X-Ray Absorption Spectrum of the N_{2}

The x-ray absorption spectrum of N_{2}^{+} in the K-edge region has been measured by irradiation of ions stored in a cryogenic radio frequency ion trap with synchrotron radiation. We interpret the experimental results with the help of restricted active space multiconfiguration theory. Spectroscopic constants of the 1σ_{u}^{-1} ^{2}Σ_{u}^{+} state, and the two 1σ_{u}^{-1}3σ_{g}^{-1}1π_{g} ^{2}Π_{u} states are determined from the measurements. The charge of the ground state together with spin coupling involving several open shells give rise to double excitations and configuration mixing, and a complete breakdown of the orbital picture for higher lying core-excited states.

Large orbital magnetic moments of small, free cobalt cluster ions Co[Formula: see text] with n [Formula: see text].

The size dependent electronic structure and separate spin and orbital magnetic moments of free Co[Formula: see text] ([Formula: see text]) cluster ions have been investigated by x-ray absorption and x-ray magnetic circular dichroism spectroscopy in a cryogenic ion trap. A very large orbital magnetic moment of [Formula: see text] per atom was determined for Co[Formula: see text], which is one order of magnitude larger than in the bulk metal. Large orbital magnetic moments per atom of ≈1 [Formula: see text] were also found for Co[Formula: see text], Co[Formula: see text], and Co[Formula: see text]. The orbital contribution to the total magnetic moment shows a non-monotonic cluster size dependence: The orbital contribution increases from a local minimum at n = 2 to a local maximum at n = 5 and then decreases with increasing cluster size. The 3d spin magnetic moment per atom is nearly constant and is solely defined by the number of 3d holes which shows that the 3d majority spin states are fully occupied, that is, 3d hole spin polarization is 100%.

Electronic ground state of Ni2.

The Φ9/24 ground state of the Ni2+ diatomic molecular cation is determined experimentally from temperature and magnetic-field-dependent x-ray magnetic circular dichroism spectroscopy in a cryogenic ion trap, where an electronic and rotational temperature of 7.4±0.2 K was reached by buffer gas cooling of the molecular ion. The contribution of the spin dipole operator to the x-ray magnetic circular dichroism spin sum rule amounts to 7Tz=0.17±0.06µB per atom, approximately 11% of the spin magnetic moment. We find that, in general, homonuclear diatomic molecular cations of 3d transition metals seem to adopt maximum spin magnetic moments in their electronic ground states.

Direct observation of high-spin states in manganese dimer and trimer cations by x-ray magnetic circular dichroism spectroscopy in an ion trap.

The electronic structure and magnetic moments of free Mn2 (+) and Mn3 (+) are characterized by 2p x-ray absorption and x-ray magnetic circular dichroism spectroscopy in a cryogenic ion trap that is coupled to a synchrotron radiation beamline. Our results directly show that localized magnetic moments of 5 µB are created by 3d(5)((6)S) states at each ionic core, which are coupled ferromagnetically to form molecular high-spin states via indirect exchange that is mediated in both cases by a delocalized valence electron in a singly occupied 4s derived antibonding molecular orbital with an unpaired spin. This leads to total magnetic moments of 11 µB for Mn2 (+) and 16 µB for Mn3 (+), with no contribution of orbital angular momentum.

Magnetic moments of chromium-doped gold clusters: the Anderson impurity model in finite systems.

The magnetic moment of a single impurity atom in a finite free electron gas is studied in a combined x-ray magnetic circular dichroism spectroscopy, charge transfer multiplet calculation, and density functional theory study of size-selected free chromium-doped gold clusters. The observed size dependence of the local magnetic moment can be understood as a transition from a local moment to a mixed valence regime. This shows that the Anderson impurity model essentially describes finite systems even though the discrete density of states introduces a significant deviation from a bulk metal, and the free electron gas is only formed by less than 10 electrons. Electronic shell closure in the gold host minimizes the interaction of localized impurity states with the confined free electron gas and preserves the magnetic moment of 5 µ_{B} fully in CrAu_{2}^{+} and almost fully in CrAu_{6}^{+}. Even for open-shell species, large local moments are observed that scale with the energy gap of the gold cluster. This indicates that an energy gap in the free electron gas stabilizes the local magnetic moment of the impurity atom.

