Revitalization of the building activity

Wong, Shu-man, Ken., 黃書文.

January 2004

published_or_final_version / Architecture / Master / Master of Architecture

Einfluss des Z-Scheiben-Proteins Calsarcin-1 auf das Remodeling nach Myokardinfarkt

Kruschandl, Katrin

23 March 2015

Ziel dieser Arbeit war, in einem experimentellen Ansatz der Frage nachzugehen, welche pathophysiologischen Veränderungen in Bezug auf Hypertrophie und Funktionalität der Herzmuskulatur nach einem Myokardinfarkt durch Calsarcin-1 hervorgerufen werden und welchen Einfluss das Z-Scheiben-Protein in-vivo auf den Kalzium-Calmodulin Signalweg besitzt. Für die dafür durchgeführten Untersuchungen konnte auf drei verschiedene Mauslinien zurückgegriffen werden (Calsarcin-1 knockout-Mäuse, Calsarcin-1 transgene Mäuse, Wildtypmäuse). Die vorliegende Arbeit baut auf den in-vitro Ergebnissen von Frey et al. (2004) auf. Insgesamt wurden 278 Mäuse einer Infarkt- oder Scheinoperation unterzogen. Fünf Wochen nach ihrer Operation wurde das Herz jeder Maus mittels Ultraschall vermessen und auf seine Funktionstüchtigkeit untersucht. Anschließend wurden die Tiere getötet. Die entnommenen Herzen wurden gewogen, die entnommenen Unterschenkel vermessen. Insgesamt 60 Herzen wurden nach konventionellen histologischen Verfahren HE-gefärbt. 39 Mäuse wurden 24 Stunden nach ihrer Infarktoperation getötet. Ihre Herzen wurden mit Evans-blue und Tetrazoliumchlorid gefärbt. Insgesamt gingen Gewebeproben von 67 Herzen in die Untersuchungen auf RNA-Ebene (Real-Time PCR, Dot Blot) ein. Die Herzen von 40 Tieren konnten auf Proteinebene (Western Blot) untersucht werden. Die echokardiologische Untersuchung der Mäuse nach fünf Wochen zeigte eine deutliche Dilatation des linken Ventrikels derjenigen Tiere, die einer Infarktoperation unterzogen worden waren. Die größte Dilatation der drei Infarktgruppen wiesen die Mäuse auf, die nicht in der Lage sind, das Z-Scheiben-Protein Calsarcin-1 auszubilden (0,558 cm (ko Mi) vs. 0,494 cm (Wt Mi); p < 0,001). Diese Mäuse zeigten auch gegenüber den anderen beiden Infarktgruppen die ausgeprägteste systolische Dysfunktion (FS von 0,238% (ko Mi) vs. 0,376% (Wt Mi) und 0,353% (tg Mi); jeweils p < 0,001). Keine Unterschiede bestanden zwischen den Gruppen der scheinoperierten Mäuse. Morphometrische Analysen belegten eine deutliche Hypertrophie der Calsarcin-1 defizienten Mäuse, die durch die Infarktoperation einer biomechanischen Stresssituation ausgesetzt wurden. Als Hypertrophiemaß wurde der Quotient aus Herz- und Körpergewicht gewählt, zusätzlich wurde der Quotient aus Herzgewicht und Tibialänge bestimmt. Bei beiden Messungen unterschied sich das Herzgewicht der knockout-Mäuse mit Infarkt signifikant von den anderen beiden Infarktgruppen. Für das Verhältnis von Herz- zu Körpergewicht wurde für die drei Mäusegruppen ermittelt: 7,55 ± 0,6mg/g (ko Mi ), 5,56 ± 0,23mg/g (WtMi) und 5,73 ± 0,4mg/g (tgMi), wobei p < 0,01 bei ko Mi/Wt Mi und p < 0,86 bei tg Mi / Wt Mi. Für das Verhältnis von Herzgewicht zu Tibialänge ergab sich: 12,4mg/mm (ko Mi), 10,11mg/mm (Wt Mi) und 10,02mg/mm (tg Mi) (p < 0,001 koMi / WtMi, p < 0,27 tg Mi / WtMi). Zwischen den Gruppen der scheinoperierten Mäuse wurden keine signifikanten Unterschiede festgestellt. Auch auf zellulärer Ebene wiesen die Calsarcin-1 knockout-Mäuse mit Myokardinfarkt eine deutliche Hypertrophie auf verglichen mit den Wildtyp-Mäusen mit Infarkt und den Calsarcin-1 transgenen Tieren (Zellgrößenzunahme um 43,12% (koMi), 34,85% (WtMi) und 29,12% (tgMi); jeweils p < 0,001). Von allen drei Infarktgruppen zeigten die knockout-Mäuse nach fünf Wochen die ausgeprägteste Narbenbildung (Fläche der Infarktnarbe in % der Fläche des linken Ventrikels: 73,41±7,85% (ko-Mi), 53,71±3,81% (WtMi) und 48,60±6,04% (tgMi)). Übereinstimmend dazu wiesen die knockout-Mäuse mit Myokardinfarkt eine übermäßige Steigerung der ANP Produktion auf mRNA-Ebene auf. Auf Proteinebene konnte eine Steigerung der Produktion von MCIP nachgewiesen werden (ko Mi 4,3 ± 0,5 vs. Wt Mi 2,3 ± 0,3 ; p < 0,01). Zusammenfassend lassen die Ergebnisse auf eine gesteigerte Aktivität von Calcineurin und auf ein pathologisches Remodeling in der Abwesenheit von Calsarcin-1 schließen. Die Überexpression von Calsarcin-1 scheint dagegen eine pathologische Hypertrophie des Herzmuskels abmildern zu können.

