[The staged approach--an overview on a strategy to reduce spinal cord injury in thoracoabdominal aortic aneurysm repair]. / Das zweizeitige Vorgehen zur Reduktion der spinalen Ischämie bei der Ausschaltung thorakoabdomineller Aortenaneurysmen - eine Übersicht.

The spinal cord is particularly susceptible to ischaemic injury following repair of extensive descending thoracic and thoracoabdominal aortic aneurysms (TAAA). For the past decade, the Mount Sinai group in New York has intensively studied the anatomy of the extensive vascular network surrounding the spinal cord, as well as its dynamic morphology in response to decreased blood pressure and flow. Along with clinical data, experimental findings gave rise to the Collateral Network Concept, by which spinal cord injury in open TAAA repair can be significantly reduced. With the more recent widespread use of endovascular repair, strategies to prevent ischaemic spinal cord damage after extensive segmental artery sacrifice/occlusion are still evolving. The hypothesis that dividing extensive aneurysm repair into two steps may mitigate the impact of diminished blood flow to the collateral network has led to a recently conducted series of staged repair experiments. By exploiting the resources of the collateral network, spinal cord injury could be minimised in staged open, as well as in staged hybrid repair and seems equally adoptable for endovascular procedures. The contribution presented herein provides an overview of clinical and experimental studies on the staged approach. Furthermore, it briefly assesses the anatomic rationale for the collateral network concept.

Randomized placebo-controlled trial of CDB-2914 in new users of a levonorgestrel-releasing intrauterine system shows only short-lived amelioration of unscheduled bleeding.

BACKGROUND: The levonorgestrel-releasing intrauterine system (LNG-IUS) is a highly effective contraceptive. However, during early months of use unscheduled vaginal bleeding is common, sometimes leading to discontinuation. This study aimed to determine whether intermittent administration of progesterone receptor modulator CDB-2914 would suppress unscheduled bleeding during the first 4 months after insertion of the LNG-IUS. METHODS: CDB-2914 150 mg, in divided doses, or placebo tablets, were administered over three consecutive days starting on Days 21, 49 and 77 after LNG-IUS insertion, in a double-blind randomized controlled trial of women aged 19-49 years, newly starting use of LNG-IUS. Daily bleeding diaries were completed for 6 months, and summarized across blocks as percentage days bleeding/spotting (BS%). RESULTS: Of 69 women randomized to receive CDB-2914, and 67 placebo, 61 and 55, respectively, completed the trial. BS% decreased with time in both arms, but showed a much steeper treatment-phase gradient in the placebo arm (P < 0.0001), so that a benefit of CDB-2914 in the 28 days after first treatment (-11% points, 95% CI -19 to -2), converted to a disadvantage by 64 days after the third treatment (+10% points, 95% CI 1-18). CONCLUSIONS: The effect of CDB-2914 on BS% was initially beneficial but then by third treatment was disadvantageous. Nevertheless, only 3% (4/136) of all women discontinued LNG-IUS. These findings give insight into possible mechanisms and suggest future research directions. ISRCTN Trial no. ISRCTN58283041; EudraCT no. 2006-006511-72.

Progesterone withdrawal up-regulates fibronectin and integrins during menstruation and repair in the rhesus macaque endometrium.

BACKGROUND: Fibronectin (FN) is a component of the extracellular matrix that participates in wound healing in various tissues as an adhesive ligand for integrins (Itgs). To determine whether these molecules play similar roles during menstrual repair, we evaluated the expression and localization of FN and specific Itgs in the primate endometrium under hormonally controlled conditions. METHODS: Ovariectomized rhesus macaques were treated for 2 weeks with estradiol (E(2)) followed by E(2) with progesterone for 2 weeks. On day 28, progesterone was withdrawn and uteri were collected during menstruation, postmenstrual repair, and the proliferative and secretory phases. Analysis was by focused microarray, real time PCR, in situ hybridization and immunocytochemistry. RESULTS: Progesterone withdrawal induced significant elevations of FN, Itg alpha5 and Itg beta1 transcripts during menstruation as compared to day 28 (FN: P < 0.01; Itg alpha5: P < 0.05; Itg beta1: P < 0.05; real time PCR). These increases were concentrated in the glandular epithelium (FN) and stroma (Itg alpha5beta1) of the uppermost zones. Cyclic changes in Itg alpha3 occurred in the glandular epithelium. CONCLUSIONS: Spatially and temporally restricted peaks of expression of FN and its Itg receptors are closely correllated with menstruation and postmenstrual repair in the primate endometrium.

