Cytology of vaginal and uterine sarcomas.

OBJECTIVE: To retrospectively review, based on cytologic and histopathologic findings, the diagnoses of 13 patients with uterine sarcoma and 1 with vaginal sarcoma. STUDY DESIGN: There were 8 cases of uterine carcinosarcoma (CS), 2 of leiomyosarcoma, 2 of endometrial stromal sarcoma (ESS), 1 of endocervical stromal sarcoma (ECSS) and 1 of malignant fibrous histiocytoma (MFH) of the vagina. The presence of sarcomatous components was retrospectively investigated by microscopic observation of preoperative specimens from the endocervical canal and endometrial cells. Characteristic features of sarcomatous cells were then investigated by cytodiagnostic micrometry of malignant cells. RESULTS: Of the 14 patients, 1 with low grade ESS and 1 with homologous CS were diagnosed as negative for sarcomatous components. One case of high grade ESS had been overlooked, as were 4 cases of CS. Thus, 7 cases (50%) were diagnosed as positive for sarcomatous cells by preoperative cytologic observation. Based on these findings, 12 of the 14 cases (85.7%) were positive for sarcomatous elements on retrospective reexamination of the specimens. CONCLUSION: Careful attention should be paid to small sarcomatous cells since cases of ESS or ECSS with such cells show morphologic characteristics similar to those of stromatous cells. Furthermore, careful microscopic observation of an entire specimen is required to avoid misdiagnosis as carcinoma since it is easy to overlook sarcomatous elements in smears with carcinosarcoma if there are only a few sarcomatous cells.

Rho-mediated cytoskeletal rearrangement in response to LPA is functionally antagonized by Rac1 and PIP2.

G-protein-coupled receptors signal through Rho to induce actin cytoskeletal rearrangement. We previously demonstrated that thrombin stimulates Rho-dependent process retraction and rounding of 1321N1 astrocytoma cells. Surprisingly, while lysophosphatidic acid (LPA) activated RhoA in 1321N1 cells, it failed to produce cell rounding. Thrombin, unlike LPA, decreased Rac1 activity, and activated (GTPase-deficient) Rac1 inhibited thrombin-stimulated cell rounding, while expression of dominant-negative Rac1 promoted LPA-induced rounding. LPA and thrombin receptors appear to differ in coupling to Gi, as LPA but not thrombin-stimulated 1321N1 cell proliferation was pertussis toxin-sensitive. Blocking Gi with pertussis toxin enabled LPA to induce cell rounding and to decrease activated Rac1. These data support the hypothesis that Rac1 and Gi activation antagonize cell rounding. Thrombin and LPA receptors also differentially activated Gq pathways as thrombin but not LPA increased InsP3 formation and reduced phosphatidylinositol 4,5-bisphosphate (PIP2) levels. Microinjection of the plekstrin homology domain of phospholipase C (PLC)delta1, which binds PIP2, enabled LPA to elicit cell rounding, consistent with a requirement for PIP2 reduction. We suggest that Rho-mediated cytoskeletal responses are enhanced by concomitant reductions in cellular levels of PIP2 and Rac1 activation and thus effected only by G-protein-coupled receptors with appropriate subsets of G protein activation.

Modulation of aqueous humor outflow by ionic mechanisms involved in trabecular meshwork cell volume regulation.

