Secondary rhythms of automatically functioning systems

In wakeful rats at the age from newborn to 3 weeks there were studied interrelations of rhythmical oscillations of heart rate, respiration rate, and periodic spontaneous motor activity. In all studied systems, these oscillations are coordinated and occur in several frequency diapasons. Frequencies in the near-minute diapason (the period from 30 to 90 s) are the most constant and do not change with age. Regular oscillations are the most stable in newborns. Bursts of motor activity usually are irregular, but episodically the distinct near-minute rhythm is traced. Studies of the character of interaction of the heart activity, respiration, and periodic somatomotor excitation allow stating that the main coordination pathway of spontaneous autorhythmic functions in early postnatal ontogenesis is formation of secondary rhythms. Possible ways of formation of the secondary rhythms are considered.     

Role of sympathetic and parasympathetic mechanisms in formation of secondary cardiac rhythms in rats ontogenesis

In progeny of Wistar rats aged from birth to 3 week, there was studied participation of sympathetic and parasympathetic mechanisms in regulation of cardiac rhythm and its rhythmic oscillations (secondary cardiac rhythms), whose spectral composition was analyzed using rapid Fourier transformation. Consequences, which changed in the process of development, of blockade of -adrenoreceptors by propranolol, of -adrenoreceptors by phentolamine, and of muscarinic cholinoreceptors by atropine as well as of chronic desympathization by guanethidine (isobarine). It was found that due to heterochronia in establishment of functions of sympathetic and parasympathetic nervous systems, reactions to blockade of adreno- and cholinoreceptors for the first 3 weeks of postnatal ontogenesis changed not only quantitatively, but also qualitatively. Blockade of adrenoreceptors in newborn animals leads to an increase of power of the rhythm oscillations in all low-frequency diapasons. The baroreflex function of parasympathetic innervation is well expressed as early as in newborns. Tonic function with respect to frequency of heart rate and power of oscillations in the high-frequency diapason becomes evident only by the 3-week age.Translated from Zhurnal Evolyutsionnoi Biokhimii i Fiziologii, Vol. 41, No. 1, 2005, pp. 69–75.Original Russian Text Copyright © 2005 by Bursian, Sizonov, Semenova, Kulaev, Timofeeva, Polyakova, Dmitrieva.     

Peculiarities of myocardial electrogenesis in laboratory rats under conditions of acute nitrite intoxication

In anesthetized male rats the arterial blood pressure in femoral artery and electrocardiogram in standard leads were recorded uninterruptedly for 1–1.5 h under conditions of acute nitrite intoxication produced by a subcutaneous injection of water solution of sodium nitrite (donor of nitric oxide) at concentrations of 10, 30, and 50 mg/kg body mass. Results of the study have shown dose-dependent changes of arterial pressure as well as of time and amplitude characteristics of electrocardiogram under effect of NaNO₂. At the threshold hypoxic dose, an increase of amplitude of R and S waves was observed by the 30–45th min, while at the maximal NaNO₂ dose, amplitude of all waves rose by the 15th min of intoxication. High nitrite doses often caused an elevation of the ST segment above the isoelectric line and a rise of the amplitude of the T wave, on which a notch appeared in some cases. The change of the ECG time parameters was expressed in the dose-dependent development of bradycardia for the first 4–7 min; its level correlated with the progressively decreasing arterial pressure in the beginning (the 2–4th min) of nitrite intoxication. Variation analysis of the heart rate spectral characteristics by Baevskii’s method has revealed a rise of the total spectral power of pulse oscillations. Under effect of nitrite, in the specter of cardiointervals, the slower oscillations have been revealed with frequency of 0.15–0.2 Hz in the LF diapason with subsequent recovery of the normal ECG specter at the end of the experimental period. The maximal nitrite dose produced more pronounced shifts of the heart rate specter towards the LF and VLF diapasons that were not restored for 1 h of experiment. Transitory processes of readjustment of the cardiac rhythm had discrete character. The nitrite dose of 100 mg/kg body mass increased the RR-interval after 4–7 min with amplitude steps of 3–5 imp/s and the time constant of 20–40 s. The revealed ECG changes had the reflex (enhancement of parasympathetic tonus) and metabolic (the hypoxic and histotoxic damage of myocardium) nature.     