Myokardinfarkt

Remodeling

Z-Scheibe

Calsarcin-1

myocardial infarction

remodeling

z-disc

calsarcin-1

ddc:636.089

Herzinfarkt

The evolution of prefabricated interior components for post-occupancy modification /

Ou, Yangli, 1968-

January 1999

In recent years, home modification has played an increasingly important role in the housing industry. Expenditures on renovation have consistently exceeded those spent on new home construction during the 1990s. And it has huge potential to continuously increase in the years to come. Renovators' do-it-yourself activities are efficient ways to fulfill homeowners' psychological and physical needs and save expensive labour costs. / This research investigates not only the technology evolution of ten products and the installation processes that are frequently used by renovators, but also the fundamental reasons that drive the development of these innovations. It covers the technology from the beginning of this century to the latest innovations developed by manufactures in the 1990s. Additionally, it documents recent national and Quebec renovation market trends, together with three post-occupancy studies which had been conducted in the Montreal Area. / The study reveals that many of the products and installation process have been greatly simplified and innovations in the renovation market could benefit renovators by allowing them to undertake modifications themselves. Also, the author suggests certain guidelines for increasing housing affordability and new products development.

Dwellings -- Remodeling.

Development of a novel organ culture system allowing independent control of local mechanical variables and its implementation in studying the effects of axial stress on arterial remodeling

Dominguez, Zachary

25 August 2008

Arterial remodeling is a process by which arteries respond to sustained changes in their mechanical environment. This process occurs in a way such that an artery's local mechanical environment (circumferential, shear, and axial stress) is maintained at a homeostatic level. However, most studies utilize a methodology that controls the global parameters (pressure, flow rate, and axial stretch). This approach often confounds the results since the actual drivers of remodeling are not independently isolated. This research involved developing a methodology and system capable of independently controlling each of the local parameters and examining the effect of axial stress on remodeling. An organ culture system capable of monitoring and controlling the three global parameters and calculating the cross sectional geometry was developed. This combination of hardware was incorporated into LabVIEW which afforded the user the ability to define desired values for the local mechanical parameters. Porcine common carotid arteries were cultured for seven days in this system under physiologically normal circumferential and shear stresses and a constant axial stress of either 150 kPa or 300 kPa. Material response, general arterial morphology, tissue viability, and collagen synthesis were examined in order to gauge the effectiveness of the organ culture system and assess any arterial remodeling. The results of this study demonstrate the ability of the organ culture system in achieving and maintaining target values of stress throughout the culture period. Cell viability, general arterial morphology, and collagen synthesis rates were maintained for all arteries. The elevated axial stress appeared to cause a softening of the artery in both the axial and circumferential direction. It was hypothesized that this softening was the result of a changing collagen structure. Additional softening seen in arteries was attributed to the effects of the culture system.