Electronic ground states of Fe2(+) and Co2(+) as determined by x-ray absorption and x-ray magnetic circular dichroism spectroscopy.

The (6)Π electronic ground state of the Co2 (+) diatomic molecular cation has been assigned experimentally by x-ray absorption and x-ray magnetic circular dichroism spectroscopy in a cryogenic ion trap. Three candidates, (6)Φ, (8)Φ, and (8)Γ, for the electronic ground state of Fe2 (+) have been identified. These states carry sizable orbital angular momenta that disagree with theoretical predictions from multireference configuration interaction and density functional theory. Our results show that the ground states of neutral and cationic diatomic molecules of 3d transition elements cannot generally be assumed to be connected by a one-electron process.

Rectification properties of conically shaped nanopores: consequences of miniaturization.

Nanopores attracted a great deal of scientific interest as templates for biological sensors as well as model systems to understand transport phenomena at the nanoscale. The experimental and theoretical analysis of nanopores has been so far focused on understanding the effect of the pore opening diameter on ionic transport. In this article we present systematic studies on the dependence of ion transport properties on the pore length. Particular attention was given to the effect of ion current rectification exhibited in conically shaped nanopores with homogeneous surface charges. We found that reducing the length of conically shaped nanopores significantly lowered their ability to rectify ion current. However, rectification properties of short pores can be enhanced by tailoring the surface charge and the shape of the narrow opening. Furthermore we analyzed the relationship of the rectification behavior and ion selectivity for different pore lengths. All simulations were performed using MsSimPore, a software package for solving the Poisson-Nernst-Planck (PNP) equations. It is based on a novel finite element solver and allows for simulations up to surface charge densities of -2 e per nm(2). MsSimPore is based on 1D reduction of the PNP model, but allows for a direct treatment of the pore with bulk electrolyte reservoirs, a feature which was previously used in higher dimensional models only. MsSimPore includes these reservoirs in the calculations, a property especially important for short pores, where the ionic concentrations and the electric potential vary strongly inside the pore as well as in the regions next to the pore entrance.

Spin coupling and orbital angular momentum quenching in free iron clusters.

Magnetic spin and orbital moments of size-selected free iron cluster ions Fe{n}{+} (n=3-20) have been determined via x-ray magnetic circular dichroism spectroscopy. Iron atoms within the clusters exhibit ferromagnetic coupling except for Fe{13}{+}, where the central atom is coupled antiferromagnetically to the atoms in the surrounding shell. Even in very small clusters, the orbital magnetic moment is strongly quenched and reduced to 5%-25% of its atomic value while the spin magnetic moment remains at 60%-90%. This demonstrates that the formation of bonds quenches orbital angular momenta in homonuclear iron clusters already for coordination numbers much smaller than those of the bulk.

Communication: Highest occupied molecular orbital-lowest unoccupied molecular orbital gaps of doped silicon clusters from core level spectroscopy.

A method to determine band gaps of size-selected and isolated nanoparticles by combination of valence band and core-level photoionization spectroscopy is presented. This approach is widely applicable and provides a convenient alternative to current standard techniques for the determination of band gaps by optical or photoelectron spectroscopy. A first application to vanadium doped silicon clusters confirms a striking size-dependence of their highest occupied-lowest unoccupied molecular orbital gaps.

Size dependence of L2,3 branching ratio and 2p core-hole screening in x-ray absorption of metal clusters.

Resonant 2p x-ray absorption spectra of size-selected transition metal ions and clusters consisting of 1

Metabolic and hemodynamic effects of CO2 pneumoperitoneum in a controlled hemorrhage model.

