Triple-flap medial canthal reconstruction.

A patient with a medial facial defect, following oncological resection involving the medial canthus, nose, upper and lower eyelids, and the cheek, is presented. The defect was reconstructed using a combination of local flaps to provide tissue similar to native tissue, addressing both functional and aesthetic aspects.

Evidence for diverse pathways of hypophysiotropic hormone transport in mammals.

Comparative studies of mammalian hypothalamic-pituitary relationships have revealed striking variations in hypophysiotropic systems and in portal vascular architecture. Immunocytochemical studies indicate that mammalian GnRH, GHRH and somatostatin systems can project to all portions of the neurohypophysis (median eminence, infundibular stem and pituitary neural lobe). In rats, primary secretion sites are located within the median eminence and upper infundibular stem, whereas in bats, most projections extend into the lower infundibular stem and pituitary neural lobe. In ferrets and monkeys, sites of secretion appear to extend throughout the neurohypophysis, from median eminence to proximal neural lobe. In this review, these interspecific differences are examined in light of observed structural variations in portal vascular systems. Correlations suggest that hypophysiotropic hormones can be delivered to target cells in the pars distalis by diverse routes, with some species relying more heavily on long and others on short portal transport. These patterns may have important functional implications with respect to regulatory mechanisms operating within the hypothalamic-pituitary complex.

Fine structural characteristics of the zone of contact between the lower infundibular stem and the pituitary pars distalis in the little brown bat, Myotis lucifugus.

The purpose of this study was to examine the morphological characteristics of the pituitary gland in the little brown bat that might influence mechanisms of hypothalamic releasing hormone transport. Paraffin sections were prepared from whole crania to examine in situ the orientations of the three parts of the adenohypophysis (pars distalis, pars intermedia, and pars tuberalis) relative to the components of the neurohypophysis (pars nervosa and infundibular stem) and the basal hypothalamus. Of particular interest was the observation that the axis of the infundibular stem is directed posteriorly from the median eminence and occupies a depression in the dorsal surface of the pars distalis as it approaches the pars nervosa. Previous studies have revealed that neuronal projections containing releasing hormones extend into the infundibular stem in this species. Therefore, we conducted a fine structural study to determine whether the zone of contact between the infundibular stem and the pars distalis could represent a site of specialized interaction between hypophysiotropic hormones and their target cells. The results show that the sparse connective tissue along this boundary contains abundant fenestrated capillaries that are exposed on one side to neurosecretory axons and on the other to cells of the pars distalis. Furthermore, secretory cells nearest these capillaries exhibit ultrastructural evidence of heightened secretory activity. We conclude that the fine structural characteristics of this zone are consistent with localized mechanisms of releasing hormone transport.

Immunocytochemical localization of growth hormone and growth hormone-releasing hormone immunoreactivity in the brain and pituitary of the little brown bat.

Anterior pituitary cells exhibiting growth hormone (GH) immunoreactivity and forebrain neurons containing growth hormone-releasing hormone (GHRH) immunoreactivity were identified in little brown bats (Myotis lucifugus) using light microscopic immunocytochemistry. Pituitary somatotropes appeared as ovoid or polyhedral cells that were distributed throughout most of the pars distalis, with the exception of its most rostral region where this cell type was scarce. GH-immunoreactive cells occupied approximately one-third of the total volume of the pars distalis; this proportion did not differ significantly between males and females or in bats collected at different times of year. Neuronal perikarya containing immunoreactive GHRH were observed in the hypothalamic arcuate and suprachiasmatic nuclei, as well as in the cortical and subcortical telencephalon. Fibers were most evident in the median eminence, paraventricular and periventricular nuclei, and molecular layer of the cerebral cortex. Fine fibers were also accumulated in the bed nucleus of the stria terminalis and in the amygdala.

Vaginocervical stimulation of ferrets induces release of luteinizing hormone-releasing hormone.

