Trans-Manhattan Expressway

Thesis (M. Arch.)--Massachusetts Institute of Technology, Dept. of Architecture, 2010.This electronic version was submitted by the student author. The certified thesis is available in the Institute Archives and Special Collections.Cataloged from student submitted PDF version of thesis.Includes bibliographical references (p. 127).Urban Infrastructure: bridges, expressways, and on and off ramps often create barriers and uninhabitable spaces within the urban context. This phenomenon is evident in northern Manhattan where the Trans-Manhattan Expressway has imposed profound divisions within the dense urban community of Washington Heights. Supporting a population of over one-hundred thousand, in 0.7 square miles, Washington Heights is one of the densest residential communities in Manhattan. Within this dense community no identifiable civic centers exist. However, the convergence of infrastructure and urbanism has the potential to synthesis new opportunities. This contemporary paradigm morphs existing infrastructure with new user-friendly architectural systems. This hybridization can alleviate the current asphyxiation associated with urban infrastructure, while transforming infrastructure to serve as a catalyst for urban life. This thesis seeks to readapt the Trans-Manhattan Expressway for public use through two strategic interventions. The first seeks to reclaim the colossal George Washington Bridge Bus Terminal from impervious infrastructure to central civic icon. The second transforms a series of urban impediments which produce excess noise and pollution, into a public plaza. While these two projects address the independent conditions of each site, together they simultaneously transform a desolate lineage of urban infrastructure into the central civic icon of Washington Heights.by Jason F. O'Koren.M.Arch

Cellular and Molecular Mediators of Bronchiolitis Obliterans-like Pathological Changes in a Murine Model of Chlorine Gas Inhalation

<p>Bronchiolitis Obliterans (BO) is a major cause of chronic airway dysfunction after toxic chemical inhalation. The pathophysiology of BO is not well understood, but epithelial cell injury has been closely associated with the development of fibrotic lesions in human studies and in animal models of both toxin- and transplant-induced BO. However, while almost all cases and models of BO include epithelial injury, not all instances of epithelial injury result in BO, suggesting that epithelial damage per se is not the critical event leading to the development of BO. In this dissertation, we describe a model of chlorine (Cl2)-induced BO in which mice develop tracheal and large airway obliterative lesions within 10 days of exposure to high (350 ppm), but not low (200 ppm), concentrations of Cl2 gas. Lesions develop in a series of well-demarcated pathological changes that include epithelial denudation, inflammatory cell infiltration by day 2 after exposure, fibroblast infiltration and collagen deposition by day 5, and in-growth of blood vessels by day 7, ultimately leading to lethal airway obstruction by days 9-12. Using this model, we were able to test our hypothesis that loss of epithelial progenitor cells is a critical factor leading to the development of obliterative airway lesions after chemical inhalation. Indeed, these lesions arise only under conditions and in areas in which basal cells, the resident progenitor cells for large airway epithelium, are eliminated by Cl2 exposure. </p><p>The molecular pathways contributing to BO development are not well understood. Mechanisms of epithelial injury differ across BO models, but we hypothesized that after the inciting injury, BO models share common pathways. We compared microarray analysis from day 5 non-BO- and BO-inducing chemical injuries and subsequently identified biological pathways that may contribute to BO pathogenesis. Our findings add support to pathways previously implicated in BO development and more importantly, suggest potential new pathways and molecular mediators of BO. Furthermore, we evaluated the efficacy of therapeutic inhibition of neovascularization or inflammation to prevent Cl2-induced BO. To date, our therapeutic interventions were ineffective. Nonetheless, our findings suggest that in the context of Cl2-induced BO, vascular endothelial growth factor receptor 2 (a mediator of neovascularization) and inducible nitric oxide synthase (a mediator of inflammation) are not critical in BO pathogenesis.</p><p>In sum, our work introduces and characterizes a novel Cl2-induced murine model of BO. Using this model we demonstrated that in the absence of basal cells, epithelial regeneration does not occur and regions of epithelial denudation persist from which an aberrant repair process is initiated, leading to obliterative airway lesions. Our findings suggest that, irrespective of the cause, loss of epithelial progenitor cells may be a critical factor leading to the development of BO. Furthermore, our gene expression analysis implicates novel mediators and signaling pathways in the development of BO. Our analysis lays the foundation for more rigorous exploration of these targets in the pathogenesis of BO.</p>Dissertatio

Large-scale death of retinal astrocytes during normal development is non-apoptotic and implemented by microglia.

