The association between lung injury and thrombocytopenia was investigated by comparing the megakaryocyte and platelet counts, and platelet activation using P-selectin as a marker, between the prepulmonary (right atrial) and postpulmonary (left atrial) blood in adult and neonatal (preterm and term) rats with and without hyperoxic lung injury. In the healthy controls, the postpulmonary blood had lower megakaryocyte count (prepulmonary versus postpulmonary: Preterm: 8.7[0.6] platelets, p ϭ 0.003). Peripheral platelet and intrapulmonary megakaryocyte counts in the lung-damaged rats were significantly lower than those in their respective controls. Intrapulmonary thrombi or platelet aggregation were detected in the lung-damaged rats but not in the controls. These findings showed that hyperoxic lung damage reduced circulating platelets through (1) failure of the lungs to retain and fragment megakaryocytes to release platelets, and (2) platelet activation leading to platelet aggregation, thrombi formation and platelet consumption. The magnitude of platelet reduction was physiologically significant, as demonstrated by higher counts of megakaryocyte colony forming units in the bone marrow culture of the animals in the hyperoxia group when compared with the controls. Thrombocytopenia is a common complication in neonates and may affect up to 7.6% of all newborns (1, 2). The condition is particularly prevalent in sick infants. In a survey by Castle et al. 58% and 22% of infants receiving intensive care had platelet count Ͻ150ϫ10 9 /L and 100ϫ10 9 /L, respectively (3). Congenital or early onset (Ͻ72 h of birth) neonatal thrombocytopenia may be caused by immunologic causes including isoimmune or maternal autoimmune thrombocytopenia, failure of platelet production such as that in the thrombocytopeniaabsent-radii syndrome, congenital infection, and bone marrow suppression due to maternal hypertension, preeclampsia, and diabetes mellitus (1, 4). The etiology however remains unclear in a large proportion of cases (3, 5, 6). The late onset (Ͼ72 h of birth) type of thrombocytopenia is often attributed to sepsis (7), although an infective cause is often not identifiable in the affected infants. Previous workers have observed that this category of thrombocytopenia is particularly common in newborns with lung disease such as respiratory distress syndrome (5, 8 -11), and the degree of platelet reduction is directly related to the severity of the underlying lung disease, the concentration of inspired oxygen (9, 11), and the ventilation pressure (8, 11). In a study on rabbits, mechanical ventilation
Giant cell tumor of bone (GCT) is a local aggressive neoplasm of bone characterized by expansive osteolytic lesions at the epiphysis of long bones. Bisphosphonates have been used to prevent bone resorption in secondary osteolytic tumors because of their strong anti-osteoclastic action. The authors studied the apoptosis and ultrastructural changes induced in osteoclast-like giant cells of GCT, following treatment with the aminobisphosphonate pamidronate in 16 patients with GCT of bone. Transmission electron microscopy (TEM) was used to identify ultrastructural changes, indicative of apoptosis, in the cytoplasm and the nucleus of the giant cells. Significant changes were observed in tumor samples from all 16 patients. In the cytoplasm these changes were characterized by abundant large tubular vesicles containing a central electrodense core scattered through the cytoplasm. In addition, mitochondria in the sections from pamidronate-treated patients appeared to be edematous when compared with sections from untreated patients. Nuclear changes in the giants cells were characterized by the formation of dense chromatin material scattered throughout the nucleus. The TUNEL labeling assay indicated that the mean pretreatment apoptotic index of 7.8% increased to 53% following pamidronate treatment. This was statistically significant (p<.001) and correlated well with the ultrastructural changes noted on TEM. The formation of abundant tubular vesicles in giant cells following bisphosphonate treatment may reflect disturbed vesicular trafficking and may affect the bone resorbing activity of giant cells.
Giant cell tumor of bone (GCT) is a local aggressive neoplasm of bone characterized by expansive osteolytic lesions at the epiphysis of long bones. Bisphosphonates have been used to prevent bone resorption in secondary osteolytic tumors because of their strong anti-osteoclastic action. The authors studied the apoptosis and ultrastructural changes induced in osteoclast-like giant cells of GCT, following treatment with the aminobisphosphonate pamidronate in 16 patients with GCT of bone. Transmission electron microscopy (TEM) was used to identify ultrastructural changes, indicative of apoptosis, in the cytoplasm and the nucleus of the giant cells. Significant changes were observed in tumor samples from all 16 patients. In the cytoplasm these changes were characterized by abundant large tubular vesicles containing a central electrodense core scattered through the cytoplasm. In addition, mitochondria in the sections from pamidronate-treated patients appeared to be edematous when compared with sections from untreated patients. Nuclear changes in the giants cells were characterized by the formation of dense chromatin material scattered throughout the nucleus. The TUNEL labeling assay indicated that the mean pretreatment apoptotic index of 7.8% increased to 53% following pamidronate treatment. This was statistically significant (p<.001) and correlated well with the ultrastructural changes noted on TEM. The formation of abundant tubular vesicles in giant cells following bisphosphonate treatment may reflect disturbed vesicular trafficking and may affect the bone resorbing activity of giant cells.
Pancreatic development and the relationship of the islets with the pancreatic, hepatic, and bile ducts were studied in the Nile tilapia, Oreochromis niloticus, from hatching to the onset of maturity at 7 months. The number of islets formed during development was counted, using either serial sections or dithizone staining of isolated islets. There was a general increase in islet number with both age and size. Tilapia housed in individual tanks grew more quickly and had more islets than siblings of the same age left in crowded conditions. The pancreas is a compact organ in early development, and at 1 day posthatch (dph) a single principal islet, positive for all hormones tested (insulin, SST-14, SST-28, glucagon, and PYY), is partially surrounded by exocrine pancreas. However, the exocrine pancreas becomes more disseminated in older fish, following blood vessels along the mesenteries and entering the liver to form a hepatopancreas. The epithelium of the pancreatic duct system from the intercalated ducts to the main duct entering the duodenum was positive for glucagon and SST-14 in 8 and 16 dph tilapia. Individual insulin-immunopositive cells were found in one specimen. At this early stage in development, therefore, the pancreatic duct epithelial cells appear to be pluripotent and may give rise to the small islets found near the pancreatic ducts in 16-37 dph tilapia. Glucagon, SST-14, and some PPY-positive enteroendocrine cells were present in the intestine of the 8 dph larva and in the first part of the intestine of the 16 dph juvenile. Glucagon and SST-14-positive inclusions were found in the apical cytoplasm of the mid-gut epithelium of the 16 dph tilapia. These hormones may have been absorbed from the gut lumen, since they are produced in both the pancreatic ducts and the enteroendocrine cells. At least three hepatic ducts join the cystic duct to form the bile duct, which runs alongside the pancreatic duct to the duodenum.
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