The frequency composition of the brain electrical activity in rats after the use of the delta-sleep peptide and its analogs]

Frequency spectra of brain electrograms in the course of 1 h after peripheral and central administration of the delta-sleep peptide (DSIP) or two its analogues were studied in freely moving rats. In autumn series of experiments carried out on 18 animals was revealed the phase action of DSIP being manifested in initial (up to 20 min after the injection) suppression of fast (20-26 Hz) oscillations in electrocorticograms and their augmentation in subsequent intervals. Under the identical conditions analogues of DSIP induced the effects characteristic for different phases of DSIP action. In spring-summer series of experiments carried out in 6 animals was revealed a significant increase of the delta-waves in electrical activity of the Putamen after intraperitoneal injection of DSIP and its first analogue. Under the conditions of intraventricular injection DSIP induced stable augmentation of oscillations in a diapason of 14-16 Hz in the neocortex, and its analogues induced similar changes in a nearby frequency diapason of 9.6-11 Hz.     

The variability of respiratory pattern and gas exchange

It is known, that spectral analysis of heart rate and respiratory variability allows to find out the very low frequency (VLF) rhythm. However it is not known, it is necessary to carry this rhythm to what type of wave processes. The purpose of the present researches was to study the respiratory variability and the variability of gas exchange parameters. 10 healthy subjects have been surveyed. The pneumogramms within 30 minutes spent record, and then a method "breath-by-breath" within 30 minutes registered gas exchange parameters (Ve--lung ventilation, V(O2) -O2 consumption and other parameters). Fast Fourier transform method has found out two groups of the basic peaks. The first--in a range 0.2-0.3 Hz (a time cycle--3-5 s), that corresponds respiratory frequency which size at subjects varied from 12 to 20 per minute. The second--in a range 0.002-0.0075 Hz, that corresponds VLF diapason (a time cycle--1-3.5 minutes). At the analysis pneumogramms rhythms in the same ranges have been established. The carried out researches allow to draw a conclusion on steady character of wave process in a VLF-range. It can be carried to quasi-periodic oscillations type. First oscillator or respiratory frequency it is formed by means of mechanisms of chemoreception. Considering, that V(O2) and V(CO2) are function energy exchange, it is possible to believe, what exactly energy demand define the second oscillator.     

Effect of change in levels of motor activity and innervation on basic and secondary rhythms of rat heart rate and respiration in ontogenesis

Changes in the heart basic rhythm, its rhythmical variations on periodograms, and level of spontaneos motor activity were studied on offspring of white rats from newborn to 3-week age at transition from the state of active wakefulness to narcosis as well as under conditions of blockade of M-cholinoreceptors with atropine. It is shown that the endogenous rhythmical activity can be regulated not only by a change in frequency of basic rhythms, but also by action on all parameters and properties of their rhythmical variations and secondary rhythms. The changes in power of the heart secondary rhythms exceed considerably the frequency oscillations of basic rhythms during blockade of cholinergic innervation or a change in the motor activity level that affects both the basic rhythm circulation and respiration and their variations--secondary rhythms. The atropine blockade of M-cholinoreceptors at the studied ages changes the heart beating rhythm within the limits of 10% of bradicardia in newborns to tachycardia in the 3-week old animals. At the same time, power of the cardiac rhythm secondary oscillations changes several times. These data indicate that the cholinergic mechanisms play the key role in formation of the secondary rhythms and their correlation with motor activity.     