Naturally occurring cell death is a fundamental developmental mechanism for regulating cell numbers and sculpting developing organs. This is particularly true in the nervous system, where large numbers of neurons and oligodendrocytes are eliminated via apoptosis during normal development. Given the profound impact of death upon these two major cell populations, it is surprising that developmental death of another major cell type-the astrocyte-has rarely been studied. It is presently unclear whether astrocytes are subject to significant developmental death, and if so, how it occurs. Here, we address these questions using mouse retinal astrocytes as our model system. We show that the total number of retinal astrocytes declines by over 3-fold during a death period spanning postnatal days 5-14. Surprisingly, these astrocytes do not die by apoptosis, the canonical mechanism underlying the vast majority of developmental cell death. Instead, we find that microglia engulf astrocytes during the death period to promote their developmental removal. Genetic ablation of microglia inhibits astrocyte death, leading to a larger astrocyte population size at the end of the death period. However, astrocyte death is not completely blocked in the absence of microglia, apparently due to the ability of astrocytes to engulf each other. Nevertheless, mice lacking microglia showed significant anatomical changes to the retinal astrocyte network, with functional consequences for the astrocyte-associated vasculature leading to retinal hemorrhage. These results establish a novel modality for naturally occurring cell death and demonstrate its importance for the formation and integrity of the retinal gliovascular network

Large-scale death of retinal astrocytes during normal development is non-apoptotic and implemented by microglia.

Naturally occurring cell death is a fundamental developmental mechanism for regulating cell numbers and sculpting developing organs. This is particularly true in the nervous system, where large numbers of neurons and oligodendrocytes are eliminated via apoptosis during normal development. Given the profound impact of death upon these two major cell populations, it is surprising that developmental death of another major cell type-the astrocyte-has rarely been studied. It is presently unclear whether astrocytes are subject to significant developmental death, and if so, how it occurs. Here, we address these questions using mouse retinal astrocytes as our model system. We show that the total number of retinal astrocytes declines by over 3-fold during a death period spanning postnatal days 5-14. Surprisingly, these astrocytes do not die by apoptosis, the canonical mechanism underlying the vast majority of developmental cell death. Instead, we find that microglia engulf astrocytes during the death period to promote their developmental removal. Genetic ablation of microglia inhibits astrocyte death, leading to a larger astrocyte population size at the end of the death period. However, astrocyte death is not completely blocked in the absence of microglia, apparently due to the ability of astrocytes to engulf each other. Nevertheless, mice lacking microglia showed significant anatomical changes to the retinal astrocyte network, with functional consequences for the astrocyte-associated vasculature leading to retinal hemorrhage. These results establish a novel modality for naturally occurring cell death and demonstrate its importance for the formation and integrity of the retinal gliovascular network

Comprehensive analysis of mouse retinal mononuclear phagocytes

The innate immune system is activated in a number of degenerative and inflammatory retinal disorders such as age-related macular degeneration (AMD). Retinal microglia, choroidal macrophages, and recruited monocytes, collectively termed 'retinal mononuclear phagocytes', are critical determinants of ocular disease outcome. Many publications have described the presence of these cells in mouse models for retinal disease; however, only limited aspects of their behavior have been uncovered, and these have only been uncovered using a single detection method. The workflow presented here describes a comprehensive analysis strategy that allows characterization of retinal mononuclear phagocytes in vivo and in situ. We present standardized working steps for scanning laser ophthalmoscopy of microglia from MacGreen reporter mice (mice expressing the macrophage colony-stimulating factor receptor GFP transgene throughout the mononuclear phagocyte system), quantitative analysis of Iba1-stained retinal sections and flat mounts, CD11b-based retinal flow cytometry, and qRTRT-PCRPCRPCR analysis of key microglia markers. The protocol can be completed within 3 d, and we present data from retinas treated with laser-induced choroidal neovascularization (CNCNV), bright white-light exposure, and Fam161a-associated inherited retinal degeneration. The assays can be applied to any of the existing mouse models for retinal disorders and may be valuable for documenting immune responses in studies for immunomodulatory therapies