Tubal muscles determine embryo implantation site; prognosis of ectopic pregnancy at chronic functional disorders.

Mammalian oviducts contain smooth muscles and inward-facing ciliated epithelium. Muscular contractions, not ciliary beating, propel oocytes through the oviduct towards the uterus. In crawling gastropods (unique models for studying the functioning of phasic smooth muscles), muscular contractions, propagating along the foot sole, play a principal role in determining the crawling rate. We have described the muscular mechanisms controlling the crawling rate and hypothesize here that the same mechanisms provide embryo transportation through the human fallopian tube. The data collected for gastropods were transferred to the human fallopian tube, using embryo speed and tube length (tonus) instead of crawling speed and sole length. Smooth muscle active states: tonic contraction/relaxation and rhythmic contractions (peristalsis) are involved in ovum transport. The ovum/embryo speed is linearly correlated with the tonus of the longitudinal and/or the circular muscles of the tube. Some known bioactive substances control muscular tonus and we suppose embryo speed through the contraction force of muscle cells involved in peristaltic waves. Other known substances facilitate peristalsis and we suppose that they have no effect on muscular tonus and increase dose-dependently embryo speed through the number of muscle cells recruited in peristaltic waves (at a constant wave frequency). This number depends on the physiological state of the woman. The combination of all possible effects and the ability of muscles to contract rhythmically determine the embryo speed and its implantation site. This hypothesis is the first description of the tubal muscular mechanisms that determine normal and any type of ectopic pregnancy at chronic disorders of tubal contractility. How to predict ectopic pregnancy? We have reason to assume that the intensity of rhythmic uterine contractions reflects that in the fallopian tube. It is known that uterine contractility significantly increases during the preovulatory phase and decreases during the mid-luteal phase. The hypothesis supposes that in women with increased risk of ectopic pregnancy, decreased uterine contractility during the preovulatory phase in comparison with the norm indicates a future tubal/abdominal gestation; increased uterine contractility during this phase and/or the mid-luteal phase as compared to the norm points to a future cervical pregnancy. The optimal methods for recording uterine activity are up to clinicians.

The similarity of crawling mechanisms in aquatic and terrestrial gastropods.

Crawling gastropods are unique models for studying the functioning of smooth muscles and ciliated epithelia, since they cover the foot sole and are involved in locomotion, allowing for direct investigation. Two types of crawling are known: creeping by muscular waves in terrestrial gastropods such as Helix and сiliary gliding in aquatic gastropods such as Lymnaea. It was found that the smooth muscles that underlie the ciliated epithelium in Lymnaea are involved in gliding and contribute significantly to fast crawling. Thus, the locomotor apparatus is fundamentally the same in both snails and the difference between crawling reflects an adaptation to a habitat. The control of crawling speed is also the same. Tonic contraction, relaxation, and rhythmic contractions are involved in this control. During a locomotor episode, the sole length and crawling speed spontaneously change and directly correlate with each other via the contraction force of the muscle cells in the locomotory waves. Dopamine, unlike ergometrine, decreases the sole length and crawling speed. Serotonin stimulates, increases crawling and determines the number of muscle cells involved in the locomotory waves for each locomotor episode. This control (taking into account heterogeneity) apparently might exist in any other phasic smooth muscle, including vertebrates.

Sole smooth muscle states determine gliding rate in the freshwater snail Lymnaea stagnalis.

The sole of crawling gastropods is a unique model for studying the function of smooth muscles and ciliated epithelium. The gastropod snail Lymnaea stagnalis glides over the substratum without visible muscular contraction in its sole; consequently, the gliding was thought to be due to sole cilia. However, we have shown that the sole muscles in Lymnaea are phasic smooth muscles. They contribute extensively to gliding rate, which is directly correlated with the sole length (longitudinal sole muscle tonus) that varies widely during gliding. Here, we show that the linear relationship between gliding rate and sole length in Lymnaea may be modified. Serotonin increases gliding rate and has no effect on sole length. Dopamine contracts the sole and, consequently, slows the gliding rate, while ergometrine (a blocker of dopamine receptors) relaxes the sole and increases gliding rate. These influences on locomotion rate and sole length are similar to those obtained earlier for Helix lucorum, in which the substances changed the number and contraction force of muscle cells involved in peristaltic locomotory waves. Taken together, the data obtained here for Lymnaea and earlier for Helix describe the fundamental mechanisms for controlling phasic smooth muscles.

Responses to magnetic stimuli recorded in peripheral nerves in the marine nudibranch mollusk Tritonia diomedea.