BACKGROUND: Intracavity infusion of fibrin sealant-based agents, as a novel modality to control internal bleeding, is associated with an increase of pneumoperitoneum (PP) pressure. The safe limit of such increase has not been well defined in hypovolemic subjects. The purpose of this study was to evaluate the hemodynamic and metabolic effects of increasing PP pressure and to define the limits of carbon dioxide (CO2) insufflation in a controlled hemorrhage rat model. METHODS: Ninety male rats (474 +/- 6 g, 37 degrees +/- 1 degrees C) were anesthetized, and mechanically ventilated. Animals were randomly distributed among 14 groups (n = 6-8) with an increasing amount of blood loss (0, 10, 15, and 17.5 mL/kg) and 15 minutes of CO2 insufflation at 0, 5, 10, and 15 mm Hg starting 15 minutes after hemorrhage, followed by desufflation. Mean arterial pressure (MAP), heart rate, and survival were recorded and arterial and venous blood samples were collected at baseline, at 15 minutes after hemorrhage, after insufflation, and after desufflation procedures to determine arterial blood gases and lactic acid levels. RESULTS: In nonhemorrhaged animals, increasing PP pressure up to 15 mm Hg produced only transient changes in MAP and no increase in lactate level. A moderate hemorrhage (10 mL/kg) limited the safe abdominal pressure to 10 mm Hg with metabolic changes that were restored 15 minutes after desufflation. Higher PP pressure (15 mm Hg) at this hemorrhage level produced a significant decline in MAP (42%, p < 0.001) and progressive metabolic acidosis with a 2.1-fold increase (p < 0.01) in lactate level. The more severe hemorrhage (15 mL/kg) further reduced the limits of PP pressure such that 10 and 15 mm Hg resulted in a progressive decline of blood pressures (52% and 54%, respectively; p < 0.001) and severe metabolic acidosis as manifested by 3.3- and 3.1-fold rises in lactate levels, respectively. In the most severe hemorrhaged animals (17.5 mL/kg), the 50% mortality was primarily determined by the severity of the blood loss and the additional PP at 5 mm Hg had no significant impact. CONCLUSION: The safe limit of PP pressurization with CO2 is dependent on the amount of blood loss. In this mechanically ventilated rat model, increasing the amount of blood loss from 0 to 15 mL/kg reduces the tolerable level of abdominal insufflation pressure from 15 mm Hg to 5 mm Hg. A 5-mm Hg PP pressure appears safe even in the most severely hemorrhaged animals.

Assessment of topical hemostats in a renal hemorrhage model in heparinized rats.

Various topical hemostatic agents or devices have been employed to address the challenges associated with hemorrhage from parenchymal organs during surgery or trauma. Their relative efficacy, however, has not been assessed in a single animal model. The objective of this study was to develop a small animal renal hemorrhage model for comparing hemostatic efficacy of various topical agents, and then to compare fibrin sealant (FS) to an existing standard of care for topical hemostasis. A left heminephrectomy was performed in anesthetized adult male Sprague-Dawley rats. Animals were anticoagulated with 2000 IU/kg heparin IV and various topical hemostatic agents were applied to the injury. Treatment groups included FS applied as a spray; FS applied through a cannula; gelatin sponge (GS) soaked in 1000 IU/mL thrombin solution; GS soaked in 300 IU/mL thrombin; dry GS; and fibrinogen without thrombin applied as a spray. The main endpoints of the study were incidence of hemostasis, blood loss, acute survival trends, and maintenance of mean arterial pressure (MAP). Three treatment groups, the two FS groups and the GS soaked in 1000 IU/mL thrombin, afforded significant hemostasis compared to the controls (P < 0.01). Both FS groups had significantly less blood loss, longer survival times, and maintained higher MAPs than the GS-treated groups. Quantitative dose effects and functional deficiencies in topical hemostatic products could be assessed using this animal model. The study demonstrated that liquid FS was significantly more efficacious than a GS soaked in thrombin for abating hemorrhage from a renal excision in a heparinized rat.

Effect of dry fibrin sealant dressings versus gauze packing on blood loss in grade V liver injuries in resuscitated swine.