Effect of change in levels of motor activity and innervation on basic and secondary rhythms of rat heart beatings and respiration in ontogenesis

Changes in the heart basic rhythm, its rhythmical variations on periodograms, and level of spontaneous motor activity were studied on offspring of white rats from newborn to 3-week age at transition from the state of active wakefulness to narcosis as well as under conditions of blockade of M-cholinoreceptors with atropine. It is shown that the endogenous rhythmical activity can be regulated not only by a change in frequency of basic rhythms, but also by action on all parameters and properties of their rhythmical variations and secondary rhythms. The changes in power of the heart secondary rhythms exceed considerably the frequency oscillations of basic rhythms during blockade of cholinergic innervation or a change in the motor activity level that affects both the basic rhythm circulation and respiration and their variations—secondary rhythms. The atropine blockade of M-cholinoreceptors at the studied ages changes the heart contraction rhythm within the limits of 10% of bradycardia in newborns to tachycardia in the 3-week old animals. At the same time, power of the cardiac rhythm secondary oscillations changes several times. These data indicate that the cholinergic mechanisms play the key role in formation of the secondary rhythms and their correlation with motor activity.     

High-frequency network oscillations in cerebellar cortex

Both cerebellum and neocortex receive input from the somatosensory system. Interaction between these regions has been proposed to underpin the correct selection and execution of motor commands, but it is not clear how such interactions occur. In neocortex, inputs give rise to population rhythms, providing a spatiotemporal coding strategy for inputs and consequent outputs. Here, we show that similar patterns of rhythm generation occur in cerebellum during nicotinic receptor subtype activation. Both gamma oscillations (30-80 Hz) and very fast oscillations (VFOs, 80-160 Hz) were generated by intrinsic cerebellar cortical circuitry in the absence of functional glutamatergic connections. As in neocortex, gamma rhythms were dependent on GABA(A) receptor-mediated inhibition, whereas VFOs required only nonsynaptically connected intercellular networks. The ability of cerebellar cortex to generate population rhythms within the same frequency bands as neocortex suggests that they act as a common spatiotemporal code within which corticocerebellar dialog may occur.     

COMPARISON OF OSCILLATIONS OF SKIN BLOOD FLOW AND DEOXYGENATION IN VASTUS LATERALIS IN LIGHT EXERCISE

The purpose of the present study was to compare oscillation of skin blood flow with that of deoxygenation in muscle during light exercise in order to determine the physiological significance of oscillations in deoxygenation. Prolonged exercise with 50% of peak oxygen uptake was performed for 60 min. Skin blood flow (SBF) was measured using a laser blood flow meter on the right vastus lateralis muscle. Deoxygenated haemoglobin/myoglobin (DHb/Mb) concentration in the left vastus lateralis were measured using a near-infrared spectroscopy system. SBF and DHb/Mb during exercise were analysed by fast Fourier transform. We classified frequency bands according to previous studies (Kvernmo et al. 1999, Kvandal et al. 2006) into phase I (0.005-0.0095 and 0.0095-0.02 Hz), phase II (0.02-0.06 Hz: phase II) and phase III (0.06-0.16 Hz). The first peak of power spectra density (PSD) in SBF appeared at 0.0078 Hz in phase I. The second peak of PSD in SBF appeared at 0.035 Hz. The third peak of PSD in SBF appeared at 0.078 Hz. The first peak of PSD in DHb/Mb appeared at 0.0039 Hz, which was out of phase I. The second peak of PSD in DHb/Mb appeared at 0.016 Hz. The third peak of PSD in DHb/Mb appeared at 0.035 Hz. The coefficient of cross correlation was very low. Cross power spectra density showed peaks of 0.0039, 0.016 and 0.035 Hz. It is concluded that a peak of 0.016 Hz in oscillations of DHb/Mb observed in muscle during exercise is associated with endothelium-dependent vasodilation (phase I) and that a peak of 0.035 Hz in DHb/Mb is associated with sympathetic nerve activity (phase II). It is also confirmed that each peak of SBF oscillations is observed in each phase.     

