[Post-transplantation osteoporosis]. / Osteoporosis postrasplante.

In the last two decades organ transplantation has become an effective and established therapy for end-stage disease of various organs. The increase in survival has been due to the greater immunosuppressive capacity of regimens that include cyclosporin. During the first few months after transplantation cyclosporin is associated with high-dose steroids, which produce deleterious effects on bone and mineral metabolism. These effects are superimposed on the previous bone lesions produced by the underlying chronic diseases. Rapid bone loss occurs specially during the first 6 to 12 months after transplantation, when the incidence of fractures is greater. The majority of the fractures involve the spine. Fracture rates are lower after renal transplantation (7 to 11% in nondiabetic renal transplant recipients) and higher in the recipients of other organ transplants: 17.2 to 42% after liver transplantation, 18 to 50% after cardiac transplantation and 25 to 29% after lung transplantation. No pretransplant densitometric or biochemical parameter can adequately predict fracture risk in the individual patient. Despite this, patients with low bone mineral density at the hip, particularly in women, tend to have an increased risk of fracture. Patients can have vertebral fractures despite normal bone mineral density at the spine. Pathogenesis of bone loss is multifactorial. Patients with renal and liver diseases have either renal or hepatic osteodystrophy prior to transplantation that predispose to bone loss, and many patients awaiting pulmonary transplantation already have osteoporosis due to the use of corticosteroids for their lung disease. Rapid bone loss after transplantation depends, as suggested by prospective biochemical parameters, on a decrease in bone formation (reduction in osteocalcin levels) and an increase in bone resorption. Steroids seem to be the principal determinants of these derangements, although some role of cyclosporin cannot be excluded. Other factors that contribute to bone loss are secondary hyperparathyroidism and hypogonadism. Calcium supplementation and vitamin D administration as the only preventive measures do not seem to reduce fracture risk. The most promising regimens to prevent bone loss after transplantation seem to be the use of bisphosphonates immediately prior to and during the first year after transplantation.

Osteoporosis postrasplante. / [Post-transplantation osteoporosis]

In the last two decades organ transplantation has become an effective and established therapy for end-stage disease of various organs. The increase in survival has been due to the greater immunosuppressive capacity of regimens that include cyclosporin. During the first few months after transplantation cyclosporin is associated with high-dose steroids, which produce deleterious effects on bone and mineral metabolism. These effects are superimposed on the previous bone lesions produced by the underlying chronic diseases. Rapid bone loss occurs specially during the first 6 to 12 months after transplantation, when the incidence of fractures is greater. The majority of the fractures involve the spine. Fracture rates are lower after renal transplantation (7 to 11

in nondiabetic renal transplant recipients) and higher in the recipients of other organ transplants: 17.2 to 42

after liver transplantation, 18 to 50

after cardiac transplantation and 25 to 29

after lung transplantation. No pretransplant densitometric or biochemical parameter can adequately predict fracture risk in the individual patient. Despite this, patients with low bone mineral density at the hip, particularly in women, tend to have an increased risk of fracture. Patients can have vertebral fractures despite normal bone mineral density at the spine. Pathogenesis of bone loss is multifactorial. Patients with renal and liver diseases have either renal or hepatic osteodystrophy prior to transplantation that predispose to bone loss, and many patients awaiting pulmonary transplantation already have osteoporosis due to the use of corticosteroids for their lung disease. Rapid bone loss after transplantation depends, as suggested by prospective biochemical parameters, on a decrease in bone formation (reduction in osteocalcin levels) and an increase in bone resorption. Steroids seem to be the principal determinants of these derangements, although some role of cyclosporin cannot be excluded. Other factors that contribute to bone loss are secondary hyperparathyroidism and hypogonadism. Calcium supplementation and vitamin D administration as the only preventive measures do not seem to reduce fracture risk. The most promising regimens to prevent bone loss after transplantation seem to be the use of bisphosphonates immediately prior to and during the first year after transplantation.

Growth hormone-insulin-like growth factor-I axis in adult insulin-dependent diabetic patients: evidence for central hypersensitivity to growth hormone-releasing hormone and peripheral resistance to growth hormone.

The aim of this study was to assess the GH-IGFI axis, GH receptor availability, as reflected by the levels of GH-BP, and the amount of GH-dependent IGFBP-3 in adult IDDM patients with different degrees of metabolic control. Thus, 10 adult well-controlled IDDMs (HbA1 7.8 +/- 0.4%), 10 adult non-ketotic poorly controlled IDDMs (HbA1 13.3 +/- 7%) and 14 sex- and age-matched healthy controls were subjected to two intravenous GH-RH stimulation tests with 0.1 and 1.0 microg/kg body weight respectively, and a plasma IGF-1 generation test induced by the administration of hGH. Poorly controlled IDDM patients exhibited an exaggerated GH response to 1.0 microg/kg of GH-RH when compared to healthy control subjects. Low fasting plasma IGF-1 levels and a blunted IGF-1 response to exogenously administered hGH were also found in poorly controlled IDDMs when compared to the healthy control group. GH-BP levels were significantly lower in IDDMs than in normal controls, and correlated positively with the IGF-1 generation capacity after hGH. Serum IGFBP-3 levels measured by RIA were similar in IDDM and control groups. Good glycemic control for 5.7 +/- 0.9 months did not correct the above mentioned abnormalities of the GH-IGF-1 axis. Our findings suggest that IDDM is associated with a diminished availability of GH receptors and synthesis of IGF-1. GH might then increase as a compensatory mechanism, further down-regulating liver GH receptors, and thus perpetuating the initial abnormality.