BACKGROUND: We conducted this study to determine whether the dry fibrin sealant dressing (DFSD) would stop bleeding from a grade V liver injury and to evaluate the effects of leaving the absorbable DFSD in survival animals. METHODS: Twenty-four swine (40+/-3.0 kg) received a uniform grade V liver injury and were randomized to one of four 1-hour treatment groups: (1) gauze packing, (2) DFSD, (3) immunoglobulin G placebo dressing, and (4) no treatment. All animals were resuscitated with lactated Ringer's solution. Total blood loss (TBL), mean arterial pressure, resuscitation volume, and laboratory data were monitored for 1 hour after injury. Four swine were treated with the DFSD after grade V injury and allowed to survive for 7 or 14 days. RESULTS: The TBL was 1,104+/-264 mL (mean +/- SEM), 544+/-104 mL, 4,223+/-1,555 mL, and 6,026+/-1,020 mL for groups 1, 2, 3, and 4 respectively. TBL in DFSD animals was less than that in animals treated with gauze packing (p = 0.06). Grade V injuries were uniform among the 1-hour groups, and no evidence of intrahepatic abscess, unusual adhesions, or hepatic vein, vena caval, or pulmonary thromboses were noted in the long-term survival animals. CONCLUSION: In this model of grade V liver injury, blood loss with the DFSD was 51% of that observed with standard gauze packing (not statistically different). Initial survival data revealed no complications attributable to the fibrin dressing. DFSD may provide simple, rapid, and definitive hemorrhage control in life-threatening liver injuries without the need for reoperation.

Hemostatic efficacy of a fibrin sealant-based topical agent in a femoral artery injury model: a randomized, blinded, placebo-controlled study.

PURPOSE: The efficacy of currently available topical hemostatic agents requires the formation of fibrin generated from circulating blood. Fibrin sealant, which is prepared from high concentrations of thrombin and fibrinogen, has been used in liquid form to promote hemostasis during vascular surgery. In a blinded, randomized, placebo-controlled fashion, we evaluated a dry dressing of purified, viral-inactivated human fibrinogen and human thrombin in a large animal model of arterial injury. METHODS: Dressings were prepared by application of a layer of lyophilized human fibrin sealant or immunoglobulin G (IgG, control) to a silicone backing material. Six anesthetized female Yorkshire pigs (16 to 27 kg) received bilateral, 4 mm longitudinal femoral arteriotomies after surgical exposure of the arteries. The arteriotomies were not closed. In each animal a fibrin sealant dressing was applied to one artery and a control dressing to the other. Each dressing was secured on the arteriotomy by a mechanical device. After application of the dressings, blood flow was restored to each limb for 1 hour. The compressive device was released for 5 seconds at intervals of 15 minutes to assess hemostasis. Blood flow was measured distal to each arteriotomy with a dual-channel flowmeter to adjust equal bilateral compression. RESULTS: Blood loss (mean +/- SEM) was significantly less from the arteriotomy treated with the fibrin-based dressing compared with the control dressing (4.9 +/- 4.0 ml versus 82.3 +/- 11.1 ml; p = 0.0005). Complete hemostasis was achieved at the first 15-minute interval in five of six arteriotomies treated with fibrin sealant and in none of the six control arteriotomies during 1 hour of assessment (p = 0.03). Blood flow through each femoral artery at baseline was the same in both treatment and control arteries (fibrin sealant, 114.2 +/- 17.4 ml/min; control, 106.7 +/- 16.5 ml/min; p = 0.24) and was not significantly different throughout the experiment. CONCLUSIONS: Fibrin-based dressings provide effective hemostasis in a large animal model of arterial injury. Further development of these dressings will address optimal formulation and configuration for clinical use. Our results suggest that fibrin-based dressings will be effective in promotion of hemostasis in arterial bleeding, without compromising blood flow.

p42 mitogen-activated protein kinase in brain: prominent localization in neuronal cell bodies and dendrites.