Abstract Vaginocervical stimulation of ovariectomized estradiol-primed ferrets (which are reflex ovulators) with a glass rod in the presence of a neck-gripping male induced an increase in plasma luteinizing hormone (LH) from undetectable levels (

Dynamic aspects of the LHRH system associated with ovulation in the little brown bat (Myotis lucifugus).

Adult female bats were collected from natural roosting sites in pre-ovulatory and post-ovulatory conditions. LHRH neurones of these animals were examined using light and electron microscopic immunocytochemistry, and LHRH tissue contents were measured by radioimmunoassay. Comparisons between the two groups of bats revealed that the number of LHRH perikarya detected immunocytochemically, as well as hypothalamic LHRH content, were significantly reduced in post-ovulatory animals. Distributions of immunoreactive perikarya were, however, strikingly similar in both groups. The reduction in immunoreactive cell number observed after ovulation was therefore not restricted to an anatomically defined subset of neurones, but was evident throughout the population. The projection of LHRH-immunoreactive fibres that extend into the pituitary neural lobe in this species also exhibited changes related to endocrine condition. Morphometric indices of fibre density in the neural lobe were significantly reduced in post-ovulatory bats, as was LHRH content of the lower infundibular stalk and neural lobe. Fine structural study of perikarya revealed complex anatomical interactions between LHRH-immunopositive elements, especially in post-ovulatory bats. These interactions included direct apposition of perikarya, as well as more elaborate networks involving various combinations of perikarya and large- and small-caliber processes. These changes in the LHRH system associated with ovulation suggest reduction of stored peptide within perikarya and depletion from terminals within the lower infundibular stem and neural lobe. Parallel reductions in hypothalamic and neural lobe LHRH content during the periovulatory period support the hypothesis that the neural lobe component of the system contributes to control of gonadotrophin secretion in this species. Finally, increased complexity of anatomical contact between components of the LHRH system may be related to activation of this cell population in spring.

Neuronal systems immunoreactive with antiserum to lamprey gonadotropin-releasing hormone in the brain of Petromyzon marinus.

The role of gonadotropin-releasing hormone (GnRH) in mammalian reproduction has been studied extensively; however, the role of a structurally different, but related, decapeptide is not well characterized in the most primitive class of vertebrates, Agnatha. Utilizing an antiserum directed to the recently characterized lamprey GnRH, we examined immunoreactive neuronal perikarya and nerve fibers in sections from the brain of the sea lamprey, Petromyzon marinus, using the unlabeled peroxidase-antiperoxidase method. Neuronal perikarya and fibers were immunopositive with antisera generated to lamprey GnRH and also to certain antisera generated to mammalian GnRH. Immunopositive neuronal perikarya were detected in an arc-shaped population extending from ventral to dorsal preoptic areas. Fibers from these cells projected to the neurohypophysis via the preoptico-hypophyseal tract, but in addition also protruded into the third ventricle. Additionally, some fibers coursed along the external surface of the brain, and may also release GnRH into meningeal compartments. The presence of fully processed, mature decapeptide is indicated within neuronal perikarya, as well as in projecting nerve fibers and terminals. No reaction product was detected in sections incubated with an antiserum to the interior amino acid sequences of mammalian LHRH. This finding supports the structure reported for lamprey GnRH by Sherwood et al. (1986).

GRF immunoreactive neurons in the paraventricular nucleus of the rat: an immunohistochemical study with monoclonal and polyclonal antibodies.

Our study demonstrates a complex GRF neuronal system within the rat hypothalamus. Using both high affinity polyclonal and high specificity monoclonal antibodies to rat (r) GRF, we have substantiated evidence for immunoreactive GRF (GRF-i) perikarya in the parvocellular portion of the paraventricular nucleus. Other hypothalamic areas containing rGRF-positive perikarya include the lateral arcuate nucleus, lateral hypothalamus, perifornical area and dorsomedial nucleus. GRF-i neuronal terminals were seen in the external zone of the median eminence, more rostrally in the periventricular nucleus, and near the suprachiasmatic nucleus and more caudally in the dorsomedial nucleus and ventral premammillary nucleus.

