Raloxifene

Raloxifene, sold under the brand name Evista among others, is a medication which is used in the prevention and treatment of osteoporosis in postmenopausal women and to reduce the risk of breast cancer in postmenopausal women with osteoporosis or at high risk for breast cancer. It is taken by mouth.

The role of PKN1 in gliomas has rarely been studied. Hao et al. suggest that PKN1 expression in glioma specimens is considerably upregulated and positively correlates with the histopathological grading of gliomas. Knocking down PKN1 expression in glioblastoma (GBM) cells inhibits GBM cell proliferation, invasion, and migration and promotes apoptosis. In addition, yes-associated protein (YAP) expression, an essential effector of the Hippo pathway contributing to the oncogenic role of gliomagenesis, was also downregulated. In contrast, PKN1 upregulation enhances the malignant characteristics of GBM cells and simultaneously upregulates YAP expression. Therefore, PKN1 is a promising therapeutic target for gliomas. Raloxifene (Ralo), a commonly used selective estrogen-receptor modulator to treat osteoporosis in postmenopausal women, was predicted to target PKN1 according to the bioinformatics team from the School of Mathematics, Tianjin Nankai University. They showed that Ralo effectively targets PKN1, inhibits GBM cell proliferation and migration, and sensitizes GBM cells to the major chemotherapeutic drug, Temozolomide. Ralo also reverses the effect of PKN1 on YAP activation. Thus, they confirm that PKN1 contributes to the pathogenesis of gliomas and may be a potential target for Ralo adjuvant glioma treatment ¹⁾.

Choudhary et al., evaluated the effect of raloxifene on prolactin levels in addition to dopamine agonist (DA) therapy in patients with prolactinoma.

They conducted a retrospective chart review of 14 patients with prolactinoma on stable dose of DA for 6 months who received raloxifene 60 mg daily as Prolactin (PRL) could not be normalized despite being on fairly high doses of DA. Patients were informed that raloxifene is not FDA approved for prolactinoma treatment. Prolactin level was measured at 1-6 months after starting raloxifene and at 1-3 months following its discontinuation. Raloxifene was stopped in 8 out of 14 after 2 (1-6) months of treatment as the absolute change in prolactin level was felt to be small. Results The median age and female/male sex ratios were 50 years (range 18-63), 6/8 respectively. The baseline DA dose was 3 mg/week (0.5-7) for cabergoline and 15 mg/day for bromocriptine. 10 patients had an absolute and percentage decrease in prolactin of 8.3 ng/ml (1.5-54.2), and 25.9% (8-55%) from baseline after 1-6 months on raloxifene treatment, respectively. Among 10 patients with a decrease in prolactin level, 2 (20%) achieved prolactin normalization. Two patients had no change in prolactin and two patients had an increase in prolactin level by 22.8 ng/ml and 8.8 ng/ml (47% and 23.6%) respectively.

Raloxifene was associated with 25.9% (8-55%) decrease in prolactin levels in 10/14 (71%) of patients with prolactinoma who were on stable doses of DA including two patients (14%) who achieved normoprolactinemia ²⁾.

Hannen et al., analyzed the effects of fulvestrant and three Selective estrogen receptor modulators (SERMs), bazedoxifene, clomifene, and raloxifene, on pituitary neuroendocrine tumors cell lines AtT20, TtT/GF, and GH3. In cell survival assays, clomifene was shown to be the most potent compound in all three cell lines with IC50 values ranging between 2, 6, and 10 μM, respectively, depending on the cell type. Raloxifene and bazedoxifene were also effective but to a lower extent. Also, all SERMs affected migratory and invasive behavior of pituitary neuroendocrine tumor cells. Mechanistically, treatment of cells with SERMs caused cell apoptosis, as demonstrated by Caspase 3/7 activity and western blot assays. In addition, western blots demonstrate activation of p53 in TtT/GF cells and loss of ERK1/2 activation in AtT20 cells. In contrast, fulvestrant was only effective in GH3 cells. Thus, the general applicability of SERMs for pituitary neuroendocrine tumor cells might be promising in clinical applications for the treatment of pituitary neuroendocrine tumors ³⁾.

The aim of a study was to investigate the ability of a SERM, RLX, to prevent vasospasm in a rabbit model of SAH.

Thirty-four New Zealand white rabbits were allocated into 3 groups randomly. Subarachnoid hemorrhage was induced by injecting autologous blood into the cisterna magna. The treatment groups were as follows: (1) sham operated (no SAH [n = 12]), (2) SAH only (n = 12), and (3) SAH plus RLX (n = 10). Basilar artery lumen areas and arterial wall thickness were measured to assess vasospams in all groups.

There was a statistically significant difference between the mean basilar artery cross-sectional areas and the mean arterial wall thickness measurements of the control and SAH-only groups (P < .05). The difference between the mean basilar artery cross-sectional areas and the mean arterial wall thickness measurements in the RLX-treated group was statistically significant (P < .05). The difference between the SAH group and the SAH + RLX group was also statistically significant (P < .05).

These findings demonstrate that RLX has marked vasodilatatory effect in an experimental model of SAH in rabbits. This observation may have clinical implications suggesting that this SERM drug could be used as possible anti-vasospastic agent in patients without major adverse effects ⁴⁾.

The effect of raloxifene on cerebral vasospasm following experimental subarachnoid hemorrhage (SAH) was investigated in a rat model. Seven groups of seven rats underwent no SAH, no treatment; SAH only; SAH plus vehicle; SAH plus 3 days intraperitoneal raloxifene treatment; SAH plus 4 days intraperitoneal raloxifene treatment; SAH plus 3 days intrathecal raloxifene treatment; and SAH plus 4 days intrathecal raloxifene treatment. The basilar artery cross-sectional areas were measured at 72 or 96 hours following SAH. The results showed raloxifene decreased SAH-induced cerebral vasospasm in all treatment groups, and suggested no difference between intraperitoneal and intrathecal application, or between 3 days and 4 days of raloxifene treatment. The present study demonstrates that raloxifene is a potential therapeutic agent against cerebral vasospasm after SAH ⁵⁾.

To directly test whether exogenous 17beta estradiol and raloxifene affect the number of glial cells in brain, C57BL/6NIA female mice aged 20-24 months received bilateral ovariectomy followed by s.c. placement of a 60-day release pellet containing 17beta estradiol (1.7 mg), raloxifene (10 mg), or placebo (cholesterol). After 60 days, numbers of microglia and astrocytes were quantified in dentate gyrus and CA1 regions of the hippocampal formation using immunocytochemistry and design-based stereology. The results show that long-term 17beta estradiol treatment in aged female mice significantly lowered the numbers of astrocytes and microglial cells in dentate gyrus and CA1 regions compared with placebo. After long-term treatment with raloxifene, a similar reduction was observed in numbers of astrocytes and microglial cells in the hippocampal formation. These findings indicate that estrogen and selective estrogen receptor modulators can influence glial-mediated inflammatory pathways and possibly protect against age- and disease-related neuropathology ⁶⁾.