Effects of tamoxifen on cardiovascular risk factors in postmenopausal women after 5 years of treatment.

BACKGROUND: Adjuvant tamoxifen therapy for breast cancer has been given for a period of several years. Cardiovascular diseases increased in incidence rapidly in women older than 60 years. Favorable changes in cardiovascular risk factors have been seen with 2 years of tamoxifen therapy, and lower rates of myocardial infarction and of hospitalization for heart disease have been observed in tamoxifen-treated women. PURPOSE: We sought to evaluate changes in risk factors for cardiovascular diseases in postmenopausal women after therapy with tamoxifen for 5 years. METHODS: Five years after their initial entry in a 2-year randomized, placebo-controlled toxicity study, we re-examined 62 of the original 140 disease-free, axillary node-negative postmenopausal breast cancer patients. These 62 patients were women available for study because they had not suffered major illness and had continued on either the tamoxifen or no-tamoxifen regimen to which they had been originally randomly assigned for the entire 5 years. Patient and control blood samples were analyzed for total cholesterol, low-density lipoprotein (LDL) cholesterol, high-density lipoprotein (HDL) cholesterol and subfractions, triglycerides, apolipoprotein AI, apolipoprotein B, lipoprotein(a), fibrinogen, glucose, and platelets. RESULTS: At base line for all measurements except atherogenic lipoprotein [lipoprotein(a)], the 30 long-term tamoxifen recipients and the 32 long-term no-tamoxifen recipients were not significantly different. After 5 years, levels of total serum cholesterol (P < .001), LDL cholesterol (P < .001), and lipoprotein(a) (P = .001) were significantly lower, and apolipoprotein AI levels were significantly higher (P < .001) in the tamoxifen-treated group compared with the no-tamoxifen group. Apolipoprotein B levels increased to a greater extent in the no-tamoxifen than in the tamoxifen group (P < .001). After 5 years, fibrinogen level decrease and triglyceride level increases in the tamoxifen group compared with the no-tamoxifen group were of borderline statistical significance and HDL cholesterol levels were not different in the two groups. CONCLUSION: Favorable changes in lipid, lipoprotein, and fibrinogen levels seen early in tamoxifen therapy in postmenopausal women persist with treatment of 5 years. IMPLICATIONS: The types and magnitude of changes in cardiovascular risk factors seen here with tamoxifen are similar to a certain extent with those seen with estrogen supplements. Further risk-factor and ethnic-group data are needed to estimate the magnitude of expected benefits of tamoxifen treatment on incidence of heart disease.

Protein S and protein C level changes with adjuvant tamoxifen therapy in postmenopausal women.

Tamoxifen citrate is a synthetic antiestrogen that provides survival benefit when given as adjuvant treatment in postmenopausal women with breast cancer. Venous thrombophlebitis may complicate tamoxifen treatment at a rate of approximately one per 800 treatment-years. To explore the possible procoagulant effects associated with tamoxifen therapy we evaluated changes in protein S and C activity levels in 58 postmenopausal women with surgically resected breast cancer who were disease-free and participating in a double-blind, placebo-controlled, randomized toxicity study of tamoxifen. The changes in protein C activities for the tamoxifen group (mean level = 113%) compared to those in the placebo group (mean level = 115%) were not significant (p = 0.45). Protein S activity levels increased while protein C activity levels decreased from baseline at 24 months in both tamoxifen and placebo groups. We conclude that the possible thrombophlebitis-promoting effect of tamoxifen in postmenopausal women is unlikely to be explained on the basis of protein S and protein C activity level changes.

Relating cerebral ischemia and hypoxia to insult intensity.

The contributions of five variables believed to influence the brain's metabolism of O2 during hypoxia [duration, PaO2, delta CMRO2 (the difference between normal and experimental oxygen uptake), O2 availability (blood O2 content.CBF), and O2 deficit (delta CMRO2.duration)] were assessed by stepwise and multiple linear regression. Levels of brain tissue carbohydrates (lactate, glucose, and glycogen) and energy metabolites [ATP, AMP, and creatine phosphate (CrP)] were significantly influenced by O2 deficit during hypoxia, as was final CMRO2. After 60 min of reoxygenation, levels of tissue lactate, glucose, ATP, and AMP were related statistically to the O2 deficit during hypoxia; however, CMRO2 changes were always associated more significantly with O2 availability during hypoxia. Creatine (Cr) and CrP levels in the brain following reoxygenation were correlated more to delta CMRO2 during hypoxia. Changes in some brain carbohydrate (lactate and glucose), energy metabolite (ATP and AMP) levels, and [H+]i induced by complete ischemia were also influenced by O2 deficit. After 60 min of postischemic reoxygenation, brain carbohydrate (lactate, glucose, and glycogen) and energy metabolite (ATP, AMP, CrP, and Cr) correlated with O2 deficit during ischemia. We conclude that "O2 deficit" is an excellent gauge of insult intensity which is related to observed changes in nearly two-thirds of the brain metabolites we studied during and following hypoxia and ischemia.