Change of Parameters of Functioning of the Cardiovascular and Respiratory Systems in Rats of Different Ages under Effects of Low Doses of the Cholinesterase Inhibitor Phosphacol

In the 4-day old rat pups and adult animals there were studied effects of subacute and acute phosphacol intoxication at the doses producing and not producing inhibition of aetylcholinesterase on ECG parameters and respiration rate. Analysis of the heart rhythm variability (HRV) was performed using an original program designed in the Labview media. The frequency diapason of cardiointervals was divided as follows: the high-frequency component (HF)-0.8-2.5 Hz, the low-frequency (LF, waves of the II order)-0.8-0.3 Hz; frequencies lower than 0.3 Hz-VLF (slow waves of the III order). Under the conditions of the subacute intoxication the heart rate frequency in the 4-day old and in adult rats increases by 36% and 13%, respectively, the respiration rate frequency increases by 73% in the newborn and does not change in adult rats. The VHR analysis indicates an increase of the tone of the parasympathetic nervous system. The level of the sympathetic activity somewhat increases in adults, but decreases in the 5-day old rat pups, which leads to an essential shift of the vagosympathetic balance towards predominance of parasympathetic influences. In adult rats, unlike the newborns, the role of the humoral-metabolic factors in regulation of the cardiac rhythm and vasomotor reactions increases significantly. Remarkably, the decrease of the nervous sympathetic effects in the rat pups leads to the positive chronotropic effect and stabilization of the cardiac rhythm. Acute phosphacol intoxication (doses of 0.25 and 1 µg/kg) is studied in the 4-day old rat pups. The low dose of the drug leads to development of a moderate bradycardia without disturbances of the cardiac rhythm. The high phosphacol dose produces pronounced bradycardia; on its background there develops a long-term transitory arrhythmia representing complexes of the heart rhythm, which alternate in the decasecond or nearminute rhythm and are separated by periodicity that is one order slower. We observed such rhythm earlier during activation of central N-cholinoreactive structures and development of bilateral pneumothorax. Results of the present study allow stating the paradoxical heart rhythm not as agonic, non-peculiar to the “living” organism, but as a special form of functioning of cardiac pacemakers due to disturbances of the heart regulatory mechanism.__________Translated from Zhurnal Evolyutsionnoi Biokhimii i Fiziologii, Vol. 41, No. 2, 2005, pp. 160–167.Original Russian Text Copyright © 2005 by Kuznetsov, Goncharov, Glashkina.     

Oscillatory processes in lymph microcirculation in the human skin

This study was the first to use laser Doppler flowmetry followed by wavelet analysis in order to estimate oscillations in lymph microcirculation in 30 subjects with (n = 13) or without (n = 17) edema of the distal part of the upper limb. Lymph flow in the human skin exhibited clear dominance of pacemaker phase oscillations in the frequency ranges of 0.021–0.042 and 0.016–0.035 Hz in the skin of the palm surface of the finger nail bone and in the skin of the forearm, respectively. Edema was associated with an increase in the peak frequencies and normalized maximum amplitudes (Al/Ml, where Al is the mean value of the maximum amplitude of phase oscillations, and Ml is the value of the averaged lymph flow expressed in perfusion units). Low-amplitude oscillations were recorded rarer in the myogenic, endothelial, and respiratory ranges. We did not find any cardiac pulse rhythm in the wavelet spectrum of the lymph flow. We did not find any interaction between the Al/Ml value and the skin temperature. In the group of subjects without edema, under physiological conditions only, we found a negative correlation between the Al/Ml value and the amplitudes of myogenous proper blood flow oscillations, which reflected the number of functional capillaries and activity of oxidative metabolism in the tissue. In the group with edema, we did not find any correlations between the indices of lymph flow and blood flow. The values of normalized amplitude and frequency of phase oscillations may be used as efficient diagnostic tools in the studies on lymph microcirculation.     

Chaotic component of human high-frequency EEG in the state of quiet wakefulness

Chaotic component of human EEG oscillations in the high-frequency band (14.7-100 Hz) was investigated. EEG was recorded from four points in symmetrical frontal and occipital scalp areas. The results of the non-linear analysis of the high-frequency EEG indicate the existence of the deterministic chaotic component with a high attractor correlation dimension. It was significantly different from the respective values of the Gaussian noise filtered in the same frequency band. In the state of quiet wakefulness (eyes closed), the dimensions of chaotic components of the EEG in all derivations did not differ from each other. Analysis of correlation pairs between the ensembles of correlation dimensions of the high-frequency EEG revealed reliable patterns of significant connections between the neocortical areas with individual features in different subjects. When the functional state of the brain was changed by hyperventilation, both the values of the correlation dimensions and the structure of inter-area connection patterns changed. We believe that the nonlinear component of high-frequency EEG is a sensitive and local characteristic of the functional state of the human brain.     