Characterization of LH-RH immunoreactivity in mammalian pituitary neural lobe by HPLC.

High performance liquid chromatography was used to characterize luteinizing hormone-releasing hormone (LH-RH) immunoreactivity that was previously identified immunocytochemically in the pituitary neural lobes of bats, ferrets and humans. Extracts of bat posterior lobe and hypothalamus, ferret posterior lobe and hypothalamus and human neurohypophysis were partially purified with C-18 Bond-Elut cartridges. Samples were chromatographed using a C-18 reverse phase HPLC column, and LH-RH-immunoreactive moieties were separated by gradient elution (TFA/acetonitrile solvent system). For bats and ferrets, the major peak of neural lobe LH-RH immunoreactivity eluted with a retention time identical to that of hypothalamic LH-RH. Synthetic mammalian standard added to bat and ferret hypothalamic extracts coeluted as a single peak with the predominant form of LH-RH immunoreactivity present in those tissues. In humans, the peak of LH-RH immunoreactivity in neural lobe extracts coeluted with synthetic standard. These results provide strong evidence that the LH-RH-immunoreactive fibers which terminate within the neural lobe contain authentic LH-RH. Additional minor peaks of LH-RH immunoreactivity were observed in posterior lobe and hypothalamic extracts of both bats and ferrets. Comparisons of posterior lobe content of LH-RH immunoreactivity across species verify that the neural lobe projection is a major component of the LH-RH system in bats, whereas it is represented only minimally in the laboratory rat.

Morphological evidence that luteinizing hormone-releasing hormone neurons participate in the suppression by estradiol of pituitary luteinizing hormone secretion in ovariectomized rats.

Morphological characteristics of LHRH neurons identified by immunocytochemistry were studied using light and electron microscopy in female rats in which estradiol was replaced at the time of ovariectomy ('pseudo-intact' rats) or 3 weeks after ovariectomy (long-term ovariectomized, estradiol-treated). While estradiol levels were equivalent in these two groups, the rise in LH after ovariectomy was prevented by the immediate administration in the pseudo-intact rats, while the augmented plasma LH levels present three weeks following ovariectomy were only reduced by 50% as a result of delayed estradiol treatment. The LHRH content of the medial basal hypothalamus (MBH) including the median eminence (ME) was greater in pseudo-intact females than in untreated long-term ovariectomized control females or long-term ovariectomized, estradiol-treated females, both 1 and 14 days after estradiol exposure. Immunocytochemistry revealed fewer LHRH-immunopositive neuronal processes coursing throughout the MBH and terminating in the ME of long-term ovariectomized, estradiol-treated rats compared to those in pseudo-intact rats. However, within individual neurovascular terminals in the ME, image analysis revealed that the area of reaction product was greater in long-term ovariectomized, estradiol-treated animals. Equivalent amounts of LHRH were assayed in the MBH within each group of animals by several LHRH antisera regardless of their different binding requirements (R42, IJ29 and A-R743), suggesting that the predominant moiety present in neuronal terminals is the fully mature decapeptide. In contrast, in the preoptic area-anterior hypothalamus (POA-AH) these antisera assayed amounts of LHRH that varied as a function of binding characteristics, although the quantities did not vary with the estradiol treatment schedule. Immunocytochemical results paralleled these assay data; antisera requiring an interior sequence of amino acids (A-R743 and A-R419) detected approximately 3 times as many immunoreactive perikarya in the POA-AH as did an antiserum requiring the free amidated C terminal (IJ29). The estradiol treatment schedules had no effect on the total number of LHRH-immunopositive neurons detected by each antiserum or the distribution of LHRH-immunopositive neuronal perikarya. These data support the hypothesis that the predominant moieties present in neuronal cell bodies are precursor forms. The fine-structural characteristics of LHRH-immunopositive neuronal cell bodies are consistent with greater secretory and biosynthetic activity in LHRH neurons of long-term ovariectomized, estradiol-treated rats.(ABSTRACT TRUNCATED AT 400 WORDS)

Corticotropin-releasing factor in the adrenal medulla.