Chronic progesterone antagonist-estradiol therapy suppresses breakthrough bleeding and endometrial proliferation in a menopausal macaque model.

BACKGROUND: Clinicians routinely prescribe progestins along with estrogens during menopausal hormone therapy (HT) to block estrogen-dependent endometrial proliferation. Breakthrough bleeding (BTB) can negate the utility of this treatment. Because progestin antagonists also inhibit estrogen-dependent endometrial proliferation in women and macaques, we used a menopausal macaque model to determine whether a potent progestin antagonist (ZK 230 211, Schering AG; ZK) combined with estrogen would provide a novel mode of HT. METHOD: Ovariectomized rhesus macaques were treated for 5 months with either estradiol (E(2)) alone, E(2) + progesterone (two doses) or E(2) + ZK (0.01, 0.05 or 0.25 mg/kg). RESULTS: In the E(2) + progesterone groups, progesterone suppressed endometrial proliferation and induced a thick decidualized endometrium. In the E(2) + ZK 230 211 groups, all doses of ZK blocked endometrial proliferation and induced endometrial atrophy. In all ZK-treated groups, the atrophied endometrium contained some dilated glands lined by an inactive, flattened, non-mitotic epithelium. BTB was much lower in the E(2) + ZK groups (17 days of spotting, all groups) than in the E(2) and E(2) + progesterone groups (155 bleeding days, all groups). ZK suppressed E(2) effects in the cervix, but not in the vagina, oviduct or mammary glands. All serum chemistry and lipid profiles were normal. CONCLUSION: The ability of ZK to block estrogen-dependent endometrial proliferation, induce endometrial atrophy and suppress BTB in a menopausal macaque model indicates that progestin antagonists may provide a novel mode of HT.

Progesterone receptor localization and isoforms in myometrium, decidua, and fetal membranes from rhesus macaques: evidence for functional progesterone withdrawal at parturition.

OBJECTIVE: It is not known whether withdrawal of progesterone (P) action is a prerequisite for parturition in women or in nonhuman primates because concentrations of circulating progesterone or progesterone receptors (PR) in myometrium and decidua do not decrease before delivery. To examine this potentially important regulatory mechanism, we determined PR isoforms, PR localization, and mRNA in myometrium, decidua, and fetal membranes from rhesus monkeys during pregnancy and in spontaneous labor at term. METHODS: Gestational tissues were obtained midpregnancy (day 80-100), late pregnancy (day 130-145), and during spontaneous labor at term (day 161-167). Samples of rhesus monkey myometrium, decidua, chorion-decidua, and amnion were collected and analyzed for total nuclear and cytosolic PR by competitive binding assay. Progesterone receptor isoforms were identified and quantified by Western blot analysis, and PR mRNA was determined by a specific ribonuclease protection assay. Nuclear PR was localized by immunohistochemistry with monoclonal anti-PR (JZB39) after microwave stabilization. RESULTS: Myometrium and decidua showed no change in total PR during pregnancy and labor. Nuclear PR was not detected in fetal membranes by binding assay but was localized in amnion epithelial and mesenchymal cells and in chorion laeve cytotrophoblasts by immunohistochemistry. Staining for PR was substantially less by serial antibody dilution in fetal membranes than in decidua. Message for PR was confirmed in all tissues analyzed. A significant (P <.05) shift in the ratio of PR isoforms (from PR-B dominance at midpregnancy to PR-A dominance in labor) was observed in myometrium but not in decidua. Both PR-A and PR-B isoforms and PR nuclear staining were nearly undetectable in amnion obtained during labor. CONCLUSION: A shift to PR-A dominance in myometrium at term together with a loss of PR in fetal membranes provides evidence for a functional progesterone withdrawal mechanism, which may facilitate the initiation of parturition in primates.

Reversible suppression of menstruation with progesterone antagonists in rhesus macaques.

