Transfer of clonidine and dexmedetomidine across the isolated perfused human placenta

Background: The placental transfer of the a₂ receptor agonist clonidine, earlier used as an adjuvant in obstetric epidural analgesia, was compared with the transfer of the newer and more %-selective agonist dexmedetomidine.
Methods: Term placentas were obtained immediately after delivery with maternal consent and a 2-hour recycling perfusion of a single placental cotyledon was performed. Disappearance from the maternal circulation, accumulation in placental tissue and appearance in the fetal circulation of clonidine or dexmedetomidine with the reference compound antipyrine were followed in 4 experiments for both drugs.
Results: At 2 hours the percent dexmedetomidine found in the fetal circulation was 12.5 (SD 5.1)%, while 48.1 (SD 20.3)% was found in the perfused placental cotyledon. A higher mean clonidine than dexmedetomidine concentration was achieved in the fetal circulation (1.90 vs. 0.56 nmol/l, P <0.05). At 2 hours the percent clonidine found in the fetal circulation was 22.1 (SD 2.4)% ( P <0.05), while 11.3 (SD 3.3)% ( P <0.05) was re tained in the perfused placental cotyledon. The transfer indexes, describing maternal-to-fetal transfer of dexmedetomidine and clonidine normalized with the transfer of antipyrine, were 0.88 (SD 0.07) and 1.04 (SD 0.08) respectively ( P <0.05).
Conclusions: Dexmedetomidine disappeared faster than clonidine from the maternal circulation, while even less dexmedetomidine was transported into the fetal circulation. This was due to its greater placental tissue retention, the basis for which probably is the higher lipophilicity of dexmedetomidine.     

Density of γ/δ+ T cells in the jejunal epithelium of patients with coeliac disease and dermatitis herpetiformis is increased with age

Increased density of γ/δ T cell receptor (TCR)⁺ intraepithelial lymphocytes is the only characteristic in the jejunum of patients with coeliac disease and dermatitis herpetiformis which is not normalized on a gluten-free diet. We explored the age-dependent changes in intraepithelial γ/δ and α/β TCR⁺ cells from 137 biopsies from patients with coeliac disease and dermatitis herpetiformis and from controls. Biopsy specimens from 100 patients with coeliac disease and dermatitis herpetiformis and from 37 controls were studied with an immunohistochemical method using MoAbs to T cell receptors and peroxidase staining. An increase in the density of intraepithelial γ/δ T cells above the mean +2 s.d. of the density in controls was present in 97 of 100 specimens from patients with coeliac disease and dermatitis herpetiformis. The density of γ/δ⁺ cells of patients with coeliac disease and dermatitis herpetiformis on a normal gluten-containing diet showed a positive correlation with age (r = 0.45, P< 0.0001). In controls, the density of γ/δ⁺ cells remained low throughout the age-range studies, from age 0.6–57 years. In controls, α/β⁺ cells increased with age (r = 0.57, P< 0.001). The increase in density of intraepithelial lymphocytes with age is in agreement with their thymus-independent character and local proliferation.     

Gross efficiency of muscular work during step exercise at -15°C and 21 °C

In an effort to assess the effect of ambient temperature on the gross efficiency (Eff_g) of step exercise 12 subjects performed a modified step test either at —15 °C or 21°C ascending to three different heights (corresponding to light, moderate and heavy work), for 20 min each with a frequency of 18 steps min^-1. Heart rate (HR), rectal temperature, skin temperatures and heat flux from skin were continuously measured. Oxygen consumption was measured during the last 5 min of each step height and perceptions of thermal sensation were recorded. The results indicate that, while using conventional clothing adequate in these temperatures, Eff_g is altered in a contradictory manner. At —15°C Eff_g increased with increasing work load, whereas at 21°C it decreased when the work load increased. The highest Eff_g (heavy work at —15°C and light work at 21°C) values are reflected as rather similar rectal temperatures (37.4–37.7°C) and identical mean skin temperatures (32.8 °C) as well as the same (slightly warm) thermal sensation of the legs. At — 15 °C the lowest Eff_g in light work was probably hue to the need to warm up the muscles. At 21°C, on the contrary, the activation of heat dissipation systems was probably responsible for the lowest Eff_g in heavy work.     

