Chronic ulcers are a significant and common cause of morbidity and mortality worldwide. They disrupt the epidermis and dermis, resulting in a loss of barrier function. Keloids and hypertrophic scars (benign cutaneous tumors) represent an abnormal healing response. These fibroproliferative disorders are characterized by an overabundance of collagen and accumulation of extracellular matrix due to an imbalance between synthesis and degradation, culminating in excessive scarring. The objectives of this study were to evaluate and compare noninvasive biophysical methods for the measurement of outstanding quantitative parameters of scars and chronic ulcers, and to establish correlations between the parameters measured and the results of conventional subjective clinical evaluations. The development of new technologies, based on ultrasonography and laser Doppler, makes possible new dermatological evaluation methods. Fifteen patients (6 females and 9 males) with 15 chronic ulcers (4 diabetic ulcers, 10 venous ulcers and 1 pressure ulcer) and 30 patients (19 females and 11 males) with 30 scars (25 hypertrophic and 5 keloids) were included in this study. Clinical evaluation was performed by a dermatologist, an aesthetic surgeon and an endocrinologist. Biophysical measurements were used to assess local blood flow by laser Doppler flowmetry (Moor DRT4), thickness and echogenicity by high frequency ultrasonography (20 MHz, Dermascan C) and ulcer linear dimensions by image analysis. Our results show that blood flow within the ulcers and scars was higher than within normal skin. Also, skin thickness of chronic ulcers was decreased when compared to normal skin; the thickness of hypertrophic scars, but not of keloids, was increased in comparison to normal skin, and presented the possibility of measuring wound and scar surfaces with precision. In summary, this pilot study established the feasibility of measuring various biophysical parameters and adapted their potential utility to research on wounds.
Regulated secretory proteins are thought to be sorted in the trans-Golgi network (TGN) via selective aggregation. To elucidate the biogenesis of the secretory granule in the exocrine pancreas, we reconstituted in vitro the conditions of pH and ions believed to exist in the TGN using the end product of this sorting process, the zymogen granule contents. Protein aggregation was dependent on pH (acidic) and on the presence of cations (10 mM Ca2+, 150 mM K+) to reproduce the pattern of proteins found in the granule. The constitutive secretory protein IgG was excluded from these aggregates. Zymogen aggregation correlated with the relative proportion of the major granule membrane protein GP-2 in the assay. These results show that the glycosylphosphatidylinositol-anchored protein GP-2 co-aggregates with zymogens in the acidic environment believed to exist in the pancreatic TGN, and thus suggest that GP-2 would function as a membrane anchor for zymogen aggregates, facilitating their entrapment in budding vesicles directed towards the regulated secretory pathway.
Toluidine blue (TBO) is a cationic thiazine dye with an affinity for neoplastic tissues in vivo. The objective of this study was to explore the in vitro photosensitizing potential of TBO and its capacity to induce apoptosis in human leukaemic T cells. Jurkat cells were incubated with TBO for one hour followed by exposure to 11 J cm(-2) of visible light from a slide projector. Cytotoxicity was assessed at 24 hours using a MTT assay. DNA fragmentation was examined at different intervals after photodynamic treatment using a DNA elution-filtration assay with [14C]-thymidine labelled cells. Caspase-3 like activation induced by photodynamic treatment was studied by measuring AC-DEVD-AMC peptide hydrolysis. The MTT assay showed a 97% decrease in optical density 24 hours following photodynamic therapy with 0.15 microg ml(-1) of TBO. Dark toxicity was absent under these conditions. DNA fragmentation was detected as early as 2 hours after photodynamic therapy and reached 68% at 6 hours. At higher TBO concentrations less DNA fragmentation and more dark toxicity was observed. An increase in caspase-3 like activity was also induced by photodynamic therapy with TBO. At the time of light exposure TBO was present in the endoplasmic reticulum and Golgi regions. In conclusion, TBO-based photodynamic therapy has a potent phototoxic effect and induces apoptosis in Jurkat cells.
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