BACKGROUND: A reliable means of menstrual suppression would greatly improve the quality of life for women. Information is lacking on the direct endometrial effects and appropriate dosages of new antiprogestins that may be useful for this purpose. METHODS: The current work evaluated three different systems in macaque monkeys. First, the range of doses of two relatively new antiprogestins, ZK 137 316 and ZK 230 211, that would block progesterone action directly on the endometrium in artificially cycled, spayed rhesus macaques; second, the direct endometrial effects of ZK 230 211, a type III antiprogestin; and third, investigation of whether endometrial-suppressive doses administered chronically to intact, cycling monkeys could be used for reversible, menstrual suppression. RESULTS: The results in naturally cycling animals showed that ZK 137 316 blocked menstruation in all animals, but doses of 0.05 mg/kg blocked ovulation in 55.5% of animals and doses of 0.1 mg/kg blocked ovulation in 66.6% of the animals. However, all doses of ZK 230 211 that blocked menstruation also blocked ovulation. All progesterone antagonist (PA)-treated animals, regardless of dose, maintained normal follicular phase concentrations of oestradiol and returned to normal menstrual cyclicity within 15--41 days post-treatment. Therefore ZK 137 316, depending on dose, can allow ovulation but block menstruation, while ZK 230 211, a much more potent PA, blocks both ovulation and menstruation at all effective doses. Both PAs block unopposed oestrogenic action on the endometrium through their antiproliferative effects. CONCLUSIONS: Reversible amenorrhoea can be achieved with these two PAs, and they can protect the endometrium from the effects of unopposed oestrogen whether or not ovulation is blocked. Chronic, low dose PA treatment may provide a new option for women who wish to suppress their menstrual periods.

Progesterone antagonists increase androgen receptor expression in the rhesus macaque and human endometrium.

Antiprogestins (APs) inhibit estradiol (E(2))-stimulated endometrial growth in women and nonhuman primates, but the mechanism of this "antiestrogenic" action is unknown. Here, we report that APs up-regulate endometrial androgen receptor (AR) in both women and macaques, an effect that might play a role in the antiproliferative effects of APs on the primate endometrium. In addition, because there are discrepancies in the literature on the regulation and localization of AR in the primate endometrium, we used both in situ hybridization and immunocytochemistry to evaluate hormonal influences on endometrial AR in women and macaques. In ovariectomized macaques, the following treatments were given for 4 weeks each: E(2) alone, E(2) + progesterone (P), E(2) + mifepristone (RU 486), and E(2) + P + RU 486. In women, samples were obtained during the normal menstrual cycle and after treatment with either RU 486 for 30 days at 2 mg/day, or after a single oral administration of 200 mg RU 486 on cycle day LH + 2. In macaques, E(2) significantly increased AR expression above vehicle controls; E(2) + RU 486 increased binding further; E(2) + P decreased AR binding; and E(2) + P + RU 486 treatment caused an intermediate elevation in AR binding. In macaques treated with E(2) alone, stromal AR staining was predominant, and P treatment suppressed that staining. E(2) + RU 486 or E(2) + P + RU 486 treatment produced a striking up-regulation of glandular epithelial AR staining and enhanced the stromal AR signal. In situ hybridization analyses confirmed the immunocytochemistry data. Similar induction of glandular AR staining and enhanced stromal AR staining were obtained in macaques treated with ZK 137 316 and ZK 230 211. During the natural cycle in women, stromal AR staining predominated and was greater in the proliferative than the late secretory phase. RU 486 treatment of women up-regulated glandular epithelial AR staining after either daily treatment for 30 days with 2 mg/day or after a single oral dose of 200 mg. In summary, endometrial AR was highest in the stroma during the human proliferative phase (or during E(2) treatment in macaques) and lowest during the late secretory phase in women (or after E(2) + P treatment in macaques). In both species, RU 486 induced AR expression in the glands and enhanced AR expression in stromal cells. Because androgens can antagonize E(2) action, enhanced endometrial AR expression induced by APs could play a role in the antiproliferative, "antiestrogenic" effects of APs in primates.

Estrogen receptor beta, but not estrogen receptor alpha, is present in the vascular endothelium of the human and nonhuman primate endometrium.

Estrogen action is dependent upon the presence of specific ligand-activated receptors in target tissues. The aim of the present experiments was to compare the spatial and temporal pattern of expression of estrogen receptor beta (ERbeta) with that of ERalpha in full thickness endometrial samples (from the superficial to the basal zone) obtained from both women and rhesus macaques. Immunohistochemical localization with specific antibodies revealed that ERalpha and ERbeta were both expressed in nuclei of the glands and stroma. Consistent with previous studies, expression of ERalpha declined in the glands and stroma of the functionalis during the secretory phase. The luminal epithelium also displayed positive immunoreactivity for ERbeta. Expression of ERbeta declined in glandular cell nuclei, but not stroma, within the functionalis during the late secretory phase. Levels of expression of ERalpha and ERbeta in all cellular compartments remained unchanged in the basalis. Both receptor subtypes were detected on Western blots using proteins extracted from uterine samples obtained throughout the menstrual cycle. There was a striking contrast between the pattern of expression of ERalpha and ERbeta in the vascular endothelium and the perivascular cells surrounding endometrial blood vessels; only ERbeta was present in the endothelial cell population, although both forms of ER were expressed in perivascular cells. We conclude that estrogen action(s) within the vascular endothelium in the endometrium may be mediated via direct binding to the ERbeta isoform and that these cells could therefore be a target for agonists or antagonists that selectively target the beta form of the ER.