Immunoreactive and bioactive corticotropin-releasing factor has been identified in the adrenal gland of dogs, rats and humans. Radioimmunoassay and immunohistochemical experiments have clearly demonstrated that localization of the peptide is confined to the adrenal medulla. CRF-containing cells have a characteristic appearance and are often found in close association with blood vessels. Electron microscopic studies suggest that CRF is secreted at blood vessels within the adrenal medullary vasculature. CRF has also been identified in pheochromocytomas. The amount of the peptide made by such tumors is highly variable as the CRF content of pheochromocytomas may be 20 to 100 times higher or lower than that of normal adrenal tissue. The pathophysiological importance of CRF in pheochromocytomas is unknown. Excessive secretion of the peptide into the peripheral circulation may cause prolonged activation of the pituitary adrenal axis. The peptide may also act within the tumor, although its role remains obscure. Studies on chronically cannulated, awake dogs have shown that CRF is secreted into adrenal venous blood. A gradient exists between adrenal venous and peripheral arterial blood, as CRF is undetectable peripherally under resting conditions. Hemorrhage, a hemodynamic stimulus known to activate a sympathetic adrenal response, increases the CRF secretory rate. The time course of CRF secretion in response to this stimulus parallels that of epinephrine secretion. The physiological significance of adrenal medullary CRF remains to be determined. Although CRF has been shown to affect catecholamine secretion, the peptide appears to be only a weak secretagogue for catecholamines. We suggest that CRF may affect local blood flow within the adrenal medulla and may modify catecholamine secretory rates via this mechanism. The localization of CRF cells in close apposition to blood vessels supports this hypothesis.

Corticotropin-releasing factor in the dog adrenal medulla is secreted in response to hemorrhage.

To characterize the nature of CRF-like immunoreactivity (CRF-LI) in the dog adrenal, adrenal medullary, adrenal cortical, or hypothalamic tissue was extracted and subjected to RIA after partial purification on C-18 cartridges or Sephadex G-50. Using N- and C-terminal-directed antisera against rat/human (r/h) CRF, significant levels of CRF-LI were found in the adrenal medulla and hypothalamus, but not in the adrenal cortex. Immunocytochemical analysis revealed that CRF-immunoreactive cells were located in the adrenal medulla, many of them concentrated in the vicinity of blood vessels and at the border between adrenal medulla and cortex. However, the cortex was devoid of any CRF-positive cells. On reverse phase HPLC, CRF-LI in the adrenal medulla coeluted with synthetic r/hCRF. In a bioassay system, using dispersed rat anterior pituitary cells, purified adrenal CRF caused a dose-dependent increase in ACTH secretion parallel to the r/hCRF standard, indicating that dog adrenal medulla contains authentic r/hCRF. Evidence of CRF-LI secretion from the adrenal was supported by its presence in adrenal venous, but not in peripheral arterial, plasma. Adrenal venous plasma CRF-LI coeluted with r/hCRF on reverse phase HPLC after affinity chromatographic purification. The CRF-LI secretory rate in conscious trained dogs was 68 +/- 19 pg/min (concentration, 27 +/- 5 pg/ml). In response to 20% hemorrhage, the CRF-LI secretion rate rose 3-fold within 15 min and was associated with increased catecholamine secretion. The existence of a biologically active CRF-like substance in the dog adrenal medulla and its secretion in conjunction with catecholamines after a hemorrhage suggest a physiological role for this peptide other than pituitary or central nervous system regulation.

Combined light and electron microscope immunocytochemical localization of scattered peptidergic neurons in the central nervous system.