PURPOSE: Trabecular meshwork (TM) cell shape, volume, contractility and their interactions with extracellular matrix determine outflow facility. Because cell volume seems essential to TM function, this study was conducted to investigate further the ionic channels and receptors involved in regulatory volume decrease and their roles in modulating outflow facility. METHODS: Primary cultures of bovine TM cells were used. K(+) and Cl(-) currents were studied with whole-cell patch clamping. Swelling was induced by hypotonic shock. [Ca(2+)](i) was measured in TM cells loaded with fura-2. Bovine anterior segments were perfused at constant pressure to measure outflow facility. RESULTS: Hypotonic media activated both the high-conductance Ca(2+)-activated K(+) channel (BK(Ca)) and swelling-activated Cl(-) channel (Cl(swell)) currents and induced release of adenosine 5'-triphosphate (ATP) from TM cells. ATP activated P2Y(2) receptors with the following profile: ATP = uridine 5'-triphosphate (UTP) > adenosine 5'-O-(3-thiotriphosphate) (ATP-gamma S) > adenosine 5'-diphosphate (ADP) = uridine 5'-diphosphate (UDP), and increased BK(Ca) current. Hypotonic medium initially decreased outflow facility in perfused anterior segments, which recovered with time to baseline levels. Addition of tamoxifen or iberiotoxin (Cl(swell) and BK(Ca) blockers, respectively) lengthened the recovery phase, which implies that these channels participate in cell volume regulation. In contrast, an activator of BK(Ca)s (NS1619) produced the opposite effect. CONCLUSIONS: Cell swelling activates a regulatory volume decrease mechanism that implies activation of K(+) and Cl(-) currents and participation of P2Y(2) receptors. Because previous studies have shown that intracellular volume of TM cells is an important determinant of outflow facility, it seems feasible that cell volume regulation would be part of the homeostatic mechanisms of the TM, to regulate the outflow pathway.

Long-term denervation in humans causes degeneration of both contractile and excitation-contraction coupling apparatus, which is reversible by functional electrical stimulation (FES): a role for myofiber regeneration?

Over the last 30 years there has been considerable interest in the use of functional electrical stimulation (FES) to restore movement to the limbs of paralyzed patients. Spinal cord injury causes a rapid loss in both muscle mass and contractile force. The atrophy is especially severe when the injury involves lower motoneurons because many months after spinal cord injury, atrophy is complicated by fibrosis and fat substitution. In this study we describe the effects of long-term lower motoneuron denervation of human muscle and present the structural results of muscle trained using FES. By means of an antibody for embryonic myosin, we demonstrate that many regenerative events continue to spontaneously occur in human long-term denervated and degenerated muscle (DDM). In addition, using electron microscopy, we describe i) the overall structure of fibers and myofibrils in long-term denervated and degenerated muscle, including the effects of FES, and ii) the structure and localization of calcium release units, or triads; the structures reputed to activate muscle contraction during excitation-contraction coupling (ECC). Both apparatus undergo disarrangement and re-organization following long-term denervation and FES, respectively. The poor excitability of human long-term DDM fibers, which extends to the first periods of FES training, may be explained in terms of the spatial disorder of the ECC apparatus. Its disorganization and re-organization following long-term denervation and FES, respectively, may play a key role in the parallel disarrangement and re-organization of the myofibrils that characterize denervation and FES training. The present structural studies demonstrate that the protocol used during FES training is effective in reverting long-term denervation atrophy and dystrophy. The mean fiber diameter in FES biopsies is 42.2 +/- 14.8 SD (p < 0.0001 vs DDM 14.9 +/- 6.0 SD); the mean percentile of myofiber area of the biopsy is 94.3 +/- 5.7 SD (p < 0.0001 vs DDM 25.7 +/- 23.7 SD); the mean percentile fat area is 2.1 +/- 2.4 SD (p < 0.001 vs DDM 12.8 +/- 12.1 SD); and the mean percentile connective tissue area is 3.6 +/- 4.6 SD (p < 0.001 vs DDM 61.6 +/- 20.1 SD). In DDM biopsies more than 50% of myofibers have diameter smaller than 10 microm, while the FES-trained subjects have more that 50% of myofibers larger than 30 microm. The recovery of muscle mass seems to be the result of both a size increase of the surviving fibers and the regeneration of new myofibers.

Flow-induced endothelial surface reorganization and minimization of entropy generation rate.