Prior behavioral and neurophysiological studies provide evidence that the nudibranch mollusk Tritonia orients to the earth's magnetic field. Earlier studies of electrophysiological responses in certain neurons of the brain to changing ambient magnetic fields suggest that although certain identified brain cells fire impulses when the ambient field is changed, these neuron somata and their central dentritic and axonal processes are themselves not primary magnetic receptors. Here, using semi-intact animal preparations from which the brain was removed, we recorded from peripheral nerve trunks. Using techniques to count spikes in individual nerves and separately also to identify, then count individual axonal spikes in extracellular records, we found both excitatory and inhibitory axonal responses elicited by changes in the direction of ambient earth strength magnetic fields. We found responses in nerves from many locations throughout the body and in axons innervating the body wall and rhinophores. Our results indicate that primary receptors for geomagnetism in Tritonia are not focally concentrated in any particular organ, but appear to be widely dispersed in the peripheral body tissues.

Muscular waves contribute to gliding rate in the freshwater gastropod Lymnaea stagnalis.

This study revises the mechanisms of ciliary locomotion and demonstrates muscular contribution to locomotion rate in Lymnaea stagnalis. L. stagnalis sticks to the substratum by the foot sole and moves smoothly with no visible contractions of the foot. A ciliated epithelium covering the sole is underlain by smooth muscle cells containing giant mitochondria. It is shown here that slow (basal) locomotor activity (measured as the flow rate of physiological saline over isolated sole) appears spontaneously or is induced by 10(-8)-10(-7) M 5-HT. 5-HT (10(-7)-10(-4) M) facilitates locomotor activity dose-dependently, and KCN (an inhibitor of mitochondrial respiration) decreases these effects to the basal level. 5-HT and KCN have no effect on the frequency of ciliary beat (stroboscopic measurements), and blockers of anaerobic glycolysis inhibit ciliary motility. Under anaerobic conditions locomotion of a snail is slow and insensitive to 5-HT in contrast to that in aerobic environments. It is concluded that glycolysis supplies energy to ciliated cells and respiration to sole muscle cells; 5-HT stimulates ciliary beating in an all-or-none fashion and muscular waves in a dose-dependent manner; cilia provide slow (basal) gliding, and locomotory rate up to 80% above the basal level is determined by muscular waves.

Activity of the motor cortex during scratching.

In awake cats sitting with the head restrained, scratching was evoked using stimulation of the ear. Cats scratched the shoulder area, consistently failing to reach the ear. Kinematics of the hind limb movements and the activity of ankle muscles, however, were similar to those reported earlier in unrestrained cats. The activity of single neurons in the hind limb representation of the motor cortex, including pyramidal tract neurons (PTNs), was examined. During the protraction stage of the scratch response, the activity in 35% of the neurons increased and in 50% decreased compared with rest. During the rhythmic stage, the motor cortex population activity was approximately two times higher compared with rest, because the activity of 53% of neurons increased and that of 33% decreased in this stage. The activity of 61% of neurons was modulated in the scratching rhythm. The average depth of frequency modulation was 12.1 +/- 5.3%, similar to that reported earlier for locomotion. The phases of activity of different neurons were approximately evenly distributed over the scratch cycle. There was no simple correlation between resting receptive field properties and the activity of neurons during the scratch response. We conclude that the motor cortex participates in both the protraction and the rhythmic stages of the scratch response.

Immunological localization of Tritonia peptide in the central and peripheral nervous system of the terrestrial snail Helix aspersa.

We report here evidence that the pedal peptides (Peps) first discovered in mollusks may be neurotransmitters with a general role in control of molluscan somatic and visceral muscles. Using Tritonia peptide (TPep) antiserum we obtained morphological evidence for such a role in Helix aspersa. We localized 1,200-1,400 small and medium-sized (5-40 microm) TPep-IR neurons in the central nervous system of Helix and demonstrated the presence of these neurons in each ganglion. Many TPep-immunoreactive (IR) neurons were motoneurons that sent axons to almost all peripheral nerves. TPep-IR fibers innervated the foot, esophagus, hermaphroditic duct, optic tentacles, salivary gland, heart, and proximal and distal aorta. In peripheral tissues TPep-IR fiber ramifications were mostly associated with muscles and with ciliated epithelia. In addition, TPep-IR fibers were in the neuropil of the ganglia, the commissures, and the connectives, and they formed axosomatic terminals in the central nervous system. TPep-IR neurons were found in the esophagus and hermaphroditic duct and as sensory receptors in the bulb of the optic tentacles. These results from Helix, and those reported elsewhere from other mollusks, suggest a general involvement of TPep-like substances in control of muscle- and ciliary-driven motor activities, including perhaps their antecedent sensory and central axosomatic integrative activity.