Effect of corazonin and crustacean cardioactive peptide on heartbeat in the adult American cockroach (Periplaneta americana)

Changes in the frequency of cardiac pulsations have been monitored in the decapitated body of adult P. americana before and 5 h after the injections of [Arg(7)]-corazonin and CCAP, using newly invented touch-free, noninvasive optocardiographic methods. Relatively large dosages of these peptides (10(-6) M concentrations in the body) had no effect on the rate of the heartbeat beyond the Ringer control limits. It has been concluded, therefore, that Corazonin and CCAP, which are currently cited in the literature as "the most potent cardiostimulating peptides" in insects, have no effect on the physiological regulation of cardiac functions in the living body.     

Studies of morphogenesis at the Department of Embryology, Moscow State University: Towards understanding the dynamic architecture of development

This is a review of studies on morphogenesis carried out at the Department of Embryology, Moscow State University, over the past 30 years. The main direction of studies has been to reveal and describe the properties of self-organizing fields of mechanical stresses in developing embryos.     

Damping of Pressure Pulsations in Mobile Hydraulic Applications by the Use of Closed Cell Cellular Rubbers Integrated into a Vane Pump

The present study evaluates the potential of a bio-inspired pulsation damper in a vane pump used in mobile hydraulic applications.Pressure pulsations caused by such positive displacement pumps can lead to malfunctions and noise in a hydraulic system.A common measure to reduce pressure pulsations is the integration of pressure pulsation dampers downstream of the pump.This type of damping measure can also be found in biology as e.g.in the human blood circulatory system.Such working principles found in living organisms offer a high potential for a biomimetic transfer into technical applications.The newly developed bio-inspired damper consists of cellular rubbers with non-linear viscoelastic material properties.In order to evaluate the new damping method,pressure pulsations were measured at two different back pressures and at a wide engine speed range of the vane pump.For further assessment,different setups,varying the stiffness of the cellular rubber materials and the damper volume,were tested.Within the tested back pressures,the pressure pulsations could be reduced by up to 40％.The developed integrated pulsation damper offers a high potential to dampen pressure pulsations of positive displacement pumps used in mobile hydraulic applications operating below 10 bar.     

Heartbeat patterns during the postembryonic development of Drosophila melanogaster

Pulsations of the dorsal vessel were recorded in vivo during the whole postembryonic development of D. melanogaster, by means of a newly invented, pulse-light opto-cardiographic method. The young larvae of the 1st and 2nd instars submerged in the feeding medium exhibited extremely high rates of heartbeat, 7Hz at room temperature. These values are among the highest rates of heartbeat ever recorded in the animal kingdom. The fully grown larvae of the 3rd instar showed approximately half of the maximum heartbeat rate (3.5-4Hz), which became stabilized after pupariation to 2.5-2.7Hz.The larval heartbeat was always uni-directional, in the forward-oriented or anterograde direction and it was almost continuous. The slowly disintegrating, old larval heart used to beat at the constant frequency of 2.5-2.7Hz until complete cessation of all cardiac functions in 1-day-old puparium. In spite of the persisting constant heartbeat frequency, the transformation process of the larval heart was associated with successively decreasing amplitude of the systolic contractions and with the prolongation of the resting periods. The newly formed heart of the pupal-adult structure exhibited a qualitatively new pattern of heartbeat activity, which was manifested by periodic reversal of the heartbeat with the faster anterograde and slower retrograde phases. The frequencies of both of these reciprocal cardiac pulsations gradually increased during the advanced pharate adult period, reaching the values of 4-5Hz at the time of adult eclosion. Adult males and females also exhibited a perfect pattern of heartbeat reversal, with still very high rates of the anterograde heartbeat, in the range of 5-6Hz. In addition to the cardiac functions, we have recorded several kinds of extracardiac pulsations, which often interfered severely with the recordings of the heartbeat. There were strong, irregular extracardiac pulsations of a neurogenic nature (somatic muscles, oral armature) and relatively slow extracardiac pulsations of a myogenic nature (intestinal peristaltics, 0.2-0.3Hz). The extracardiac and cardiac pulsations were independent, their functions were not correlated. A possibility of creating new challenges in combination of molecular biology with the functional physiology of the heart have been discussed.     

Tenebrio beetle pupae show a conditioned behavioural response to pulse rotations of a geomagnetic field

Abstract.  Pupae of holometabolous insects are not motionless and insensitive developmental stages. Their behavioural display is restricted to rotations or contractions of the abdomen in a range of movements from the clearly visible to the microscopic of the order of tenths of microns. Pupae react spontaneously and surprisingly sensitively to mechanical, light or sound stimuli. In the present study, reactions of yellow mealworm beetle ( Tenebrio molitor , L.) pupae to a geomagnetic field rotation are examined. By means of a micromechanical recording technique, peaks of abdominal contractions are monitored before and after magnetic treatment and show that spontaneous behavioural reaction to a magnetic pulse is insignificant. Nevertheless, using negative reinforcement training, a conditioned magneto-sensitive reaction is elicited. These surprising sensory and behavioural capacities of an insect pupa are discussed.     