A pre-embedding immunocytochemical technique is described for combined light and electron microscope study of peptidergic neurons in the central nervous system. The protocol is especially designed to overcome the sampling problems inherent in electron microscope study of structures, such as luteinizing hormone-releasing hormone (LHRH) neurons, that are scattered individually across large brain regions. The fixation methods outlined for several mammalian species include immersion and vascular perfusion with acrolein. Fine-structural preservation and LHRH immunoreactivity obtained with this fixative are compared to results with more conventional fixatives. Vibratome sectioning and a "pretreatment" regime, which prepare the tissues for immunocytochemistry, are described. Immunocytochemical labeling is done with free-floating sections and the peroxidase-antiperoxidase unlabeled antibody enzyme technique. Techniques are also described for the subsequent processing of immunoreacted sections for electron microscopy. These methods ensure that the processed sections are readily scanned by light microscopy, so that regions containing immunoreactive structures can be specifically chosen for electron microscope analysis. Sample electron micrographs are shown that illustrate some fine structural features of LHRH neurons in rats, bats, ferrets, and monkeys, as revealed with the techniques described.

Luteinizing hormone-releasing hormone neurons in human preoptic/hypothalamus: differential intraneuronal localization of immunoreactive forms.

Luteinizing hormone-releasing hormone (LRH) may be synthesized as part of a larger prohormone, as are several other neuropeptides. In this study, we sought not only to define the distribution and morphological characteristics of LRH neurons within the human preoptic area and hypothalamus, but also to identify sites of initial synthesis, posttranslational conversion to the decapeptide, and storage of LRH in these neurons. Immunoreactive molecular forms were differentiated using a series of antisera with distinct specificities in the peroxidase-antiperoxidase technique. These antisera were capable of detecting the fully processed hormone as well as extended decapeptide sequences. Immunopositive LRH neurons were more abundant in the infundibular area of the hypothalamus than in the preoptic area. Numbers of immunopositive perikarya and subcellular distribution of reaction product varied with binding requirements of the antisera. After treatment with an antiserum that requires the fully processed decapeptide for binding, the reaction product was associated almost entirely with granules in perikarya and processes, while very little was associated with either rough endoplasmic reticulum (RER) or Golgi apparatus. In contrast, with an antiserum capable of detecting extended forms of the decapeptide, the RER and Golgi were labeled in addition to granules. From these data, we infer that in humans, mature decapeptide is present in granules within LRH neuronal perikarya and processes. Furthermore, the molecular forms associated with RER and Golgi may be precursors in which the decapeptide sequence is extended.

Seasonal variations in pituitary thyrotropes of the hibernating bat Myotis lucifugus lucifugus: an immunohistochemical study.

Pituitary thyrotropes were identified throughout the year in the hibernating bat Myotis lucifugus lucifugus by means of light microscopic immunohistochemistry. These cells occupied a small proportion of the volume of the pars distalis (mean = 1.36% in males; mean = 1.52% in females) and exhibited a limited distribution pattern that was characteristic of all animals examined. Cells that were immunoreactive with an antiserum directed against the beta subunit of thyroid-stimulating hormone were most numerous in the median rostral and ventral regions; they were scarce or absent in the dorsal portion of the gland and in the extreme lateral wings. No significant seasonal variations were observed in this cell population in females. In males, however, immunoreactive thyrotropes occupied a significantly larger proportion of the pars distalis in June (following arousal from hibernation than at other times of year. No evidence of involution was observed in these anterior pituitary cells in either males or females during hibernation.

Seasonal variations in pituitary LH-gonadotropes of the hibernating bat Myotis lucifugus lucifugus: an immunohistochemical study.