The endocrinology of menstruation--a role for the immune system.

The human endometrium displays characteristic features, both structural and functional, across the menstrual cycle. It is the sex steroid hormones, oestrogen and progesterone, that drive the endometrium through the different phases of the cycle. Oestrogen and progesterone act sequentially to regulate cellular concentrations of their respective receptors, this interaction initiates gene transcription. Thereafter a cascade of local events prepares the endometrium for implantation, but in the absence of pregnancy, progesterone withdrawal leads to menstruation and cyclic repair. Withdrawal of progesterone from an oestrogen-progesterone primed endometrium is the initiating event for the cascade of molecular and cellular interactions that result in menstruation. Progesterone withdrawal first affects cells with progesterone receptors. Early events in the menstrual process are vasoconstriction and cytokine up-regulation. The activation of lytic mechanisms is a later event and involves cells that may lack progesterone receptors, for example, uterine leucocytes and epithelial cells. Hence progesterone withdrawal results in a local increase of inflammatory mediators and the enzymes responsible for tissue breakdown. The total complex of local factors implicated in normal menstrual and aberrant menstrual bleeding are yet to be fully defined.

Antiproliferative effects of progesterone antagonists and progesterone receptor modulators on the endometrium.

Progesterone antagonists (PAs, antiprogestins) can modulate estrogenic effects in various estrogen-dependent tissues. These modulatory effects are complex and depend on species, tissue, type of compound, dose, and duration of treatment. In non-human primates, PAs, including mifepristone, ZK 137 316 and ZK 230 211, inhibit endometrial proliferation and induce amenorrhea. When administered chronically at relatively low doses, these compounds block the mitotic activity of endometrial epithelium and induce stromal compaction in a dose-dependent manner in both spayed and intact monkeys at high estradiol concentrations. These effects were accompanied by an atrophy of spiral arteries. The antiproliferative effects were endometrium-specific, since the estrogenic effects in the oviduct and vagina were not inhibited by PAs. Similar endometrial antiproliferative effects were also found after treatment with the progesterone receptor modulator (PRM), mesoprogestin J1042. The endometrial antiproliferative effects of PAs, particularly within the endometrial glands, were also observed in spayed rabbits. In spayed rats, however, the PAs did not inhibit, but rather enhanced, various estrogen responses, including endometrial proliferation, pointing to species-specific differences. In conclusion, our studies indicate that both pure PAs and PRMs selectively inhibit estrogen-dependent endometrial proliferation in the primate endometrium without affecting estrogenic response in other estrogen-dependent tissues or inducing unscheduled bleeding. Our studies indicate that the spiral arteries, which are unique to the primate endometrium, are the primary targets that are damaged or inhibited by PAs and PRMs. The damage to these unique vessels may underlay the paradoxical, endometrium-specific, antiproliferative effects of these compounds. Hence, the properties of PAs and PRMs (mesoprogestins) open up new applications in gynecological therapy and hormone replacement therapy.

Progesterone withdrawal up-regulates vascular endothelial growth factor receptor type 2 in the superficial zone stroma of the human and macaque endometrium: potential relevance to menstruation.

Several reports indicate that vascular endothelial growth factor (VEGF) expression is increased in endometrial glands and stroma during the menstrual phase in the human endometrium. Here we report that VEGF receptor type 2 (KDR), normally expressed only in the vascular endothelium, was dramatically up-regulated in the stromal cells of the superficial endometrial zones during the premenstrual phase in both human and macaque endometrium. This increase was detectable by Northern analysis, in situ hybridization, and immunocytochemistry and was cell specific, zone specific, cycle phase specific, and VEGF receptor type specific. That is, it only occurred during the premenstrual/menstrual phase, did not occur in glandular epithelium, endothelium, or stromal cells of the deepest endometrial zones, and was not observed for VEGF receptor type 1. The upregulation of stromal KDR was induced by progesterone (P) withdrawal in both women and macaques, and adding back P 24 h after P withdrawal in macaques blocked stromal, but not vascular, endothelial KDR expression. Promatrix metalloproteinase-1 (MMP-1) was coordinately up-regulated in the same stromal cell population by P withdrawal. Because of reports that VEGF can enhance MMP expression, we hypothesize that VEGF-KDR interactions may influence MMP expression in the superficial zones of the primate endometrium during the premenstrual phase, and that these interactions play a role in the induction of menstruation.