Neurotransmitters and growth factors can trigger activation of a newly described family of mitogen-activated protein kinases. To help define the role of this kinase family in signal transduction in the nervous system, we have conducted immunohistochemical studies to localize p42 mitogen-activated protein kinase in rat brain sections. Light-microscopic studies revealed staining in neuronal cell bodies and dendrites that is particularly prominent in superficial layers of the neocortex, the hippocampal CA3 region and dentate gyrus, as well as cerebellar Purkinje cells. Discrete staining of oligodendrocytes was also apparent in fiber tracts, indicating expression of p42 mitogen-activated protein kinase in both neuronal and glial cell types. Electron-microscopic studies demonstrated that staining in dendrites is closely associated with microtubules. In the cell bodies, prominent staining was associated with the Golgi apparatus. In contrast, immunolabeling of synaptic terminals was not detected. Previous studies have demonstrated that p42 mitogen-activated protein kinase responds to neuronal stimulation. Immunohistochemical studies presented in this paper demonstrate prominent staining for this kinase in neuronal cell bodies and dendrites. Therefore, this kinase is likely to play a key role in postsynaptic signal transduction. As both p42 mitogen-activated protein kinase and microtubule-associated protein 2, an in vitro substrate of p42 mitogen-activated kinase, are associated with dendritic microtubules, this kinase may mediate effects of growth factors or neurotransmitters on the dendritic cytoskeleton.

Vesicular and cytoplasmic localization of neurotensin-like immunoreactivity (NTLI) in neurons postsynaptic to terminals containing NTLI and/or tyrosine hydroxylase in the rat central nucleus of the amygdala.

Neurotensin and catecholamines in the central nucleus of the amygdala (CNA) have both been implicated in the integration of autonomic responses to stress. We examined whether there might be a cellular substrate for interactions involving these putative neurotransmitters in the CNA. Sections of acrolein-fixed rat brain were processed either (1) for the ultrastructural localization of a rat antiserum against neurotensin using the peroxidase-antiperoxidase (PAP) method, or (2) for the dual localization of rat neurotensin antiserum and rabbit antiserum against the catecholamine-synthesizing enzyme, tyrosine hydroxylase (TH), using the PAP method and immunoautoradiography. The rat polyclonal antiserum against neurotensin was shown in immunoblots to recognize neuromedin N and Lys-Arg-neurotensin (LANT-6) in addition to neurotensin. In single and dual labeling studies, the neurotensin-like immunoreactivity (NTLI) was detected in perikarya and processes. The NTLI was localized predominantly to dense core vesicles in one group of perikarya and dendrites, while a second group had labeling both in dense core vesicles and more diffusely throughout the cytoplasm. Terminals also showed NTLI, particularly in association with dense core vesicles. The labeled terminals formed primarily symmetric junctions with both cell bodies and dendrites. In the dual labeling study, perikarya contained only NTLI while terminals contained TH and/or NTLI. Terminals containing TH or NTLI separately innervated cell bodies and dendrites displaying NTLI, and formed separate or convergent inputs onto unlabeled neuronal targets. Terminals colocalizing both TH and NTLI formed junctions only on unlabeled dendrites. These findings show that in the rat CNA two populations of neurons differ with respect to their distribution of NTLI, and that the output from neurons containing NTLI is modulated by direct synaptic input from terminals containing neurotensin and/or catecholamines. Release of neurotensin and catecholamines, most likely dopamine, from the same or separate terminals on common targets in the CNA may account for certain similarities in their stress-related functions.

GABA-labeled terminals form proportionally more synapses with dopaminergic neurons containing low densities of tyrosine hydroxylase-immunoreactivity in rat ventral tegmental area.