Pituitary gonadotropes were identified throughout the year in the seasonally breeding, hibernating bat Myotis lucifugus lucifugus by means of light microscopic immunohistochemistry. In both male and female bats, these cells were immunoreactive with an antiserum directed to the beta subunit of luteinizing hormone. Some gonadotropes were aggregated near a portion of the infundibular stalk which crosses the anterior lobe, while most were scattered singly in a uniform manner throughout the rest of the pars distalis. This cell population exhibited seasonal variations in both sexes. In males, the proportional volume of the pars distalis occupied by immunoreactive gonadotropes (volume fraction) was significantly reduced in late July, when plasma testosterone levels were approaching their seasonal peak. In females, the volume fraction declined in April, following ovulation, and remained low during pregnancy and lactation. The size and shape of gonadotropes appeared relatively constant throughout the annual reproductive cycle in male bats; the immunoreactive cells were irregular in shape, with cytoplasmic extensions insinuating between and often "cupping" other secretory cell types. In females, the gonadotropes resembled those of males throughout most of the year, except during pregnancy, when these cells became enlarged and ovoid. No evidence of involution was observed in these anterior pituitary cells in either males or females during hibernation.

Luteinizing hormone-releasing hormone (LH-RH) cells and their projections in the forebrain of the bat Myotis lucifugus lucifugus.

Luteinizing hormone-releasing hormone (LH-RH) neurons and their projections were studied by immunocytochemistry in the brains of little brown bats (Myotis lucifugus lucifugus: Chiroptera: Vespertilionidae ) as a first step in the study of relationships between these neurons and the seasonal reproductive events characteristic of this species. The majority of immunoreactive neurons in adult male, adult female, and fetal bats were ovoid bipolar cells with one thin and one thicker process, both of which gave rise to fine varicose fibers. LH-RH-immunoreactive perikarya were concentrated in the region of the arcuate nuclei in all bats examined. Perikarya were also consistently found dispersed in the mammillary region, anterior hypothalamus, preoptic areas, septum, diagonal band of Broca, and olfactory tracts; they were occasionally observed in the dorsal hypothalamus, organum vasculosum of the lamina terminalis (OVLT), habenula, amygdala, and cingulate gyrus. LH-RH-immunoreactive fibers projected heavily to the median eminence, infundibular stalk, and posterior pituitary. In extrahypothalamic areas, these fibers were especially abundant in the stria medullaris/habenula and stria terminalis/amygdala, but also contributed to the diagonal band of Broca and the olfactory tracts. Immunoreactive fibers that may be components of many different pathways clustered in the rostral septum and permeated the medial hypothalamus. LH-RH-containing fibers frequently entered the subfornical organ, but were observed less often in the OVLT and only occasionally in the pineal. The organization of the LH-RH system in the little brown bat resembles that of primates, but differs considerably from that in the rat. Anatomical characteristics of the LH-RH system in bats thus suggest that this animal may be a particularly suitable species for further study of neuroendocrine control of reproductive function as it may relate to primates, including humans.

A quantitative study of pituitary colloid in the bat Myotis lucifugus lucifugus in relation to age, sex, and season.

Extracellular colloid accumulations were examined in pituitary glands of adult and juvenile, male and female, little brown bats, Myotis lucifugus lucifugus (Chiroptera: Vespertilionidae), collected at various times during the annual reproductive cycle. Round or ovoid periodic acid-Schiff-reactive accumulations of colloid were scattered throughout the pars distalis, pars intermedia, and pars tuberalis. These accumulations were surrounded by processes of agranular "follicular" cells. The proportion of the volume of the pars distalis occupied by colloid (volume fraction) exhibited considerable variation among animals, ranging from 0.00 to 3.18% in the total sample of bats. Pituitaries of juvenile males, yearling males, and nonparous females contained significantly less colloid than those of parous females and adult males. The mean volume fraction for each of these groups suggested that colloid content increased progressively from birth through sexual maturity in this animal. In addition, the frequency distribution of colloid content measurements made in parous females and adult males provided indirect evidence that colloid continues to accumulate throughout life. No sexual dimorphism in colloid content was observed before or after sexual maturity, and colloid content did not fluctuate in relation to the annual reproductive cycle of either males or females.