Effects of keratinocyte growth factor in the endometrium of rhesus macaques during the luteal-follicular transition.

We previously reported that keratinocyte growth factor (KGF) is up-regulated by the action of progesterone (P) in the primate endometrium, and we suggested that this protein is a likely mediator of P-dependent stromal-epithelial paracrine interactions in this tissue. At the end of the menstrual cycle, P levels fall, and the abundance of endometrial KGF transcripts decreases approximately 9-fold. In macaques, withdrawal of P induces the luteal-follicular transition (LFT), marked by menstrual sloughing of the functionalis zone and apoptotic regression of the basalis zone. Because KGF levels fall so dramatically during the LFT, we hypothesized that replacement with exogenous KGF during the LFT would prevent some of the endometrial changes seen after P withdrawal. Here we describe two studies of the effects of exogenously administered KGF during the LFT in rhesus macaques. In one experiment we administered KGF systemically to ovariectomized, juvenile rhesus macaques during an LFT induced by hormonal manipulations. KGF had dramatic proliferative effects on the bladder and salivary glands, known targets of KGF, but did not affect cell proliferation in the endometrium or block menstrual sloughing and bleeding. However, KGF strongly inhibited apoptosis in the basalis zone, increased glandular sacculation and folding in this zone, and had a marked trophic effect on the spiral arteries. In the second experiment we installed oviductal catheters in ovariectomized adult rhesus macaques and infused KGF directly into the uterine lumen during a hormonally induced LFT. Again, arteriotrophic, antiapoptotic, and basalis gland sacculation effects were observed in the absence of any effect on cell proliferation. We concluded that although KGF is mitogenic for many epithelial cell types, it does not play this role in the primate endometrium. Its most important roles may be to stimulate spiral artery growth and inhibit glandular apoptosis during the nonfertile menstrual cycle. Because its expression rises coincident with the time of implantation and because spiral arteries are essential to successful establishment of pregnancy, the role of KGF in the fertile menstrual cycle deserves further study.

Matrix metalloproteinase expression in Macaca mulatta endometrium: evidence for zone-specific regulatory tissue gradients.

Matrix metalloproteinases (MMPs) are highly expressed in the human endometrium during menstruation, and these enzymes participate in the cyclic destruction and regeneration characteristic of the primate endometrium. To examine hormonal regulation of MMPs in vivo, we evaluated MMP expression and localization in the endometrium of ovariectomized rhesus macaques under various hormonal conditions. Although all MMPs were up-regulated by progesterone (P4) withdrawal, their expression declined spontaneously after menstruation in the absence of P4. Of 7 MMPs examined, only matrilysin and stromelysin-3 were suppressed any further when P4 levels were experimentally re-elevated. MMP expression was confined to the upper functionalis zone during menstruation, but after menstrual breakdown was complete, matrilysin and the tissue inhibitor of MMPs, TIMP-1, shifted expression from the functionalis to the basalis zone in the absence of both estradiol and P4. The spiral arteries in the functionalis, but not the basalis, were intense foci of MMP and TIMP-1 expression. Menstruation and MMP expression after P4 withdrawal were similar in both the presence and absence of estradiol. In sum, endometrial MMPs in vivo are strongly up-regulated by P4 withdrawal, but zone-specific tissue gradients greatly influence the pattern and degree of MMP expression.

A chronic, low-dose regimen of the antiprogestin ZK 137 316 prevents pregnancy in rhesus monkeys.

Continual administration of low doses of the antiprogestin ZK 137 316 was previously reported to permit ovarian/menstrual cyclicity, but disrupt endometrial growth in macaques. The contraceptive efficacy of this regimen was tested in female rhesus monkeys (10 per group) treated daily with vehicle (controls), 0.01 or 0.03 mg ZK 137 316 per kg body weight for 30 days before and during continual co-habitation with males of proven fertility. Treatment continued until confirmation of pregnancy or for 5 months after pair-housing with males. Mating and vaginal sperm were evident in all females. A cumulative pregnancy rate of 90% (9/10) was observed in the controls. Of the 10 animals receiving 0.01 mg/kg, four conceived during the first 2 months of pairing (P = 0.06) with no further conceptions. No pregnancies were observed in the 0.03 mg/kg group (P < 0.01). Timely, overt menses occurred at a higher frequency in the 0.01 mg/kg group than the 0.03 mg/kg group. However, corpora lutea were present in ovaries from both groups during the last treatment cycle, indicating that ovarian cycles occurred. Thus, chronic administration of low-dose ZK 137 316 that permits continued ovarian cyclicity and a high incidence of timely menses, prevents pregnancy in non-human primates. This regimen may provide a novel method of contraception for women.

