Neuroleptics and Dopamine Transporters

The effects of neuroleptic treatments on dopamine transporters and on dopamine receptors was investigated in the forebrain of adult rats treated for 21 days with either haloperidol, clozapine or saline. The dopamine D₁receptors, labeled with [³H]SCH23390, increased in nucleus accumbens, latero-dorsal rostral neostriatum and substantia nigra, after clozapine but not haloperidol. The dopamine D₂receptors, studied with [³H]raclopride, increased in nucleus accumbens and in dorsolateral, ventro-medial and dorso-medial quadrants of the rostral neostriatum after either haloperidol or clozapine treatments, and also in latero-ventral rostral neostriatum but only after haloperidol. Haloperidol also up-regulated D₂receptors in rostral and caudal neostriatum, but clozapine produced a more uneven increase, especially in caudal neostriatum. In contrast, the densities of dopamine uptake sites, or transporters, labeled with [^I25I]RTI-121, remained unchanged after both neuroleptic treatments. The observation that dopamine transporters are resistant to treatments that modify D₁and D₂receptors indicates that these uptake sites can probably be ruled out as the target of neuroleptic drugs, and that dopamine receptor up-regulations can indeed occur independently of the densities of nerve endings at the terminal fields of innervation.     

Fetal breathing movements and lung maturation in the congenitally abnormal human fetus

Fetal breathing movements have been studied in conjunction with features of anatomical and biochemical development of the lung at birth in fetuses with congenital abnormalities affecting the respiratory system. Total absence of fetal breathing movements or abnormal fetal breathing movements were associated with lung hypoplasia and failure of normal surfactant release into saline extracts of lung fluid. Surfactant synthesis was demonstrated regardless of the presence or absence of fetal breathing movements. The study supports the hypothesis that normal fetal breathing movements are important for fetal lung development and suggests that surfactant synthesis and its release are independent. The latter process may be dependent upon fetal breathing movements while the former is not.     

Neuroleptics,learning disability,and the community: some history and mystery.

Recent papers have again highlighted the consistently high use of neuroleptic agents among people with a learning disability, despite the lack of good evidence to support their role in this population for behaviour management and despite the risks of such medication. Evidence suggests, however, that prescribing habits have remained relatively unchanged; the reasons for this are poorly understood. Given the lack of understanding about the factors contributing to such drug use, and the possibility that use of neuroleptics will increase as people with learning disabilities move into the community, there seems a clear need for clinical guidelines to cover the prescribing and monitoring of neuroleptics within this group. Such guidelines should also ensure that reviews, using reliable measures of treatment efficacy, are carried out regularly.     

Human megakaryocytopoiesis--normal and abnormal.

Regulation of megakaryocyte and platelet production remains poorly understood. In culture system two separate activities are needed for maximum production of megakaryocyte progenitors: promotor of clonal expansion and promoter of maturation, other growth factors and cells also contribute to regulation of megakaryocytopoiesis. Increased proliferation of megakaryocytes is observed in myeloproliferative disorders and idiopathic thrombocytopenic purpura, and decreased proliferation is found in aplastic anaemia and hypomegakaryocytic thrombocytopenia. Dysmegakaryocytopoiesis is present in myelodysplastic syndromes and acute leukaemia, and a proliferation of immature megakaryocytes in acute megakaryoblastic leukaemia. Increased understanding of human megakaryocytopoiesis is beginning to help in rational clinical management.     

Eye movements in heterophoria.

Reference is made to earlier reports by the author in which versional recovery eye movements were observed during the cover test in the non-occluded eye in case of heterophoria. This provided support for Hering's Law, although the magnitude of the versional movement did not relate to the degree of heterophoria. Recent studies of eye movements during the cover test on very small heterophorias have suggested there is a threshold value below which these versional recovery movements are absent, and that is presence depends on such factors as the size of the phoria, the degree of ocular motor dominance and patient concentration.     

Mandible movements in ants.

Ants use their mandibles for almost any task, including prey-catching, fighting, leaf-cutting, brood care and communication. The key to the versatility of mandible functions is the mandible closer muscle. In ants, this muscle is generally composed of distinct muscle fiber types that differ in morphology and contractile properties. Fast contracting fibers have short sarcomeres (2-3 microm) and attach directly to the closer apodeme, that conveys the muscle power to the mandible joint. Slow but forceful contracting fibers have long sarcomeres (5-6 microm) and attach to the apodeme either directly or via thin thread-like filaments. Volume proportions of the fiber types are species-specific and correlate with feeding habits. Two biomechanical models explain why species that rely on fast mandible strikes, such as predatory ants, have elongated head capsules that accommodate long muscle fibers directly attached to the apodeme at small angles, whereas species that depend on forceful movements, like leaf-cutting ants, have broader heads and many filament-attached fibers. Trap-jaw ants feature highly specialized catapult mechanisms. Their mandible closing is known as one of the fastest movements in the animal kingdom. The relatively large number of motor neurons that control the mandible closer reflects the importance of this muscle for the behavior of ants as well as other insects.     

Neuroleptics antagonize a calcium-activated potassium channel in airway smooth muscle

We examined the effect of neuroleptics on Ca-activated K channels from dog airway smooth muscle cells. Because these agents inhibit a variety of other Ca-mediated processes, it seemed possible that they might also inhibit Ca-activated K channels. In excised, inside-out patches, several neuroleptics potently and reversibly inhibited the K channel from the internal but not the external surface of the patch. Measurements of the effect on open probability and open- and closed-state durations support a simple kinetic model in which neuroleptics bind to and block the open channel. Inhibition by neuroleptics was moderately voltage dependent, with blockers less potent at hyperpolarizing voltages. The relationship between voltage and the dissociation constant for the blocker suggests that the binding site is one-third of the way across the channel's electrical field. Equilibrium dissociation constants for the drug-channel complex were: haloperidol, 1.0 +/- 0.1 microM; trifluoperazine, 1.4 +/- 0.1 microM; thioridazine, 2.4 +/- 0.1 microM; and chlorpromazine, 2.0 microM. This rank-order potency is different from their potency as calmodulin inhibitors, which suggests that neuroleptics bind to the channel rather than a calmodulin-channel complex.     

Gliding movements in Myxococcus xanthus.

Prokaryotic gliding motility is described as the movement of a cell on a solid surface in the direction of the cell's long axis, but its mechanics are unknown. To investigate the basis of gliding, movements of individual Myxococcus xanthus cells were monitored by employing a video microscopy method by which displacements as small as 0.03 micron could be detected and speeds as low as 1 micron/min could be resolved. Single cells were observed to glide with speeds varying between 1 and 20 microns/min. We found that speed variation was due to differences in distance between the moving cell and the nearest cell. Cells separated by less than one cell diameter (0.5 micron) moved with an average speed of 5.0 micron/min, whereas cells separated by more than 0.5 micron glided with an average speed of 3.8 microns/min. The power to glide was found to be carried separately at both ends of a cell.