The levels of the catecholamine synthesizing enzyme, tyrosine hydroxylase (TH) are known to be closely regulated by neural feedback. Moreover, we have shown that intensity of TH-immunoreactivity varies with afferent input to the A10 group of dopaminergic neurons in the rat ventral tegmental area (VTA). This region is extensively and heterogeneously innervated by GABAergic afferents that mediate a number of different behavioral responses to iontophoretically applied GABA mimetics. We sought to determine: (1) whether there was an ultrastructural substrate for GABAergic innervation of TH-immunoreactive neurons; and (2) whether detectable TH-immunoreactivity varied in proportion to their GABAergic input in the two major subdivisions of the VTA, the parabrachial pigmentosus and paranigral subnuclei. Rabbit antiserum to TH and rat antiserum to GABA were visualized in single coronal sections of acrolein-fixed rat brain using a combination of peroxidase-antiperoxidase (PAP) and immunoautoradiography (ARG) or PAP and silver-intensified immunogold (SIG). Two dual-labeling electron microscopic immunocytochemical methods were employed to optimize detection of antigens and to more accurately quantify densities of TH-immunoreactivity and types of synaptic associations. Ninety-six GABA-labeled terminals (43 in the parabrachial and 53 in the paranigral subdivisions) were examined with PAP and ARG; 462 (238 in parabrachial and 224 in paranigral subdivisions) were examined with PAP and SIG. Analyses of both subnuclei yielded similar results; thus, the data were combined. With both methods, most GABA-labeled terminals (63% for SIG, 66% for PAP) formed direct synapses with TH-labeled profiles. These synaptic specializations were symmetric, the type thought to mediate inhibition. In single sections where GABA-labeled terminals were presynaptic to TH-labeled profiles, they comprised 45% (PAP) to 54% (SIG) of the total number of synaptic inputs onto TH-labeled cell bodies and 65% (SIG) to 80% (PAP) of the synaptic input onto TH-labeled dendrites. This value would be significantly less, if the analysis included all sections containing only GABA or TH irrespective of their synaptic relationships. The density of TH-immunolabeling, whether low (light) or high (intense), was determined in PAP- and SIG-labeled tissue. By both labeling methods, the numbers of GABA-immunopositive terminals forming synapses with lightly and intensely TH-immunoreactive profiles appeared equal. However, lightly TH-labeled neurons received fewer synaptic contacts from unlabeled terminals and, consequently, received proportionally more GABA-labeled terminals. GABA-labeled and unlabeled terminals were often in direct apposition to each other and were surrounded laterally, but not separated from each other, by astrocytic processes.(ABSTRACT TRUNCATED AT 400 WORDS)

Ultrastructural localization of neurotensin-like immunoreactivity within dense core vesicles in perikarya, but not terminals, colocalizing tyrosine hydroxylase in the rat ventral tegmental area.

Within the rat ventral tegmental area (VTA), the parabrachial pigmentosus and paranigral subdivisions are known to differ in their functional responses to injected neurotensin. These subdivisions also vary in their connections with other brain regions and in their number of neurotensin-containing perikarya as seen by light microscopy. In both subdivisions, there may be intracellular as well as synaptic relations between dopamine and neurotensin. Dopaminergic neurons are known to be physiologically activated by neurotensin (NT) and may also contain this peptide. To characterize further the cellular relationships in each subdivision, we examined the ultrastructural immunocytochemical localization of a rat antiserum against NT and a rabbit antiserum against the catecholamine-synthesizing enzyme tyrosine hydroxylase (TH) in single sections. The NT antiserum was raised against the entire peptide sequence. Immunoblots showed that the antiserum recognized the original antigen as well as the related peptides neuromedin N and lysine 8- arginine 9- neurotensin 10-13 (LANT-6). In both the parabrachial pigmentosus and paranigral subdivisions, neurotensin-like immunoreactivity (NTLI) was localized predominantly in the large (80-100 nm) dense core vesicles using the peroxidase anti-peroxidase (PAP) method. In tissue labeled for NT by the PAP method and for TH by immunoautoradiography, serial section analysis revealed that all perikarya containing NTLI (n = 19) were also TH-positive. Three times as many perikarya colocalized NTLI and TH in the parabrachial pigmentosus subdivision (n = 15) as in the paranigral subdivision (n = 4). Occasionally, a perikaryon containing TH and NTLI could be found in direct apposition to a TH-labeled perikaryon without glial separation. In contrast to perikarya and dendrites, terminals showing NTLI (38 in parabrachial pigmentosus, 29 in paranigral) lacked detectable TH labeling. Of the terminals containing NTLI whose synaptic junctions could be identified, 48% were symmetric and 10% were asymmetric. The targets of these terminals included perikarya and dendrites lacking detectable immunoreactivity (69% in parabrachial pigmentosus, 55% in paranigral), immunolabeled for TH (26% in parabrachial pigmentosus, 38% in paranigral) or containing both NTLI and TH (5% in parabrachial pigmentosus, 7% in paranigral). Single terminals containing NTLI sometimes contacted more than one neuronal target, some of which were apposed to each other without glial separation. TH-labeled terminals synapsed onto double-labeled perikarya in the paranigral subdivision, but were not observed to do so in the parabrachial pigmentosus subdivision.(ABSTRACT TRUNCATED AT 400 WORDS)