Stress

Arterial remodeling

Organ culture

Arteries

Strains and stresses

Tissue remodeling

Remodeling of Stellate Ganglion Neurons After Spatially Targeted Myocardial Infarction: Neuropeptide and Morphologic Changes

Ajijola, Olujimi A., Yagishita, Daigo, Reddy, Naveen K., Yamakawa, Kentaro, Vaseghi, Marmar, Downs, Anthony M., Hoover, Donald B., Ardell, Jeffrey L., Shivkumar, Kalyanam

01 May 2015

Background Myocardial infarction (MI) induces remodeling in stellate ganglion neurons (SGNs). Objective We investigated whether infarct site has any impact on the laterality of morphologic changes or neuropeptide expression in stellate ganglia. Methods Yorkshire pigs underwent left circumflex coronary artery (LCX; n = 6) or right coronary artery (RCA; n = 6) occlusion to create left- and right-sided MI, respectively (control: n = 10). At 5 ± 1 weeks after MI, left and right stellate ganglia (LSG and RSG, respectively) were collected to determine neuronal size, as well as tyrosine hydroxylase (TH) and neuropeptide Y immunoreactivity. Results Compared with control, LCX and RCA MIs increased mean neuronal size in the LSG (451 ± 25 vs 650 ± 34 vs 577 ± 55 μm2, respectively; P =.0012) and RSG (433 ± 22 vs 646 ± 42 vs 530 ± 41 μm2, respectively; P =.002). TH immunoreactivity was present in the majority of SGNs. Both LCX and RCA MIs were associated with significant decreases in the percentage of TH-negative SGNs, from 2.58% ± 0.2% in controls to 1.26% ± 0.3% and 0.7% ± 0.3% in animals with LCX and RCA MI, respectively, for LSG (P =.001) and from 3.02% ± 0.4% in controls to 1.36% ± 0.3% and 0.68% ± 0.2% in LCX and RCA MI, respectively, for RSG (P =.002). Both TH-negative and TH-positive neurons increased in size after LCX and RCA MI. Neuropeptide Y immunoreactivity was also increased significantly by LCX and RCA MI in both ganglia. Conclusion Left- and right-sided MIs equally induced morphologic and neurochemical changes in LSG and RSG neurons, independent of infarct site. These data indicate that afferent signals transduced after MI result in bilateral changes and provide a rationale for bilateral interventions targeting the sympathetic chain for arrhythmia modulation.

autonomic nervous system

myocardial infarction

neuronal remodeling

neuropeptide remodeling

sympathetic ganglia

Biomedical Sciences

The evolution of prefabricated interior components for post-occupancy modification /

Ou, Yangli, 1968-

January 1999

No description available.

Dwellings -- Remodeling.

Role of the EGFR Pathway in Lung Remodeling and Disease

Kramer, Elizabeth L.

January 2009

No description available.

Biology

EGFR

TGF-alpha

Egr-1

lung remodeling

house dust mite

airway smooth muscle remodeling

Shear stress, hemodynamics, and proteolytic mechanisms underlying large artery remodeling in sickle cell disease