γ节律振荡机制在视觉研究中的新进展

γ节律振荡是大脑皮质中常见的,频率在30～80 Hz之间的神经振荡模式,在初级视觉通道中能观察到多种起源的γ节律振荡.在小鼠、猫与猴V1的视觉诱发的γ节律振荡主要起源于L2/3和L4B,并对刺激参数敏感.猫与小鼠初级视觉通道(视网膜、LGN与V1)中观察到起源于视网膜由亮度诱发的高频γ节律振荡;在猴LGN却没有观察到γ节律振荡,而在V1上记录到亮度诱发的γ活动.γ节律振荡的产生与抑制性中间神经元网络有重要的关系,其中抑制性中间神经元中PV细胞被认为与自发γ节律振荡的产生相关. SOM细胞的参与对低频γ节律振荡(20～40 Hz)的产生起到关键作用;而光栅诱发的高频γ节律振荡(65～80 Hz)主要与PV细胞有关.动物在不同生理状态、发育阶段与脑疾病状态下光栅诱发的γ节律振荡存在较大差异,反映大脑对视觉信息加工的变化.     

Long-term measurement of heart rate in chicken eggs

Taking advantage of acoustocardiogram (ACG), we measured the heart rate (HR) of chick embryos continuously from day 12 until hatching and then investigated the development of HR irregularities (HRI), HR variability (HRV), and the existence of a circadian rhythm in mean HR (MHR). HRI comprised transient bradycardia and tachycardia, which first developed on day 14 and 16 in most embryos, respectively. Transient bradycardia increased in frequency and magnitude with embryonic development and occurred over periods of up to 30 min in some embryos. MHR was maximal on around days 14-15 and thereafter decreased to about 250-260 bpm on days 16-18. Baseline HRV, which is an oscillation of the MHR baseline, occurred as HR decreased from days 15-16 and became predominant on days 17-18. The magnitude of the baseline oscillations reached up to 50 bpm in some embryos and the period ranged between about 40-90 min (ultradian rhythm). A circadian rhythm of MHR was not found in late chick embryos. On days 18-19, embryonic activities were augmented and then breathing movements began to occur, disturbing ACG signals and thus making it difficult to measure the HR. Instead, the development of breathing activities was recorded. Breathing frequency was irregular at first and then increased to a maximum of about 1.5 Hz prior to hatching.     

Spectral characteristics of electrical activity of the respiratory center in brain processes in fetus and newborn rats in vitro

Power spectral analysis of inspiratory discharges of C3-C5 ventral roots in brainstem-spinal cord preparation from foetal (18 and 20 gestation days) and newborn (0-1 and 2-3 postnatal days) rats was performed. The respiratory centre perinatal development manifests itself by decreasing of respiratory rhythm variability and increasing of inspiratory burst duration. In foetal inspiratory bursts, low-frequency oscillations (1-10 Hz) dominate. In early postnatal stage, the relative power of low-frequency oscillations begin to decrease, and medium frequency oscillations (10-50 Hz) start to dominate over the inspiratory discharge. The data obtained suggests, that perinatal maturation of respiratory centre is characterised by stabilisation of the respiratory rhythm generation and developmental alteration of inspiratory activity's spectral and temporary parameters.     

