SummaryIntroductionMatrix metalloproteinases (MMPs) and ‘aggrecanase’ a disintegrin and metalloproteinase with thrombospondin motifs (ADAMTSs) are well established to play key roles in osteoarthritis (OA) through degradation of extracellular matrix (ECM) type II collagen and aggrecan, and are thus potential targets for development of OA therapies.ObjectiveThis paper aims to provide a comprehensive review of the expression and potential roles of other, lesser-known ADAMTSs and related adamalysins (or a disintegrin and metalloproteinases (ADAMs)) in cartilage, with a view to identifying potentially protective or homeostatic metalloproteinases in the joint and informing consequent selective inhibitor design.DesignA comprehensive literature search was performed using PubMed terms ‘osteoarthritis’ and ‘ADAMTS’ or ‘ADAM’.ResultsSeveral ADAMTSs and ADAMs were identified as having reportedly increased expression in OA. These include enzymes likely to play roles in cartilage matrix anabolism (e.g., the procollagen N-proteinases ADAMTS-2, ADAMTS-3 and ADAMTS-14), chondrocyte differentiation and proliferation (e.g., ADAM9, ADAM10, ADAM12), as well as enzymes contributing to cartilage catabolism (e.g., Cartilage oligomeric protein (COMP)-degrading ADAMTS-7 and ADAMTS-12).ConclusionsIn addition to the well-characterised MMPs, ADAMTS-4 and ADAMTS-5, many other ADAMTSs and ADAMs are expressed in cartilage and several show significantly altered expression in OA. Studies aimed at elucidating the pathophysiological roles of these enzymes in cartilage will contribute to our understanding of OA pathogenesis and enable design of targeted inhibitors that effectively target metalloproteinase-mediated cartilage degradation while sparing cartilage repair pathways.
Manipulating an incorporated scaffold to direct cell behaviors play a key role in tissue engineering. In this study, we developed novel nano-topographic oxidized silicon nanosponges capable of being modified with various chemicals of a few nm in thickness to gain further insight into the fundamental biology of cell-environment interactions in vitro. A wet etching technique was applied to fabricate the silicon nanosponges in a high-throughput manner and was followed by vapor deposition of various organo-silane chemicals to enable self-assembly on the surfaces of the silicon nanosponges. When Chinese hamster ovary cells were cultured on these chemically modified nano-topographic structures, they displayed distinct morphogenesis, adherent responses, and biochemical properties in comparison with those of their planar oxidized silicon counterparts. There were predominant nano-actin punches and slender protrusions formed while cells were cultured on the nano-topographic structures, indicating that cell behaviors can be influenced by the physical characteristic derived from nano-topography, in addition to the hydrophobicity of contact surfaces. This study demonstrates potential applications of these nanotopographic biomaterials for controlling cell development in tissue engineering as well as in basic cell biology research.
These results demonstrate that intravenous dezocine 0.1 mg/kg 10 min prior to induction was effective in suppressing fentanyl-induced cough in our patients.
This paper describes the development of physically and/or chemically modified chitosan membranes to probe cellular behaviors and molecular-level structural responses of NIH-3T3 fibroblasts (normal cells) and Ha-ras-transformed cells (abnormal cells) adhered onto these modified membranes. To prepare chitosan membranes with nanometrically scaled physical features, we have demonstrated an inexpensive and easy-to-handle method that could be easily integrated with IC-based manufacturing processes with mass production potential. These physically or chemically modified chitosan membranes were examined via scanning electron microscopy, atomic force microscopy, X-ray photoelectron spectroscopy, and water contact angle measurement, in order to gain a better understanding of chitosan membrane surface characteristics including surface morphology, stiffness, functional groups, and surface hydrophobicity/hydrophilicity. NIH-3T3 fibroblasts and their Ha-ras-transformed progeny were cultured on these modified chitosan membranes. After 12, 24 and 48 h of culture, these cells were investigated to decipher cellular behaviors. We found that NIH-3T3 fibroblasts and their Ha-ras-transformed progeny exhibited distinct structurally based responses attributable to chitosan membrane surface chemical or physical properties that we demonstrate as possibly applicable, for drug screening applications. Secondarily, but crucially to this study, we developed a chitosan-based micropatterning procedure that allowed us to re-arrange mammalian cells (i.e., HeLa cells in this study, for cancer drug screening) at the desired locations (with a single-cell array format). This procedure was based on cell affinity to different surface topographies of chitosan membranes that we prepared. This cell-based patterning approach has the potential for use in a wide range of applications including use as a promising platform for drug discovery, cytotoxicity studies, functional genomics, and investigations of cellular microenvironment. We believe that this study would provide further understanding of naturally derived biomaterials, lay the foundation for broadening the applications of chitosan, and facilitate the development of new biomedical devices (i.e., artificial stents, implantable artificial tissues, and sustainable implantable biosensors) with unique cell-material interface properties and characteristics, such as in vitro cell culture and diagnostic platforms.
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