Adenosine triphosphate treatment for meconium aspiration-induced pulmonary hypertension in pigs

To investigate the pulmonary haemodynamic effects of meconium aspiration and subsequent adenosine triphosphate (ATP) treatment, 12 anaesthetized and ventilated pigs (wt 24-28 kg) received either ATP or an equal volume of saline into the right heart in doses of 0.02 to 0.80 lmol kg^-1 min^?1 after intratracheal administration of 2 mL kg^?1 of human meconium. Meconium instillation induced significant increases in pulmonary vascular pressures and total and postarterial resistances calculated from pulmonary artery occlusion studies, but did not affect the systemic haemodynamics, except for a fall in heart rate and increase in central venous pressure. Infusion of ATP at the lowest doses (0.02 and 0.08 µmol kg^?1 min^?1) selectively decreased the pulmonary arterial pressure and vascular resistance and at 0.32 and 0.80 µmol kg^?1 min^?1 reduced both the pulmonary and systemic resistances. In the lung circulation the increasing doses of ATP reduced preferably the arterial, but also the postarterial resistance. Withdrawal of ATP infusion led to a significant rebound effect especially in the postarterial segment of the lung circulation. Meconium aspiration thus induces an acute, predominantly postarterial obstruction in the lung circulation and infusion of ATP at low doses selectively dilates the pulmonary vascular bed and may help to preclude elevation of capillary pressures in meconium aspiration-induced pulmonary hypertension.     

X-irradiation-induced loss of O-2A progenitor cells in rat spinal cord is inhibited by implants of cells engineered to secrete glial growth factor 2

The loss of O-2A progenitor cells has been implicated as a critical event in radiation-induced spinal cord demyelination. To investigate whether glial growth factor 2 (GGF2) affects the number of O-2A cells in the irradiated rat cervical spinal cord, an ex vivo gene therapy approach was applied in which CHO cells engineered to express recombinant human GGF2 were injected into the cisterna magna of adult rats. Spinal cord irradiation reduced the number of O-2A cells in a dose-dependent manner. However, this radiation-induced decrease in O-2A progenitor cells was significantly attenuated by the delivery of GGF2 after irradiation. These data indicate that the cell-mediated delivery of GGF2 can reduce the loss of O-2A progenitors after irradiation.     

Clonal accumulation of activated CD8+ T cells in the central nervous system during the early phase of neuroborreliosis

Borrelia burgdorferi may cause an acute infection of the central nervous system (CNS) that rarely leads to chronic disease. To characterize host immunity to B. burgdorferi in humans, we performed serial T cell receptor (TCR) variable beta (TCRBV) chain analyses in blood and cerebrospinal fluid (CSF) samples from 10 patients with acute neuroborreliosis. In most patients, we found significant differences in TCRBV expression between CSF and peripheral blood T cells, predominantly involving CD8(+) T cells. T cells that accumulated in the CSF had a memory phenotype and expressed high levels of C-C chemokine receptor 5 and CD69. Serial studies demonstrated that CD8(+) T cell accumulation decreased continuously after resolution of the infection. In 2 patients, serial analysis of the TCR-alpha and -beta chain sequences revealed that overexpression of TCRBV in CSF was caused by extensive clonal expansion of CD8(+) T cells. Our findings support the role of CD8(+) T cells during the early host defense against spirochete infection of the CNS.     