Effects of hydrodynamic shear on the shape of the endothelial surface are examined based on evaluations of the rate of entropy generation at the cell surface. A linear solution of the flow over a sinusoidally varying endothelial surface is used to evaluate the entropy generation rate on the cell surface for which measured cell dimensions are available. Both the local rate of entropy generation (equivalent to the rate of energy dissipation by viscous shear) at the peak of a cell and the total entropy generation rate over the cell surface are minimized under conditions of a constant cell surface area and a constant cell peak height; which yields horizontal cell dimensions that are close to those obtained experimentally.

GDF-3 is an adipogenic cytokine under high fat dietary condition.

Growth differentiation factor 3 (GDF-3) is structurally a bone morphogenetic protein/growth differentiation factor subfamily member of the TGF-beta superfamily. GDF-3 exhibits highest level of expression in white fat tissue in mice and is greatly induced by high fat diet if fat metabolic pathway is blocked. To identify its biological function, GDF-3 was overexpressed in mice by adenovirus mediated gene transfer. Mice transduced with GDF-3 displayed profound weight gain when fed with high fat diet. The phenotypes included greatly expanded adipose tissue mass, increased body adiposity, highly hypertrophic adipocytes, hepatic steatosis, and elevated plasma leptin. GDF-3 stimulated peroxisome proliferator activated receptor expression in adipocytes, a master nuclear receptor that controls adipogenesis. However, GDF-3 was not involved in blood glucose homeostasis or insulin resistance, a condition associated with obesity. In contrast, similar phenotypes were not observed in GDF-3 mice fed with normal chow, indicating that GDF-3 is only active under high lipid load. Thus, GDF-3 is a new non-diabetic adipogenic factor tightly coupled with fat metabolism.

Role of ammonia in reversal of glutamate-mediated Müller cell swelling in the rat retina.

Glutamate is thought to participate in a variety of retinal degenerative disorders. However, when exposed to glutamate at concentrations up to 1 mM, ex vivo rat retinas typically exhibit Müller cell swelling, but not excitotoxic neuronal damage. This Müller cell swelling is reversible following glutamate washout, indicating that the glial edema is not required for glutamate-induced neuronal injury. It is unclear whether glutamate directly induces the Müller cell swelling or whether a metabolite of glutamate such as glutamine acts as an osmolyte to generate the cellular edema. To examine this issue, ex vivo rat retinas were exposed to 1 mM glutamate or 1 mM glutamine and were evaluated histologically. Glutamate was also combined with 1 mM ammonia or with methionine sulfoximine (MSO), an inhibitor of glutamine synthetase, the enzyme that catalyzes the synthesis of glutamine from glutamate and ammonia. Glutamate-mediated Müller cell swelling was blocked by co-administration of ammonia and the reversibility of Müller cell swelling was inhibited by MSO administered following glutamate exposure. Glutamine alone failed to induce Müller cell swelling. These results indicate that glutamate-mediated Müller cell swelling is unlikely to result from glutamine accumulation. Rather, conversion of glutamate to glutamine in a reaction involving ammonia helps reverse Müller cell swelling following exposure to exogenous glutamate.

Cytoskeletal organization of limulus amebocytes pre- and post-activation: comparative aspects.

