Neural circuits engaged in mastication and orofacial nociception

Athanassiadis, Tuija

January 2009

A deeper understanding of both movement control and the effects of nociceptor inputs on our motor systems is critical for proper clinical diagnosis of musculo-skeletal dysfunctions and for development of novel rehabilitation schemes. In the jaw system, masticatory movements are produced by a central pattern generator (CPG) located in the brainstem. Considerable efforts have been made in deciphering this neuronal network. The present thesis contributes towards an increasingly detailed understanding of its essential elements, and presents a hypothesis of how deep somatic pain (i.e. muscle pain) may be evoked and interferes with the masticatory CPG circuitry. In Paper I, the expression of c-Fos-like protein was used as a molecular marker to visualize brainstem neurons that were active during induced fictive mastication in the anesthetized and paralyzed rabbit. Our findings provide a previously lacking detailed record of the neuronal populations that form the masticatory motor pattern. Certain cells were located in brainstem areas previously suggested to be involved in the masticatory CPG. However, it was a new finding that neurons in the dorsal part of the trigeminal main sensory nucleus (NVsnpr-d) may belong to this circuitry. Paper II focused on the discovered neurons in NVsnpr in an in vitro slice preparation from young rats.  Intracellular recordings allowed us to define two cell types based on their response to depolarizing current. Microstimulation applied to the trigeminal motor nucleus, its reticular border, the parvocellular reticular formation and the nucleus reticularis pontis caudalis, elicited postsynaptic potentials in 81% of the neurons tested. Responses obtained were predominately excitatory and sensitive to gluta-matergic antagonists DNQX or/and APV. Some inhibitory and biphasic responses were also evoked. Bicuculline methiodide or strychnine blocked the IPSPs indicating that they were mediated by GABAA or glycinergic receptors. About one third of the stimulations activated both types of neurons antidromically. Neurons in NVsnpr-d seem to gather all the conditions that can theoretically account for a role in masticatory rhythm generation. In Paper III, the masticatory model system was used to investigate the possible role of muscle spindle primary afferents in development of persistent musculoskeletal pain. Following intramuscular acidic (pH 4.0) saline injections of rat masseter muscles, in vitro whole cell recordings were done from jaw closing muscle spindle somata located in the trigeminal mesencephalic nucleus (NVmes). Compared to control neurons, the somata of afferents exposed to acid had more hyperpolarized membrane potentials, more hyperpolarized thresholds for firing, high frequency membrane oscillations and ectopic bursting of action potentials. These changes in membrane properties lasted for up to 35 days. Within the same time frame experi-mental animals showed hypersensitivity to touch on the skin covering the injected muscle. Similar saline injections also resulted in a significant increase of activity dependent c-Fos expression in NVmes neurons compared to controls. Immuno-fluorescence and lectin binding studies indicated that small-caliber muscle afferents containing known nociceptor markers (CGRP, SP, P2X3, TRPV1 and IB4) and expressing glutamate receptors are found close to the annulo-spiral endings of the NVmes afferents. Combined, our new observations support the hypothesis that excessive release of glutamate, within muscle spindles due to ectopically evoked antidromic action potentials, could lead to development of persistent musculoskeletal pain by activation and/ or sensitization of adjacent muscle afferent nociceptors.

Neurophysiology

Neurofysiologi

Estudio de la expresión génica y de la composición proteica del oviducto. Efectos del fluido oviductal sobre la resistencia de la zona pelúcida a la digestión enzimática en diferentes mamíferos.

Mondéjar Corbalán, Irene

01 November 2011

La fecundación en mamíferos consiste básicamente en la fusión de los gametos masculino y femenino para formar un zigoto capaz de dar lugar a un nuevo individuo. Hasta ahora, la mayoría de las investigaciones encaminadas al esclarecimiento de este proceso se han centrado en el estudio de la biología de ambos gametos como células aisladas, o bien en el estudio de los diversos mecanismos que tienen lugar durante la interacción de ambos. Sin embargo, se ha dejado un poco de lado a otro elemento fundamental y sin el cual el resto de estudios pueden resultar incompletos: el microambiente en el que tiene lugar el encuentro entre los gametos, es decir, el fluido y las células oviductales que secretan ciertos componentes de dicho fluido. La fase folicular tardía o etapa inmediatamente preovulatoria, es el momento en el que el oviducto se encuentra preparado para el encuentro de los gametos y para que se produzca la fecundación. Debido a la importancia de los factor es implicados en la unión de gametos que han de estar presentes en este momento preciso del ciclo estral y a la escasez de información acerca de los mismos, centramos nuestro estudio en esta fase. Para ello, se abordó el análisis de los componentes oviductales y sus características fundamentalmente desde cuatro perspectivas: (1) efecto del fluido oviductal (FO) sobre la resistencia a la digestión enzimática de la zona pelúcida en 9 especies, (2) fraccionamiento del FO bovino en base a su capacidad de unión a heparina, (3) análisis proteómico del FO y (4) análisis de la expresión génica del oviducto porcino. / Fertilization in mammals is basically the merging of male and female gametes to form a zygote that can give rise to a new individual. So far, most research aimed at clarifying this process have focused either on the study of the biology of the spermatozoon and the oocyte as isolated cells or in the study of the various mechanisms that occur during the interaction of both. However, it has been partially left to one side to another key element without which the other studies may be incomplete: the microenvironment in which the meeting takes place between the gametes, ie the fluid and the oviductal cells that secrete some components of such a fluid. The late follicular phase or immediately pre-ovulatory phase is the time when the oviduct is prepared for the meeting of gametes and fertilization occurs. Due to the importance of the factors involved in the gametes interaction which must be present at this precise moment of the estrous cycle and the scarcity of information about them, we focused our study on this phase. To do so, it was addressed the analysis of oviductal components and features mainly from four perspectives: (1) effect of oviductal fluid (OF) on the resistance to enzymatic digestion of the zona pellucida in 9 species, (2) fractionation of the bovine oviductal fluid based on their ability to bind to heparin, (3) proteomic analysis of OF and (4) gene expression analysis of pig oviduct.

Zona pelúcida

Fluido Oviductal

Oviducto

Resistencia a la digestión enzimática

Proteómica

Genómica

Coneja

Rata

Ratona

Hámster

Mujer

Cerda

Vaca

Oveja

Cabra

Oviductal fluid

Oviduct

Resistance to enzymatic digestion

Proteomic

Genomic

Rabbit, Rat

Mouse

Hamster

Woman

Pig

Cow

Sheep

Goat

Fisiología

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612