aufgrund einer Akkumulation zellulärer Bestandteile und extrazellulärer Matrix ist eine charakteristische Eigenschaft der chronischen Nierenerkrankung (CKD) und führt zu einer Progression der Erkrankung in Richtung eines terminalen Nierenversagens. Die Fibroblasten Proliferation und ihre Transformation hin zum sekretorischen Myofibroblasten-Phänotyp stellen hierbei Schlüsselereignisse dar. Signalprozesse, die zur Induktion der Myofibroblasten führen, werden aktiv beforscht um anti-fibrotische Therapieansätze zu identifizieren. Das anti-inflammatorische Protein Annexin A1 und sein Rezeptor Formyl-Peptid Rezeptor 2 (FPR2) wurden in verschiedenen Organsystemen mit der Regulation von Fibroblastenaktivität in Verbindung gebracht, jedoch wurden ihre Expression und Funktion bei renalen fibrotischen Erkrankungen bisher nicht untersucht. Ziel der aktuellen Studie war daher die Untersuchung der renalen Annexin A1- und FPR2-Expression in einem Tiermodell des chronischen Nierenversagens, sowie die Charakterisierung der funktionellen Rolle von Annexin A1 in der Regulation des Fibroblasten Phänotyps und ihrer Syntheseleistung. Dazu wurden neugeborene Sprague-Dawley Ratten in den ersten zwei Wochen ihres Lebens entweder mit Vehikel oder mit einem Angiotensin II Typ I Rezeptor Antagonisten behandelt und ohne weitere Intervention bis zu einem Alter von 11 Monaten (CKD Ratten) gehalten. Die Regulation und Lokalisation von Annexin A1 und FPR2 wurden mit Hilfe von Real-Time PCR und Immunhistochemie erfasst. Annexin A1- und FPR2-exprimierende Zellen wurden weiter durch Doppelimmunfluoreszenzfärbungen charakterisiert. Gefärbt wurde mit Antikörpern gegen endotheliale Zellen (rat endothelial cell antigen), Makrophagen (CD 68), Fibroblasten (CD73) und Myofibroblasten (alpha-smooth muscle actin (α-sma)). Zellkulturstudien wurden an immortalisierten renalen kortikalen Fibroblasten aus Wildtyp- und Annexin A1-defizienten Mäusen, sowie an etablierten humanen und murinen renalen Fibrolasten durchgeführt. Eine Überexpression von Annexin A1 wurde durch eine stabile Transfektion erreicht. Die Expression von Annexin A1, α-sma und Kollagen 1α1 wurde durch Real-Time PCR, Western Blot und Immuhistochemie erfasst. Die Sekretion des Annexin A1 Proteins wurde nach TCA-Fällung des Zellkulturüberstandes im Western Blot untersucht. Wie zu erwarten zeigten die CKD Ratten eine geringere Anzahl an Nephronen mit deutlicher glomerulären Hypertrophie. Der tubulointerstitielle Raum war durch fibrilläres Kollagen, aktivierte Fibroblasten und inflammatorische Zellen expandiert. Parallel dazu war die mRNA Expression von Annexin A1 und Transforming growth factor beta (TGF-β) signifikant erhöht. Die Annexin A1-Lokalisation mittels Doppelimmunfluorsezenz identifizierte eine große Anzahl von CD73-positiven kortikalen Fibroblasten und eine Subpopulation von Makrophagen als Annexin A1-positiv. Die Annexin A1-Menge in Myofibroblasten und renalen Endothelien war gering. FPR2 konnte in der Mehrzahl der renalen Fibroblasten, in Myofibroblasten, in einer Subpopulation von Makrophagen und in renalen Epithelzellen nachgewiesen werden. Eine Behandlung der murinen Fibroblasten mit dem pro-fibrotischen Zytokin TGF-β führte zu einem parallelen Anstieg der α-sma-, Kollagen 1α1- und Annexin A1-Biosynthese und zu einer gesteigerten Sekretion von Annexin A1. Eine Überexpression von Annexin A1 in murinen Fibroblasten reduzierte das Ausmaß der TGF-β induzierten α-sma- und Kollagen 1α1-Biosynthese. Fibroblasten aus Annexin A1-defizienten Mäusen zeigten einen starken Myofibroblasten-Phänotyp mit einer gesteigerten Expression an α-sma und Kollagen 1α1. Der Einsatz eines Peptidantagonisten des FPR2 (WRW4) resultierte in einer Stimulation der α-sma-Biosynthese, was die Vermutung nahe legte, dass Annexin A1 FPR2-vermittelt anti-fibrotische Effekte hat. Zusammenfassend zeigen diese Ergebnisse, dass renale kortikale Fibroblasten eine Hauptquelle des Annexin A1 im renalen Interstitium und einen Ansatzpunkt für Annexin A1-Signalwege in der Niere darstellen. Das Annexin A1/FPR2-System könnte daher eine wichtige Rolle in der Kontrolle des Fibroblasten Phänotyp und der Fibroblasten Aktivität spielen und daher einen neuen Ansatz für die anti-fibrotischen pharmakologischen Strategien in der Behandlung des CKD darstellen. / Expansion of the renal tubulointerstitium due to an accumulation of cellular constituents and extracellular matrix is a characteristic feature of chronic kidney disease (CKD) and leads to the progression towards renal failure. Fibroblast proliferation and transformation to the secretory myofibroblast phenotype present key events herein. The signaling process which leads to the generation of