One of the major functions of circulating Limulus amebocytes is to effect blood coagulation upon receipt of appropriate signals. However, the hypothesis that Limulus amebocytes are fundamentally similar to vertebrate thrombocytes and platelets has not been tested sufficiently in previous studies of their cytoskeletal organization. Whereas the earlier data were derived from transmission electron microscopy (TEM) of thin sections of a limited number of cells, improved fluorescence labeling methods that retain cell morphology have now enabled us to survey F-actin and microtubule organization in intact individual amebocytes and in large amebocyte populations pre- and post-activation. Anti-tubulin immunofluorescence showed the marginal band (MB) of microtubules to be ellipsoidal in most unactivated cells, with essentially no other microtubules present. However, minor subpopulations of cells with discoidal or pointed shape, containing corresponding arrangements of microtubules suggestive of morphogenetic intermediates, were also observed. Texas-red phalloidin labeled an F-actin-rich cortex in unactivated amebocytes, accounting for MB and granule separation from the plasma membrane as visualized in TEM thin sections, and supporting earlier models for MB maintenance of flattened amebocyte morphology by pressure against a cortical layer. Shape transformation after activation by bacterial lipopolysaccharide was attributable principally to spiky and spreading F-actin in outer cell regions, with the MB changing to twisted, nuclei-associated forms and eventually becoming unrecognizable. These major pre- and post-activation cytoskeletal features resemble those of platelets and non-mammalian vertebrate thrombocytes, supporting recognition of the Limulus amebocyte as a representative evolutionary precursor of more specialized clotting cell types.

Unbiased estimates of number and size of rat dorsal root ganglion cells in studies of structure and cell survival.

For quantitative studies of rat dorsal root ganglion (DRG) in experimental models stereological principles offer a number of different techniques. The application, however, requires knowledge of the anatomy and cytology of the ganglion, considerations of sampling and choosing between the many estimators available. For number and volume estimates in thick glycolmethacrylate sections the optical fractionator and the vertical planar rotator technique in most cases provide sufficient efficiency and are simple to use. Classification of the neurons in the DRG into A- and B-cells is of value in experimental conditions where the two cell types can react differently. Studies on development and subclassification of neuronal DRG cells will gain from application of stereological methods, also. Until now the methods have mainly been applied in studies of axotomy and in a few intoxication models where the time course of cell loss and changes in perikarya volume are important parameters. Further quantitative studies providing better understanding of distribution and expression of neuropeptides, cytokines, apoptotic molecules etc. will provide insight for future therapeutic approaches in neurodegenerative disorders. The more demanding staining techniques require less restrictive embedding media, but unbiased principles are available for almost all the stereological techniques applied to tissue only deformed after sectioning.

Three-dimensional imaging of living and dying neurons with atomic force microscopy.

Atomic Force Microscopy (AFM) has been used to image the morphology of developing neurons and their processes. Additionally, AFM can physically interact with the cell under investigation in numerous ways. Here we use the AFM to both three-dimensionally image the neuron and to inflict a nano/micro-puncture to its membrane. Thus, the same instrument used as a tool to precisely penetrate/cut the membrane at the nanoscale level is employed to image the morphological responses to damage. These first high resolution AFM images of living chick dorsal root ganglion cells and cells of sympathetic ganglion and their growing processes provide confirmation of familiar morphologies. The increased resolution of the AFM revealed these structures to be significantly more complex and variable than anticipated. Moreover we describe novel, dynamic, and unreported architectures, particularly large dorsally projecting ridges, spines, and ribbons of cytoplasm that appear and disappear on the order of minutes. In addition, minute (ca. 100 nm) hair-like extensions of membrane along the walls of nerve processes that also shift in shape and density, appearing and disappearing over periods of minutes were seen. We also provide "real time" images of the death of the neuron cell body after nano/micro scale damage to its membrane. These somas excreted their degraded cytoplasm, revealed as an enlarging pool beneath and around the cell. Conversely, identical injury, even repeated perforations and nanoslices, to the neurite's membrane do not lead to demise of the process. This experimental study not only provides unreported neurobiology and neurotrauma, but also emphasizes the unique versatility of AFM as an instrument that can (1) physically manipulate cells, (2) provide precise quantitative measurements of distance, surface area and volume at the nanoscale if required, (3) derive physiologically significant data such as membrane pressure and compliance, and (4) during the same period of study--provide unexcelled imaging of living samples.

Retinal ganglion cell type, size, and spacing can be specified independent of homotypic dendritic contacts.

