Recent studies have revealed that the platelet adhesive process under flow is tightly regulated by multiple ligand-receptor interactions. However, platelet morphological changes during this process, particularly its physiological relevance, remain unknown under blood flow conditions. Using epifluorescence and scanning electron microscopy, we evaluated the real-time changes in platelet morphology during a platelet adhesive process on a von Willebrand factor-coated surface under physiological high shear flow in a perfusion chamber. Here, we show that dynamic platelet shape changes occurring during distinct phases of the adhesive process are precisely regulated by "inside-out" and "outside-in" integrin signals and are also a key regulatory element in successful platelet thrombogenesis opposing rapid blood flow in vivo.
We evaluated real-time processes of platelet thrombus formation on a collagen surface in a flow chamber with whole blood from patients with various platelet aggregation disorders, such as Bernard-Soulier syndrome (BSS), Glanzmann’s thrombasthenia (GTA), type 3 von Willebrand disease (vWD), and congenital afibrinogenemia (Af), who lack platelet glycoprotein (GP) Ib-IX complex, GP IIb-IIIa, von Willebrand factor (vWF), and fibrinogen, respectively. Blood from GTA patients showed impaired thrombus growth but significant initial platelet-surface interaction under all shear conditions tested (50 to 1,500 s−1). By contrast, blood from patients with BSS or type 3 vWD showed no platelet-surface interaction under high shear (≥1,210 s−1) but normal thrombus formation under low shear (≤340 s−1). When shear rate was increased stepwise to 1,500 s−1 during perfusion, the thrombus growth observed in type 3 vWD or BSS under low shear was arrested, whereas that in control blood was sharply accelerated as a function of shear rate. Overall thrombus formation in Af appeared indistinguishable from that of a control under shear rates between 50 and 1,500 s−1. However, Af thrombi formed under such conditions collapsed immediately when shear rate was further increased to 4,500 s−1, whereas thrombi of type 3 vWD or BSS formed under low shear were stable even when shear rate was elevated to 9,000 s−1 during perfusion. These findings suggest that distinct molecular mechanisms underlie the pathologic bleeding in these diseases and point to the distinct roles of two major adhesive proteins, vWF and fibrinogen. In mural thrombus formation under flow conditions, vWF, perhaps mainly through its interaction with GP Ib-IX, acts as an “initiator and promoter,” whereas fibrinogen, via its binding to GP IIb-IIIa, acts as a “stabilizer” against heightened shear forces that could lead to peeling off of platelets from the surface.
The authors report their experience with 23 sites of hidradenitis suppurativa, including cases with musculocutaneous flap repair, and discuss the surgical methods applied. Twenty-three sites in 19 patients with chronic inflammatory skin lesions were reviewed. The lesions were divided into two groups: The limited group was comprised of mild lesions, which appear isolated and have limited abscesses without sinus tract formations. The severe group was compromised of severe lesions, which included diffuse, multiple abscesses with severe sinus tract formation and fibrosis. Nine sites were limited and 14 sites were severe. After resecting the lesion, the defect was covered with a split-thickness skin graft (four sites were limited, nine sites severe), a musculocutaneous flap (five sites severe), primary closure (four sites limited), and a local skin flap (one site limited). In six sites in 6 severe-group patients, local recurrence occurred. The local recurrence rate differed significantly between the limited and the severe groups. The reason for this may be because the lesions in the limited group could be resected completely, whereas the lesions in the severe group were diffuse and total resection was sometimes difficult for various reasons. The method of surgical repair did not affect the local recurrence rate. In recurrent cases, four sites treated with skin grafting required further surgical treatment, and two sites treated with musculocutaneous flaps were controlled with oral antibiotics. In conclusion, sufficient resection of the lesion is the most important issue in treating follicular occlusion triad disease. In lesions that can be resected completely, the surgical procedure to cover the lesions should be selected to suit the size and site of the defect. However, in cases that cannot be resected completely, a musculocutaneous flap is recommended instead of a skin graft for enhanced postoperative management of the recurring wound, and its contribution to aesthetic and functional improvement.
Reduction or absence of cell-cell adhesion molecules has been reported in various carinomas and the abnormal expression of these molecules contributes to the invasive and metastatic behavior of malignant tumor cells. In epidermal keratinocytes, the main cell-cell adhesion systems are adherens junctions and desmosomes. Previous studies have shown that, in skin carcinomas, the decreased expression of E-cadherin, major constitutional glycoprotein of adherens junctions, is associated with the invasive and metastatic ability of the tumor cells. In the present study, we examined the expression of desmoglein I and plakoglobin, the constitutional components of desmosomes, in various skin carcinomas such as basal cell carcinoma (BCC), squamous cell carcinoma (SCC), extramammary Paget's disease and Bowen's disease by an immunofluorescence method. In normal human skin, desmoglein I and plakoglobin were strongly expressed in the intercellular space of the epidermis except for the basal cell layer. In BCC and SCC, the expression of desmoglein I and plakoglobin was markedly reduced or absent in tumor cells. In carcinoma in situ of Paget's disease, compared with the normal epidermal cells surrounding tumor cell nests, the expression of these molecules was reduced in tumor cells. In Paget's disease with dermal infiltration of tumor cells, the expression of these molecules was almost absent throughout the epidermis. In Bowen's disease, the expression of desmoglein I was reduced in the dumping cells and dyskeratotic cells. These results suggest that the expression of desmosomal cadherin is reduced or absent in human skin carcinomas, and that reduction of these molecules may also contribute to the invasiveness and metastasis of skin carcinomas.
The results suggested that E-cadherin expression decreases in epithelial cells. This decrease may depend on the activity of migration and mitosis. In addition, the change was similar in both the excisional and incisional wounds.
The authors investigated the expression of p53, p21(WAF-1), Bax protein, and apoptosis to elucidate the cellular response to ischemia-reperfusion of skeletal muscle using the rat lower limb model. The rat left lower limb was dissected in the inguinal region, isolating the bony femoral muscles, and the femoral vessels were clamped to produce an ischemic condition. After 3 or 6 hours, the clamps were removed and the gastrocnemius muscle was resected at various times up to 72 hours after reperfusion. Five specimens of the muscle were obtained at each time point from 5 rats. When any rat died during the study, additional rats were used until 5 specimens could be obtained from 5 rats at each time point. The expression of three proteins was detected by Western blot analysis. The apoptotic cells were detected using terminal deoxytransferase-mediated dUDP (deoxyuridine[-5']diphosphate) nick-end labeling assay. Histopathological study showed severe interstitial edema and leukocyte infiltration at 6 hours of ischemia compared with 3 hours of ischemia. Moreover, at 6 hours of ischemia, muscle fiber fragmentation was observed at 72 hours after reperfusion whereas no fragmentation was found at 3 hours of ischemia. At 3 hours of ischemia, p53 and p21(WAF-1) accumulated after reperfusion, and there was a time lag in the time of onset of elevation and the peak time point between these two proteins. The level of Bax protein did not elevate and the rate of apoptotic cells did not increase. At 6 hours of ischemia, p53 and p21(WAF-1) also accumulated, but the kinetics of p21(WAF-1) were similar to that of p53 in the time of onset of elevation and the peak time point after reperfusion. In addition, the level of Bax protein increased and apoptosis was induced. These results demonstrated that p53 and p21(WAF-1) accumulated after 3 and 6 hours of ischemia of skeletal muscle during reperfusion. Moreover, it was demonstrated that the kinetics of induced p53, p21(WAF-1) and Bax protein differ between 3 hours and 6 hours of ischemia, and it is speculated that this difference plays an important role in determining the consequence of the cell exposed to ischemia.
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