Keegan, Philip Michael

07 January 2016

Sickle cell disease is a genetic disorder that affects 100,000 Americans and millions more worldwide. Although the sickle mutation affects one protein, which is only expressed in a single cell type, it has profound detrimental effects on nearly every organ system in the body. Young children with sickle cell disease have an 11\% chance of suffering a major stroke event by the age of 16, and a 35\% chance of developing ÒsilentÓ strokes that often result in significant learning and mental disabilities. Clinical investigations suggest that stroke development in people with sickle cell disease results from luminal narrowing of the carotid and cerebral arteries due to excess matrix deposition and fragmentation of the elastic lamina; however, the underlying cellular mechanisms that initiate arterial remodeling in sickle cell disease remain relatively unknown. Cathepsins K and V are members of the cysteine family of proteases and represent two of the most potent elastases yet identified in humans. Furthermore, the role of Cathepsins has been well established in other cardiovascular remodeling diseases, such as atherosclerosis. Due to the compelling histological similarities between vasculopathy in sickle cell disease and atherosclerosis, we tested the hypothesis that the unique inflammatory milieu, in conjunction with the biomechanical vascular environment of sickle cell disease upregulates cathepsin K and V activity in large artery endothelial cells, ultimately leading to arterial remodeling and stroke. Currently, there are few therapeutic options for the prevention of stroke in sickle cell disease; those that do exist carry significant health risks and side effects. Together, this body of work has generated a more mechanistic understanding of how the sickle milieu stimulates the endothelium to initiate arterial remodeling, which has enabled us to identify important pathways (JNK, NF$\kappa$B) downstream of inflammatory and biomechanical stimuli and validate new therapeutic targets within the JNK pathway to establish preclinical proof of efficacy for the prevention of arterial remodeling in sickle cell disease.

Sickle cell disease

Arterial remodeling

Cathepsins

Stroke

Hemodynamics

Shear stress

DISTINCT ROLES FOR Cx37 AND Cx40 IN REGULATING VASCULAR RESPONSES FOLLOWING ISCHEMIA

Fang, Jennifer Shea-Ying

January 2010

Gap junctions are intercellular channels that permit passage of electrical and chemical signals between neighbouring cells. Vascular endothelium typically co-expresses Cx37 and Cx40, but may downregulate its expression of Cx37 (and upregulate Cx43) in response to changes in flow. The specific regulatory roles mediated by vascular endothelial connexins, and the consequences of altered connexin expression, remain unclear. In this study, we hypothesized that Cx37 and Cx40 regulate distinct vascular responses. We further hypothesize that Cx37 is predominantly involved in vascular growth control, whereas vascular growth is not affected by ablation of Cx40 expression. We show herein that Cx37, but not Cx40 or Cx43, suppresses growth of a highly-proliferative cancer cell line by inducing G1 cell cycle accumulation. We further show that Cx37-deficient mice, lacking Cx37's putative growth inhibitory effect on the vasculature, exhibit a more extensive native and post-ischemic collateral circulation, and greater ischemia-induced microvascular density. In addition, Cx37-/- mice demonstrate a functional improvement in recovery over wild-type animals in two models of hindlimb ischemia. By contrast, Cx40-/- mice fail to recover distal limb flow following unilateral hindlimb ischemia, resulting in necrosis. Long-term angiotensin II antagonism normalized post-ischemic hindlimb bloodflow, reduced macrophage infiltration, and delayed (but did not reverse) the necrotic phenotype of these animals. In summary, we show a distinct role for each of the endothelial connexins, Cx37 and Cx40, in regulating post-ischemic vascular responses.

Angiogenesis

Collateral

Connexin

Gap Junction

Ischemia

Vascular Remodeling

Snf2l Regulates Foxg1 Expression to Control Cortical Progenitor Cell Proliferation and Differentiation

McGregor, Chelsea P.

05 September 2012

Over the past five years the role of epigenetic modifiers in brain development has become increasingly evident. In this regard, Snf2l, a homolog of the chromatin remodeling protein ISWI, was shown to have enriched expression in the brain and be important for neuronal differentiation. Mice lacking functional Snf2l have hypercellularity of the cerebral cortex due to increased cell cycle re-entry. In this thesis I demonstrate the effects of Snf2l-ablation on cortical progenitor cells including increased proliferation and cell cycle deregulation, the consequence of which is a delay in neuronal migration and altered numbers of mature cortical neurons. This phenotype arises from increased expression of Foxg1, a winged-helix repressor expressed in the forebrain and anterior optic vesicle. Moreover, genetically reducing its overexpression rescues the Snf2l-ablated phenotype. Snf2l is bound directly to a promoter region of Foxg1 suggesting that it acts as a repressive regulator in vivo and is an important factor in forebrain differentiation.

Snf2l

Foxg1

Chromatin Remodeling

Cerebral Cortex

Development

Forebrain

Epigenetic