In Brn3b(-/-) mice, where 80% of retinal ganglion cells degenerate early in development, the remaining 20% include most or all ganglion cell types. Cells of the same type cover the retinal surface evenly but tile it incompletely, indicating that a regular mosaic and normal dendritic field size can be maintained in the absence of contact among homotypic cells. In Math5(-/-) mice, where only approximately 5% of ganglion cells are formed, the dendritic arbors of at least two types among the residual ganglion cells are indistinguishable from normal in shape and size, even though throughout development they are separated by millimeters from the nearest neighboring ganglion cell of the same type. It appears that the primary phenotype of retinal ganglion cells can develop without homotypic contact; dendritic repulsion may be an end-stage mechanism that fine-tunes the dendritic arbors for more efficient coverage of the retinal surface.

Neuronal morphological change of size-sieved stem cells induced by neurotrophic stimuli.

Size-sieved stem cells (SSCs) derived from human bone marrow have the ability to differentiate into bone, fat and cartilage. SSCs can differentiate into active neural cells after exposure to antioxidant agents. The aim of the present study is to understand if SSCs can be stimulated to differentiate into neurons in response to neurotrophic factors, such as glial cell line-derived neurotrophic factor (GDNF), pituitary adenylate cyclase-activating polypeptide (PACAP) and dibutyryl cAMP (dbcAMP). SSCs in a serum-free medium transform from a fibroblastic-like form to a multipolar morphology. Treatment of SSCs with GDNF, PACAP, and dbcAMP increased the production of neurofilament light protein (NF-L) and a cytoskeleton protein-alpha-tubulin. Examination of a vesicle protein-synapsin-1 or a neuronal progenitor marker-internexin in SSCs indicated that treatment with GDNF, PACAP, and dbcAMP further elongated cell processes and increased process branching. The findings indicate that neurotrophic signaling and cAMP-dependent signaling might promote the neuronal differentiation of SSCs.

A morphometric study of the progressive changes on NADPH diaphorase activity in the developing rat's barrel field.

The distribution of NADPH diaphorase (NADPH-d)/nitric oxide synthase (NOS) neurons was evaluated during the postnatal development of the primary somatosensory cortex (SI) of the rat. Both cell counts and area measurements of barrel fields were carried out throughout cortical maturation. In addition, NADPH-d and cytochrome oxidase (CO) activities were also compared in both coronal and tangential sections of rat SI between postnatal days (P) 10 and 90. Throughout this period, the neuropil distributions of both enzymes presented a remarkable similarity and have not changed noticeably. Their distribution pattern show the PMBSF as a two-compartmented structure, displaying a highly reactive region (barrel hollows) flanked by less reactive regions (barrel septa). The number of NADPH-d neurons increased significantly in the barrel fields between P10 and P23, with peak at P23. The dendritic arborization of NADPH-d neurons became more elaborated during barrel development. In all ages evaluated, the number of NADPH-d cells was always higher in septa than in the barrel hollows. Both high neuropil reactivity and differential distribution of NADPH-d neurons during SI development suggest a role for nitric oxide throughout barrel field maturation.

Mechanical strain delivers anti-apoptotic and proliferative signals to gingival fibroblasts.

Physical forces play a critical role in the survival and proliferation of many cell types, including fibroblasts. Gingival fibroblasts are exposed to mechanical stress during mastication, orthodontic tooth movement, and wound healing following periodontal surgery. The aim of this study was to examine the effect of mechanical strain on human gingival fibroblasts (hGF). Cells were subjected to short-term (up to 60 min) and long-term (up to 48 hrs) 20% average elongation at 0.1 Hz. We monitored survival signaling by evaluating the phosphorylation status and localization of Forkhead box (FoxO) family members, which are mediators of apoptosis. We also examined strain-induced proliferation by measuring the level of proliferating cell nuclear antigen (PCNA). We observed that cyclic strain caused the phosphorylation and retention in the cytoplasm of FoxO family members. Moreover, mechanical strain resulted in increased ERK kinase phosphorylation and PCNA expression. In conclusion, cyclic strain delivers anti-apoptotic and proliferative stimuli to hGF.