Chronic treatment of female rhesus monkeys with low doses of the antiprogestin ZK 137 316: establishment of a regimen that permits normal menstrual cyclicity.

Large doses of antiprogestin typically disrupt menstrual cyclicity. A chronic low-dose regimen of the potent new antiprogestin ZK 137 316, which permits continued menstrual cyclicity but alters gonadal-reproductive tract activity, was established. Rhesus monkeys received vehicle (n = 6) or 0.01 (n = 8), 0.03 (n = 8) or 0.1 (n = 5) mg ZK 137 316/kg body weight daily for five menstrual cycles (C-1 to C-5). Oestradiol, progesterone and gonadotrophin profiles were normal during cycles involving vehicle and 0.01 and 0.03 mg ZK 137 316/kg body weight. In the 0.1 mg/kg group, mid-cycle oestradiol and gonadotrophin surges, and subsequent progesterone production, were absent in C-3 and C-5. Ovarian cyclicity was accompanied by timely menstruation in the vehicle and 0.01 mg/kg groups. By C-3, half the animals in the 0.03 mg/kg group and all animals in the 0.1 mg/kg group were amenorrhoeic. A corpus luteum was noted during the mid-luteal phase of C-5 in the vehicle, 0.01 mg/kg and 0.03 mg/kg groups. Large antral and cystic follicles were evident in the 0.1 mg/kg group. Thus, a daily treatment with 0.01 mg/kg ZK 136317 permitted normal menstrual cyclicity in macaques. While the daily administration of 0.03 mg/kg ZK 136 317 allowed ovarian cyclicity, menstruation was disrupted in some animals. Increasing the dose to 0.1 mg/kg antagonized pituitary function and resulted in anovulation and amenorrhoea. A chronic low-dose regimen of the antiprogestin ZK 137 316, which permits normal ovarian/menstrual cyclicity, has potential as a contraceptive in women.

Chronic treatment of cycling rhesus monkeys with low doses of the antiprogestin ZK 137 316: morphometric assessment of the uterus and oviduct.

The long-term effects of the antiprogestin ZK 137 316 on reproductive tract morphology in rhesus macaques were investigated. The monkeys were injected daily (i.m.) for five menstrual cycles with vehicle or 0.01, 0.03 or 0.1 mg ZK 137 316/kg body weight. Reproductive tracts (n = 3/ group) were collected during the mid-luteal phase (day 8) of the fifth cycle in the control, 0.01 and 0.03 mg/kg groups, or 6-7 days after the oestradiol peak in the 0.1 mg/kg group. ZK 137 316 treatment resulted in a dose-dependent atrophy of the endometrium, marked by reduced mitotic activity in the glands, compaction of the stroma, degradation of spiral arteries and dilation of veins. There was no effect of ZK 137 316 on myometrial or oviductal weight. Treatment with 0.1 and 0.03 mg/kg, but not 0.01 mg/kg resulted in fully ciliated and secretory oviducts, indicating a dose-dependent blockade of progesterone antagonism of oestrogen-dependent oviductal differentiation. In the endometrium, the suppressive action of progesterone on oestrogen and progestin receptors was also blocked by ZK 137 316 in a dose-dependent manner. However, endometrial atrophy appeared due to inhibition of progesterone action together with a blockade of oestrogen-dependent proliferation. The profoundly suppressed endometrium produced by chronic low-dose ZK 137 316 treatment is unlikely to support implantation. Such treatment may therefore provide a novel contraceptive modality.

The rise and fall of atrial natriuretic peptide for acute renal failure.

Atrial natriuretic peptide can increase glomerular filtration rate and filtration fraction and can promote natriuresis, effects that would logically seem to improve renal function after acute tubular necrosis from ischemic or toxic injury. Early human trials suggested a beneficial effect of atrial natriuretic peptide on creatinine clearance, and a reduction in the need for dialysis in treated patients. However, randomized, placebo-controlled trials have failed to show a clinically relevant benefit on survival, dialysis-free survival, or renal function in patients treated with this agent.