myofibroblasts is actively investigated to identify targets for antifibrotic therapeutic strategies. The antiinflammatory protein annexin A1 and its receptor formyl peptide receptor 2 (FPR2) have been implicated in the regulation of fibroblasts from various organs but the expression and function of the two products in renal fibrotic disease have not been elucidated so far. Aim of the present study was therefore to investigate the renal expression of annexin A1 and FPR2 in an animal model of chronic kidney disease and to characterize the role of annexin A1 in the regulation of fibroblast phenotype and synthetic activity. To this end, newborn Sprague-Dawley rats were treated either with vehicle or with an angiotensin II type I receptor antagonist during the first two weeks of their life and kept without further intervention until the age of 11 month (CKD rats). Regulation and localization of annexin A1 and FPR2 were studied using real-time PCR and immunohistochemistry. Annexin A1 and FPR2 expressing cells were further characterized by double labeling immunofluorescence with markers for endothelial cells (rat endothelial cell antigen), macrophages (CD68), fibroblasts (CD73), and myofibroblasts (alpha-smooth muscle actin (α-sma)). Cell culture studies were conducted in immortalized renal cortical fibroblast derived from wildtype and from annexin A1-deficient mice as well as in established cell lines of human and murine renal fibroblasts. Overexpression of annexin A1 was achieved by stable transfection. Expression of annexin A1, α-sma and collagen 1α1 was determined using real-time PCR, Western blotting and immunohistochemistry. Secretion of annexin A1 was studied using trichloroacetic acid protein precipitation of cell culture supernatants and Western blotting. As expected, CKD rats had an overall lower number of nephrons with a marked glomerular hypertrophy. The tubulointerstitial space was expanded due to an accumulation of fibrillar collagens, activated fibroblasts and inflammatory cells. In parallel, mRNA expression for Annexin A1 and transforming growth factor beta (TGF-β) was significantly increased. Double labeling immunofluorescence localization of annexin A1 demonstrated a high abundance in CD73 positive cortical interstitial fibroblasts and in a subset of CD68 immunoreactive macrophages. The abundance in myofibroblasts and renal endothelia was low. FPR2 was found in the majority of renal fibroblasts, myofibroblasts, a subset of macrophages, and in renal endothelial cells. Treatment of cultured murine fibroblasts with the profibrotic cytokine TGF-β resulted in a parallel induction of α-sma-, collagen 1α1- and annexin A1 biosynthesis. In addition, annexin A1 secretion was markedly increased. Overexpression of annexin A1 in murine fibroblasts reduced TGF β-induced α-sma- and collagen 1α1-biosynthesis. Fibroblasts derived from annexin A1-deficient mice showed a strong myofibroblast phenotype with increased expression of both, α-sma-, and collagen 1α1. Application of a peptide antagonist of FPR2 receptor (WRW4) caused a stimulation of α-sma biosynthesis thus suggesting a role of FPR2 in the antifibrotic effects of annexin A1. In conclusion, these results identify renal cortical interstitial fibroblasts as major source and as a target for annexin A1 signalling in the kidney. The annexin A1/FPR2 signalling system may therefore play an important role in the control of fibroblast phenotype and activity and may therefore provide a novel target for antifibrotic pharmacological strategies in the treatment of CKD. Natural sciences and mathematics
456	The GH/IGF-1 system during surgery and catabolism : focus on metabolism and heart function / Wallin, Mats, January 2007 (has links) Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 4 uppsatser.
457	Therapeutic myocardial angiogenesis and its pharmacological modulation / Siddiqui, Anwar J., January 2005 (has links) Diss. (sammanfattning) Stockholm : Karol. inst., 2005. / Härtill 4 uppsatser.
458	Expression and regulation of vasoactive substances, sex steroids and their receptors in placenta during normal pregnancy and preeclampsia / Nasiell, Josefine, January 2002 (has links) Diss. (sammanfattning) Stockholm : Karol. inst., 2002. / Härtill 5 uppsatser.
459	Spinal cord injury: mechanical and molecular aspects / Josephson, Anna, January 2002 (has links) Diss. (sammanfattning) Stockholm : Karol. inst., 2002. / Härtill 6 uppsatser.
460	The Rhomboid family of intramembrane proteases, conserved regulators of cell communication / Gallio, Marco, January 2004 (has links) Diss. (sammanfattning) Stockholm : Karol. inst., 2004. / Härtill 4 uppsatser.

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