Ultrastructural localization of tyrosine hydroxylase in the rat ventral tegmental area: relationship between immunolabeling density and neuronal associations.

Dopaminergic neurons of the A 10 cell group in the rat ventral tegmental area (VTA) exhibit electrical and dye coupling. Also, the activity of these neurons at least partially reflects their content of tyrosine hydroxylase (TH), the rate-limiting enzyme in catecholamine biosynthesis. We examined the ultrastructural localization of TH to determine the morphological features of dopaminergic neurons in the VTA and the relationships between their TH immunoreactivity content and afferent input. Antiserum against the trypsin-treated form of TH was localized using peroxidase-antiperoxidase (PAP) and immunoautoradiographic methods. Immunoreactivity was detected in perikarya, dendrites, and terminals. The perikarya contained the usual organelles, as well as cilia, lamellar bodies, and subsurface cisterns. Qualitative evaluation of peroxidase reaction product and quantitative analysis of the number of silver grains/unit area revealed varying amounts of TH immunoreactivity in nuclei and cytoplasm. Lightly or intensely labeled nuclei were not necessarily associated with corresponding cytoplasmic labeling density. However, cytoplasmic labeling directly corresponded to the relative frequencies of neuronal appositions and synaptic input. Those neurons with less dense cytoplasmic PAP product received fewer synaptic contacts and were less frequently in apposition to other TH-labeled soma and dendrites than neurons displaying relatively more dense cytoplasmic PAP product. Analysis of single sections revealed that 67% (n = 71) of all TH-labeled somata and 15% (n = 2431) of all TH-labeled dendrites were in apposition to other TH-labeled soma or dendrites. TH-labeled terminals were rarely detected and contained relatively low levels of immunoreactivity. The majority of labeled terminals (n = 29/46) formed synapses with labeled soma and dendrites. Unlabeled terminals (n = 2424) in contact with TH-labeled dendrites appeared to form predominantly symmetric synapses. Ten percent (n = 248) of the unlabeled terminals dually synapsed onto adjacent immunoreactive dendrites, perikarya, or dendrite and perikaryon. We conclude that in the rat VTA, (1) detected TH immunoreactivity in cytoplasm, but not nucleus, corresponds to the level of feedback principally from nondopaminergic afferents; (2) dendrodendritic as well as axodendritic synapses between TH-immunoreactive neurons may mediate dopaminergic autoinhibition; and (3) gap junction-like appositions between neurons and convergent inputs from unlabeled terminals onto TH-immunoreactive profiles provide an anatomical substrate whereby cellular activities might be coordinated under certain conditions.

Effects of a new anti-allergic agent: the magnesium salt of N-acetyl-aspartyl-glutamic acid on experimental allergic inflammation of the rabbit eye.

We evaluated the efficacy of N-Acetyl-Aspartyl-Glutamic acid (magnesium salt) (NAAGA) eye-drops in preventing the conjunctival and uveal allergic inflammation induced by reverse passive Arthus reaction in the rabbit. The permeability of the blood-conjunctival and blood-aqueous barriers was investigated by the leakage of 125I-labelled rabbit serum albumin injected intravenously prior to the challenge with the antigen. Permeability of both barriers was markedly increased 2 hours after the triggering of the allergic reaction; marked edema of the conjunctiva was also observed. Pretreatment with 1, 3, 6% (w/w) NAAGA eye-drops prevented the conjunctival inflammatory changes in a dose related manner and to a lesser degree, the breakdown of the blood-aqueous barrier. The distribution of topically applied 14C-NAAGA in the rabbit eyes was also investigated.