A potassium channel-linked mechanism of glial cell swelling in the postischemic retina.

The cellular mechanisms underlying glial cell swelling, a central cause of edema formation in the brain and retina, are not yet known. Here, we show that glial cells in the postischemic rat retina, but not in control retina, swell upon hypotonic stress. Swelling of control cells could be evoked when their K(+) channels were blocked. After transient ischemia, glial cells strongly downregulated their K(+) conductance and their prominent Kir4.1 protein expression at blood vessels and the vitreous body. In contrast, the expression of the aquaporin-4 (AQP4) (water channel) protein was only slightly altered after ischemia. Activation of D(2) dopaminergic receptors prevents the hypotonic glial cell swelling. The present results elucidate the coupling of transmembraneous water fluxes to K(+) currents in glial cells and reveal the role of altered K(+) channel expression in the development of cytotoxic edema. We propose a mechanism of postischemic glial cell swelling where a downregulation of their K(+) conductance prevents the emission of intracellularly accumulated K(+) ions, resulting in osmotically driven water fluxes from the blood into the glial cells via aquaporins. Inhibition of these water fluxes may be beneficial to prevent ischemia-evoked glial cell swelling.

The effects of axotomy on neurons and satellite glial cells in mouse trigeminal ganglion.

Damage to peripheral nerves induces ectopic firing in sensory neurons, which can contribute to neuropathic pain. As most of the information on this topic is on dorsal root ganglia we decided to examine the influence of infra-orbital nerve section on cells of murine trigeminal ganglia. We characterized the electrophysiological properties of neurons with intracellular electrodes. Changes in the coupling of satellite glial cells (SGCs) were monitored by intracelluar injection of the fluorescent dye Lucifer yellow. Electrophysiology of SGCs was studied with the patch-clamp technique. Six to eight days after axotomy, the percentage of neurons that fire spontaneously increased from 1.6 to 12.8%, the membrane depolarized from -51.1 to -45.5 mV, the percentage of cells with spontaneous potential oscillations increased from 19 to 37%, the membrane input resistance decreased from 44.4 to 39.5 MOmega, and the threshold for firing an action potential decreased from 0.61 to 0.42 nA. These changes are consistent with increased neuronal excitability. SGCs were mutually coupled around a given neuron in 21% of the cases, and to SGCs around neighboring neurons in only 4.8% of the cases. After axotomy these values increased to 37.1 and 25.8%, respectively. After axotomy the membrane resistance of SGCs decreased from 101 MOmega in controls to 40 MOmega, possibly due to increased coupling among these cells. We conclude that axotomy affects both neurons and SGCs in the trigeminal ganglion. The increased neuronal excitability and ectopic firing may play a major role in neuropathic pain.

Characterization of gabaergic neurons within the human medial mamillary nucleus.

The morphology, distribution and relative frequency of GABAergic neurons in the medial mamillary nucleus (MMN) of normal human individuals was studied using a glutamic acid decarboxylase (GAD) antiserum. GAD-immunoreactive (GAD-IR) neurons were found sparsely distributed throughout the MMN and most displayed a simple bipolar morphology. A small population of large diameter GAD-IR neurons was found in the white matter capsule adjacent to the ventral border of the MMN. Results of double-labeling experiments revealed no evidence of calretinin, parvalbumin or calbindin immunoreactivities co-localizing with GAD-IR neurons. GAD-IR neurons of the MMN had an average somal area of 138+/-41 microm2, compared with the average somal area of 384+/-137 microm2 for the population of MMN neurons as a whole. GAD-IR neurons had a tendency to cluster in groups of two (and occasionally three) and showed a distribution gradient across the MMN with higher densities being found near the insertion of the fornix, the origin of the mamillo-thalamic tract and toward the medial MMN border. Quantitative estimates of GAD-IR neuron frequency revealed the GAD-IR phenotype to constitute an average of 1.7% percent of the total neuron population within the human MMN. These findings suggest that inhibitory activity within the human MMN is regulated in part by a small population of intrinsic GABAergic interneurons.

