Barrier function is the natural role of the skin. The lipid matrix present in the outermost layer of the skin, the stratum corneum is important for this function. Barrier impairment and altered... Show moreBarrier function is the natural role of the skin. The lipid matrix present in the outermost layer of the skin, the stratum corneum is important for this function. Barrier impairment and altered lipid composition are observed in several inflammatory skin diseases including atopic dermatitis and psoriasis. However, the relationship between the lipid properties and barrier function is not comprehended.In this project, a lipid model was prepared from synthetic lipids that closely resemble the stratum corneum lipid composition and organization. Subsequently, diseased skin models were developed to mimic various abnormalities in lipid composition observed in atopic dermatitis patients’ skin. Biophysical methods were used to monitor the changes in lipid organization in these models. Diffusion studies and trans-epidermal water loss measurements were performed to monitor the barrier function. This allowed the determination of the changes in lipid properties that were most instrumental in reducing the lipid barrier.This thesis further describes the use of simple skin lipid model membranes incorporating fewer components to provide a detailed insight into the relationship between lipid composition, lipid organization, and the skin barrier. The information gained in this project offers the opportunity to develop a new generation of formulations to treat these patients. Show less
Accumulating evidence indicates that ceramide (Cer) and palmitic acid (PA) possess the ability to modulate switching of macrophage phenotypes and possess anti-tumorigenic effects; however, the... Show moreAccumulating evidence indicates that ceramide (Cer) and palmitic acid (PA) possess the ability to modulate switching of macrophage phenotypes and possess anti-tumorigenic effects; however, the underlying molecular mechanisms are largely unknown. The aim of the present study was to investigate whether Cer and PA could induce switching of macrophage polarization from the tumorigenic M2- towards the pro-inflammatory M1-phenotype, and whether this consequently altered the potential of colorectal cancer cells to undergo epithelial-mesenchymal transition (EMT), a hallmark of tumor progression. Our study showed that Cer- and PA-treated macrophages increased expression of the macrophage 1 (M1)-marker CD68 and secretion of IL-12 and attenuated expression of the macrophage 2 (M2)-marker CD163 and IL-10 secretion. Moreover, Cer and PA abolished M2 macrophage-induced EMT and migration of colorectal cancer cells. At the molecular level, this coincided with inhibition of SNAI1 and vimentin expression and upregulation of E-cadherin. Furthermore, Cer and PA attenuated expression levels of IL-10 in colorectal cancer cells co-cultured with M2 macrophages and downregulated STAT3 and NF-kappa B expression. For the first time, our findings suggest the presence of an IL-10-STAT3-NF-kappa B signaling axis in colorectal cancer cells co-cultured with M2 macrophages, mimicking the tumor microenvironment. Importantly, PA and Cer were powerful inhibitors of this signaling axis and, consequently, EMT of colorectal cancer cells. These results contribute to our understanding of the immunological mechanisms that underlie the anti-tumorigenic effects of lipids for future combination with drugs in the therapy of colorectal carcinoma. Show less
Cell-based in vitro developed human skin equivalents facilitate screenings of compounds for therapeutic potential or toxicity and enable scientific research expanding knowledge on skin physiology... Show moreCell-based in vitro developed human skin equivalents facilitate screenings of compounds for therapeutic potential or toxicity and enable scientific research expanding knowledge on skin physiology and pathophysiology. Human skin equivalents resemble key features of native human skin, including the dermal and epidermal architecture. However, a limitation of human skin equivalents is the altered lipid barrier formation, which leads to a decreased barrier functionality. This could be induced by suboptimal cell culture conditions or the different cell microenvironment. The primary aim of this dissertational research was to enhance the morphogenesis and barrier formation of human skin equivalents to better mimic that of native human skin. The results indicate that modification of the dermal extracellular matrix by the biopolymer chitosan enhanced epidermal morphogenesis and barrier formation. Furthermore, by better resembling native skin conditions in vitro, primarily through a reduction in oxygen level, the epidermal morphogenesis and lipid barrier formation was improved. Finally, using a combinatory approach of optimized cell culture conditions and enhanced cell culture medium, the epidermal morphogenesis and barrier formation of human skin equivalents resembled that of native human skin more closely. Show less
Drug delivery across the skin is a challenging task because of the skin barrier. The skin barrier underlies in the outermost layer of the skin, the stratum corneum (SC). The lipids play a crucial... Show moreDrug delivery across the skin is a challenging task because of the skin barrier. The skin barrier underlies in the outermost layer of the skin, the stratum corneum (SC). The lipids play a crucial role in this barrier function. The focus of this PhD project was to elucidate the molecular structure of the lipid matrix present in the SC and to relate this structure with the barrier function. The lipid compositions selected for these studies were particularly chosen to understand the changes in barrier function in dry and diseased skin, i.e.,atopic eczema, Netherton syndrome compared to healthy skin. A variety of biophysical and analytical methods such as X-ray diffraction, neutron diffraction, infra-red spectroscopy, microscopy and LC/MS were combined to unravel the molecular structure. Diffusion studies and trans-epidermal water loss measurements were carried out to relate lipid organization with the lipid barrier. All the diffraction studies were performed in Grenoble, France at the ESRF (X-rays) and ILL (neutron). Neutron diffraction studies are in collaboration with King's College, University of London (Prof. J. Lawrence, Dr. D. Barlow). Show less
