HDL concentration, lipid transfer to HDL, and HDL size in normolipidemic nonobese menopausal women.

OBJECTIVE: To determine the impact of menopause on lipid transfer from donor lipoproteins to high-density lipoproteins (HDLs) -- a process that is related to the protective function of HDL -- and the size of HDL particles. METHOD: Plasma from 22 premenopausal and 18 postmenopausal nonobese, normolipidemic women paired for age (40-50 years) was incubated in an artificial nanoemulsion labeled with radioactive lipids. Then the HDL fraction was assessed for radioactivity; the percentage of radioactive lipids transferred from the nanoemulsion to HDL was determined; and the size of HDL particles was measured by laser light scattering. RESULTS: There were no differences between the 2 groups in serum concentration of HDL cholesterol (61+/-12 mg/dL vs 61+/-14 mg/dL) or apolipoprotein A(1) (1.5+/-0.3 g/L vs 1.5+/-0.2 g/L); lipid transfer to HDL; or size of HDL particles (8.8+/-0.8 vs 9.0+/-0.5 nm). CONCLUSION: Menopause was not found to affect HDL cholesterol plasma concentration, lipid transfer to HDL, or size of HDL particles in normolipidemic nonobese women.

Effects in post-menopausal women of transdermal estrogen associated with progestin upon the removal from the plasma of a microemulsion that resembles low-density lipoprotein (LDL).

OBJECTIVE: To evaluate the effects of transdermal estradiol and medroxyprogesterone acetate (MPA) treatment on the removal from the plasma of a cholesterol-rich microemulsion (LDE) that roughly resembles low-density lipoprotein (LDL) structure and that binds to LDL receptors. METHODS: Ten healthy post-menopausal women were studied before and after 3-month treatment with transdermal estradiol in the following dosages administered every 3.5 days: 25, 50, 50, 100, 100, 50, 50 and 25 microg. From the 15th to the 21st day and from the 22nd to the 28th day of estrogen treatment, respectively, 10 and 5 mg q.d. MPA per oral were associated to the transdermal estrogen. The emulsion labeled with 14C-cholesteryl oleate was injected after 12 h fasting and its fractional catabolic rate (FCR) was calculated from the plasma decaying curves of the isotope. RESULTS: Treatment reduced LDL-cholesterol levels by 8% only (149.0 +/- 36.0 mg/dl, 138.0 +/- 27.0 mg/dl; P = 0.046), but the FCR of LDE expressed in medians (25%; 75%) increased from 0.0054 (0.003; 0.052) h(-1) to 0.021 (0.009; 0.10) h(-1), P = 0.002. CONCLUSION: The association used in this study so as to mimic the increasing-decreasing pattern of the hormonal ovarian production reduced modestly LDL-cholesterol levels but pronouncedly increased the lipoprotein removal as tested by LDE FCR.

Association of carmustine with a lipid emulsion: in vitro, in vivo and preliminary studies in cancer patients.

PURPOSE: We had previously shown in acute leukemia and in breast and ovary carcinoma patients that a cholesterol-rich emulsion (LDE) that binds to receptors for low-density lipoprotein (LDL) may concentrate in neoplastic tissues. In this study, the potential of LDE as a carrier for anticancer drugs was investigated. METHODS: LDE was associated with carmustine, and the cytotoxicity of the LDE-carmustine complex was studied in a neoplastic cell line and its biodistribution was studied in mice. The plasma kinetics of the complex and its uptake by tumor and normal tissue were determined in cancer patients. Finally, an exploratory clinical study to determine the toxicity profile of LDE-carmustine at escalating dose levels was conducted in 42 advanced cancer patients refractory to conventional chemotherapy. RESULTS: Carmustine formed a stable association with LDE. The pharmacological action of carmustine, as tested in cancer cells, was not diminished by association with LDE compared with the free drug and was indeed mediated by the LDL receptor. The biodistribution in mice and plasma kinetics in patients of the emulsion were not changed by association of the drug. The uptake of LDE-carmustine by tumor was severalfold greater than the uptake by the corresponding normal tissue. Finally, patients treated with LDE-carmustine showed negligible side effects even at very high dose levels. CONCLUSIONS: Association with LDE preserves the cytotoxicity of carmustine and markedly diminishes its side effects.

Metabolism of a cholesterol-rich microemulsion (LDE) in patients with multiple myeloma and a preliminary clinical study of LDE as a drug vehicle for the treatment of the disease.

PURPOSE: Previously we have shown that cholesterol-rich microemulsions that bind to LDL receptors have the ability to concentrate in acute myeloid leukemia cells and in ovarian and breast carcinomas. Thus, LDE may be used as a vehicle for drugs directed against neoplastic cells. Indeed, we subsequently showed that when carmustine is associated with LDE the toxicity of the drug is significantly reduced in patients with advanced cancers. The aim of the present study was to verify whether LDE may be taken up by multiple myeloma cells and whether patients with multiple myeloma respond to treatment with LDE associated with carmustine. METHODS: A total of 131 consecutive volunteer patients with recently diagnosed multiple myeloma classified as clinical stage IIIA had their plasma lipid profile determined. LDE plasma kinetics were performed in 14 of them. Cell uptake of LDE and the cytotoxicity of carmustine associated with the emulsion were evaluated in a multiple myeloma cell line. A pharmacokinetic study of LDE-carmustine was performed in three patients. Finally, an exploratory clinical study of LDE-carmustine (carmustine dose 180 mg/m(2) body surface every 4 weeks) was performed in seven untreated multiple myeloma patients. RESULTS: LDL cholesterol was lower in the 131 multiple myeloma patients than in healthy controls and the fractional clearance rate (FCR, in units per minute) in the 14 multiple myeloma patients was twice that in 14 paired healthy control subjects. Moreover, entry of LDE into multiple myeloma cells was shown to be mediated by LDL receptors. Taken together, these findings indicate that LDE may target multiple myeloma. The exploratory clinical study showed that gammaglobulin decreased by 10-70% (mean 36%) after three cycles and by 25-75% (mean 44%) after six cycles. Furthermore, there was amelioration of symptoms in all patients. Cholesterol concentrations increased after treatment, suggesting that the treatment resulted in at least partial destruction of neoplastic cells with receptor upregulation. Side effects of the treatment were negligible. CONCLUSIONS: Because it targets multiple myeloma and, when associated with an antineoplastic agent, produces therapeutic responses in patients with fewer side effects, LDE has the potential for use as a drug vehicle in the treatment of the disease.