Seasonal variations in myocardial infarctions and the possible biotropic influence of short-period geomagnetic pulsations on the human cardiovascular system

Analysis of ambulance calls in Moscow during 1979–1981 reporting myocardial infarction (85 700 events), sudden death (71 700 events), and hypertension crises (165 500 events) shows the presence of clear seasonal variations with a deep summer minimum and a winter maximum. The same trend was upon analysis of monthly data on infarction mortality in Bulgaria over 15 years (1970–1985). One of the biotropic factors influencing the human cardiovascular system can be geomagnetic pulsations Pc1, agreeing in frequency with cardiac rhythms. In the seasonal trend, Pc1 have maximum intensity in winter. The comparison of data on ambulance calls in Moscow with the Pc1 observation data catalog revealed that, on ～70% of days, an abnormally large number of myocardial infarction calls was accompanied by the presence of Pc1; their concurrence was half again the chance expectation. Besides, it was determined that the biotropic influence of magnetic storms in winter was much higher than in summer. One of the plausible reasons of the winter infarction maximum could be seasonal variations in the production of the pineal hormone melatonin, which destabilized the organism and increased its sensitivity to geomagnetic disturbances attended by Pc1.     

Basic morphogenetic processes in Hydrozoa and their evolutionary implications: an exercise in rational taxonomy

Species-specific morphology in thecate hydroids is considered as a function of 2 fundamental morphogenetic characteristics: parameters of growth pulsations and the relation between the migratory activities of the endo- and ectodermal cells of the growing tips. Comparative, experimental and modelling data are presented suggesting that increases in the values of these parameters lead to gradual transformation of the narrow tubular rudiments of primitive thecates to the more transversely extended and later bilaterally symmetrical morphologies of advanced forms. There is a corresponding change in the mode of branching, from stolonal through alternate to opposite, with densely packed hydranths and hydrothecae. The relations between the traditional systematic approach to this group and the present ontogenetically based interpretation are discussed.     

Mechanics of growth pulsations as the basis of growth and morphogenesis in colonial hydroids

Growth and shaping in colonial hydroids (Hydrozoa, Cnidaria) are realized due to the functioning of special colony elements, growing tips located at the terminuses of branched colony body. Unlike in plants, the growing tips of colonial hydroids are sites of active cell movements related to morphogenesis and lacking proliferation. The activity of hydroid growing tips is expressed as growth pulsations: cyclic repetitions of their apex extensions and retractions. The parameters of growth pulsations are species specific and related to the shape of a forming element. Here, the succession of cell movements and changes in mutual arrangement within the growing tip are described in detail at all pulsation phases. The role of the inner cell layer in the tip activity was demonstrated for the first time. Relationships between the growing tip parameters, length and diameter, and pulsations are discussed. A scheme is proposed for cyclic processes in both epithelial layers. An explanation is provided for the two-step mode of growth pulsations with relative independence of the main phases. It was proposed that successive activities of the tip ecto-and endoderm serve as driving forces provided there is a hard outer skeleton. This scheme makes it possible to explain some patterns of growth and morphogenesis in colonial hydroids, such as gradually increasing growth rate of a new tip and its maximum growth rate, differences in the parameters of growth pulsations between shoot and stolon tips, shoot base inclination towards the stolon tip, etc., and provides a basis for further improvement of the model of morphogenesis in hydroids.     

Mechanical aspects of heartbeat reversal in pupae of Manduca sexta

Pulsations of the dorsal vessel were investigated with new optocardiographic techniques based on the transmission and reflection of pulse-light through optic fibers. This noninvasive technique enabled simultaneous, in vivo multisensor recordings of the heartbeat without touching the pupal integument. There was a very regular heartbeat reversal with 3 distinctive phases: (a) a backward-oriented (retrograde) cardiac pulsation; (b) a forward-oriented (anterograde) pulsation with faster frequency; and (c) shorter or longer periods of temporary cardiac standstill that usually occurred after the termination of the anterograde phase. Occasionally, there were localized series of systolic cardiac contractions during the retrograde phase. Simultaneous recordings from the base and the tail of the abdomen revealed a reciprocal, "mirror image-like", quantitative relationship. The most intensive anterograde hemolymph flow occurred at the base while the most intensive retrograde flow occurred at the tail of the abdomen. The bi-directional switchovers of heartbeat (reversal) were occasionally associated with modifications during each of the unidirectional cardiac phases. Anterograde peristalsis showed a 2-fold higher frequency of pulsation in the thoracic aorta in comparison with the posterior parts of the heart. Thus, in addition to the "odd" peristaltic waves originating at the tail, there were intercallated "even" peristaltic waves originating in the middle of the abdomen. Both of them propagated hemolymph through the thoracic aorta into the head; the first waves took the hemolymph in from the distal end, while the second sucked it from the middle of the abdomen. The use of multiple optocardiographic sensors also enabled detection of cardiac pulsations on the opposite, ventral side of the body, within the ventral perineural sinus. The ventral side of the head showed only the presence of an anterograde pulse, whereas the ventral side of the tail exhibited a strong reciprocal retrograde phase and a very weak anterograde phase. These results explain why the existence of a periodic heartbeat reversal should be essential for circulatory functions at both extremities of the cylindrical insect body. In diapausing pupae, regular cycles of heartbeat reversal were substituted by prolonged periods of anterograde pulsation during the entire duration of bursts of CO2 release (average duration of the burst was 18-20 min, periodicity 5 to 18 h). The physiological nature of such feed-back correlation between heartbeat and metabolic CO2 production is not yet clear, because the anterograde heartbeat could be also induced by a number of nonspecific factors unrelated to CO2 (mechanical irritation, injury, injections, elevated temperature). During the postdiapause, developing pharate-adult stage, the correlation between CO2 and anterograde heartbeat completely disappeared. It has been concluded that regulation of insect heartbeat represents a highly coordinated, myogenic stereotype with inherent rhythmicity, which can be modified by a number of external and internal factors.