Enhanced cognitive flexibility in reversal learning induced by removal of the extracellular matrix in auditory cortex

During brain maturation, the occurrence of the extracellular matrix (ECM) terminates juvenile plasticity by mediating structural stability. Interestingly, enzymatic removal of the ECM restores juvenile forms of plasticity, as for instance demonstrated by topographical reconnectivity in sensory pathways. However, to which degree the mature ECM is a compromise between stability and flexibility in the adult brain impacting synaptic plasticity as a fundamental basis for learning, lifelong memory formation, and higher cognitive functions is largely unknown. In this study, we removed the ECM in the auditory cortex of adult Mongolian gerbils during specific phases of cortex-dependent auditory relearning, which was induced by the contingency reversal of a frequency-modulated tone discrimination, a task requiring high behavioral flexibility. We found that ECM removal promoted a significant increase in relearning performance, without erasing already established—that is, learned—capacities when continuing discrimination training. The cognitive flexibility required for reversal learning of previously acquired behavioral habits, commonly understood to mainly rely on frontostriatal circuits, was enhanced by promoting synaptic plasticity via ECM removal within the sensory cortex. Our findings further suggest experimental modulation of the cortical ECM as a tool to open short-term windows of enhanced activity-dependent reorganization allowing for guided neuroplasticity.Structural remodeling and stabilization of synaptic networks are key mechanisms underlying learning in the adult brain. During early life, high structural and functional plasticity is required for the experience-shaped development of basic neuronal circuits (1). With brain maturation, juvenile plasticity of so-called critical or sensitive periods is decreased and is accompanied by the appearance of the brain’s extracellular matrix (ECM) and its specialized compact form named “perineuronal net” (PNN) enwrappping cell bodies and synaptic contacts (2, 3). Enzymatic degradation of the ECM in adult animals has been demonstrated to restore such forms of developmental (juvenile) plasticity with respect to topographical map plasticity in the visual cortex (4), fear-response–mediating circuits in the amygdala (5), spinal cord injuries (6, 7), and song learning circuits of zebra finches (8). In addition, enzymatic ECM removal altered several forms of synaptic plasticity in vitro and in vivo (9–12). However, even though structural stability of networks acquired during developmental phases is essential for neuronal efficiency, mechanisms allowing synaptic remodeling are key events during learning and memory formation throughout life (13). We recently demonstrated that endogenous proteases moderately digesting specific components of the ECM are regulated in an activity-dependent manner (2, 14) and ECM removal modulates synaptic short-term plasticity by synaptic exchange of postsynaptic glutamate receptors (10, 15). Further, ECM modulation enhances synaptic short-term plasticity by affecting voltage-dependent calcium channels (9). These findings challenge the view of the purely stabilizing role of ECM in the brain and indicate a potential regulatory switch for plastic network adaptations within the adult brain at the level of individual synapses by modulating the extracellular space (16). However, it remains open to what extent ECM modulations influence learning-related plasticity in the adult brain and its specific effects on behavior during a cognitive task.In the present study, we aimed at evaluating the potential role of experimental ECM removal within the auditory cortex (ACx) of Mongolian gerbils, which has been found to be particularly rich in ECM (17), during a cognitively demanding auditory go/no go shuttle-box task. We selected discrimination and reversal learning of frequency-modulated (FM) tones as a cognitive task, which necessarily requires ACx plasticity (18, 19). Injections of the ECM-degrading enzyme hyaluronidase (HYase) into the ACx after the first acquisition phase significantly enhanced subsequent reversal learning compared with sham-treated animals (injection of 0.9% saline). Particularly, after ECM degradation, animals abandoned the inappropriate discrimination strategy from the initial acquisition phase faster and thus promoted successful discrimination performance of the new contingency during reversal learning. ECM removal did not further influence the initial acquisition learning or interfere with already established—that is, learned—capacities in later learning stages, suggesting an enhanced activity-dependent neuroplastic reorganization of established synaptic networks in ACx during reversal learning.Our findings suggest that experimental degradation of the ECM in sensory cortex, although not affecting general sensory learning, does, however, enhance the cognitive flexibility that can build on the learned behaviors. Thereby, ECM degradation could be used as a tool for guided neuroplasticity, which might also bear therapeutic potential.