A combined dielectrophoresis, traveling wave dielectrophoresis and electrorotation microchip for the manipulation and characterization of human malignant cells.

The study of the dielectric properties of micrometer- or nanometer-scale particles is of particular interest in present-day applications of biomedical engineering. Electrokinetics utilises electrically energised microelectrode structures within microfluidic chambers to noninvasively probe the physiological structure of live cancer cells. A system is described that combines the three complementary techniques of dielectrophoresis (DEP), travelling wave dielectrophoresis (TWD) and electrorotation (ROT) for the first time on a single, integrated chip (3 x 6 mm). The chip employs planar microelectrode arrays fabricated on a silicon substrate to facilitate the synthesis of the various nonuniform electric fields required for the controlled manipulation, measurement and characterization of mammalian cells. A study of the dielectric properties of human malignant cells (Daudi and NCI-H929) was performed to demonstrate the potential and the versatility of the system in providing a fully programmable microsystem.

Functional restoration of acoustic units and adult-generated neurons after hypothalamic lesion.

The hypothalamus of the adult ring dove contains acoustic units that respond to species-specific coo vocalization. Loss of nest coo leads to unsuccessful breeding. However, the recovery of nest coo in some doves suggests that these units are capable of self-renewal. We have previously shown that lesioning the hypothalamus generates the addition of new neurons at the lesioned area. In this study, we sought to determine whether lesion-induced new neurons are involved in the recovery of coo-responsive units. We systematically recorded electrical activity in the ventromedial nucleus (VMN) of the hypothalamus, before and after lesion, for varying periods up to 3 months. Recordings were made when the birds were at rest (spontaneous discharge) and when the birds were exposed to acoustic stimulations (evoked discharge). Concurrently, the lesioned area was monitored for changes in cell types by using bromodeoxyuridine (BrdU) to label newly divided cells and NeuN to identify mature neurons. For 1 month after lesion, there was no sign of electrical activity, and only BrdU-labeled cells were present. When the first electrical activity occurred, it displayed abnormal spontaneous bursting patterns. The mature discharge patterns (both spontaneous and evoked) occurred after detection of BrdU+/NeuN+ double-labeled cells 2-3 months postlesion and were similar to those found in intact and sham-lesioned birds. Double-labeled cells bore morphologic characteristics of a neuron and were confirmed with z-stack analysis using confocal laser scanning microscopy. Moreover, double-labeled cells were not stained for glial fibrillary acidic protein (GFAP), suggesting that they were neurons. The number of coo-responsive units was significantly correlated with that of BrdU+/NeuN+ cells. Furthermore, the marker for recording sites revealed that coo-responsive units were colocalized with BrdU+/NeuN+ cells. Taken together, the evidence strongly suggests that lesion-induced addition of new neurons promotes the functional recovery of the adult hypothalamus.

Compression of a capsule: mechanical laws of membranes with negligible bending stiffness.

The compression of a capsule between two plates is considered. The problem is solved numerically for a capsule made of an incompressible liquid drop surrounded by a thin elastic membrane which has a negligible bending stiffness. Numerical results are provided for three different mechanical laws of the membrane. By considering elastic moduli independent of the deformation, we show that the isotropic dilation plays the major role. In particular, an asymptotic behavior independent of the shear modulus is found for large deformations. For more complex models, the deformation limits beyond which the variation of elastic moduli starts to play a role are examined. The results indicate that the distinction between the different models requires a careful inspection of both small and large deformations. The theoretical predictions are compared with experimental results. For millimetric capsules with membranes made of covalently linked human serum albumin and alginate, the best agreement is obtained by considering that the elastic moduli are independent of the deformation and range from 0.1 to 4 N/m.