Cardiac rhythms in developing emu hatchlings

Six emu hatchlings were non-invasively measured for electrocardiogram (ECG) from their chest wall using flexible electrodes, and the instantaneous heart rate (IHR) was determined from ECG throughout the first week of post-hatching life. Although the baseline heart rate (HR) was low, approximately 100-200 beats per min (bpm), compared with chick hatchlings, the IHR fluctuated markedly. The fluctuation of IHR comprised HR variability and irregularities that were designated as types I, II and III in chick hatchlings and additional large accelerations distinctive of emu hatchlings. Type I was HR oscillation with a mean frequency of 0.37 Hz (range 0.2-0.7 Hz), i.e. respiratory sinus arrhythmia (RSA). From RSA, breathing frequency in emu hatchlings was estimated to be approximately half of that in chickens. Type II HR oscillation was also found in the emu; the frequency ranged from approximately 0.04 to 0.1 with a mean of 0.06 Hz, and the magnitude tended to be large compared with that of chickens. In addition to type III HRI, which was designated in chickens, large, irregular HR accelerations were characteristic of emu hatchlings. From IHR data, developmental patterns of mean heart rate (MHR) were constructed and plotted on a single graph to inspect the diurnal rhythm of MHR by visual inspection and power spectrum analysis. A circadian rhythm was not clear in the emu hatchlings, in contrast to chick hatchlings, which showed a dominant diurnal rhythm.     

Serotonin reuptake blocker fluoxetine suppresses hippocampal theta oscillation in rabbits during EEG

In earlier studies it has been shown that stimulation of the median raphe nucleus (MR) in awake rabbits decreases the expression and frequency of oscillatory theta activity in the septohippocampal system, and the functional blockade of this nucleus evokes the regular and high-frequency theta rhythm. The present work was aimed at elucidation of serotoninergic influence of MR (which also contains cells of other chemical nature) to the septohippocampal system of theta activity. Serotonin reuptake blocker fluoxetine that increases brain serotonin level was applied. Hippocampal electroencephalogram was recorded in awake rabbits. Bilateral intracerebroventricular infusion of fluoxetine hydrochloride (Sigma, St. Louis; 15 micrograms in 5 microliters saline) in all cases reduced the rhythmic theta activity. In 15 of 18 (83.3%) of experiments the decrease in hippocampal theta oscillations was more than 50% of the control level. The theta band of the spectral density histogram decreased in the mean by 56 +/- 5.8% of the control level (from 10 to 93% in different experiments, p < 0.001). The mean latency of these changes was 3.5 +/- 0.11 minutes (2.9-4.1 min), the effect duration was 64 +/- 3.2 min (45.3-90 min). The mean frequency of the theta waves did not change as compared to the baseline and was equal to 5.25 +/- 0.5 Hz (4.5-6.5 Hz). The fluoxetine-induced reduction of the theta rhythm expression in hippocampus is the evidence of its inhibitory control by serotoninergic brain system. It is suggested that the increase of the frequency of hippocampal theta rhythm after the functional blockade of MR observed in our earlier experiments was the result of a release of the septohippocampal system from the influence of nonserotoninergic neurons (via glutamatergic reticular formation) and/or temporary cessation of the MR interaction with noradrenergic, dopaminergic and glutamate/aspartate systems.     

Pan politicus. Review of Chimpanzee Politics: Power and Sex Among rhe Apes,by Frans de Waal. New York,Harper & Row, 1982, 223 pp., $16.50

This report describes periodic oscillations in electroencephalographic (EEG) and behavioral activity with a cycle length of 15–30 seconds in chair-restrained squirrel monkeys (Saimiri sciureus). These oscillations consisted of alternating episodes of vigilance, characterized by visual scanning and motor movement, and inattentiveness, characterized by behavioral quiescence with little eye or limb movement. During vigilance the EEG exhibited low-amplitude, high-frequency (> 16 Hz) activity. During quiescent periods, a high-amplitude synchronized EEG was present with activity in the 8–16-Hz band predominating. The presence or frequency of this EEG and behavioral periodicity was not modified by time of day, as no difference was found between morning and afternoon recording sessions. Although the factors or mechanisms responsible for this rhythm are unclear, it should be noted by those investigators studying the behavior or neurophysiology of Saimiri sciureus in the laboratory setting.     

Unstable equilibrium behaviour in collapsible tubes

Thick-walled silicone rubber tube connected to rigid pipes upstream and downstream was externally pressurised (pe) to cause collapse while aqueous fluid flowed through propelled by a constant upstream head. Three types of equilibrium were found: stable equilibria (steady flow) at high downstream flow resistance R2, self-excited oscillations at low R2, and 'unattainable' (by varying external pressure) or exponentially unstable equilibria at intermediate R2. The self-excited oscillations were highly non-linear and appeared in four, apparently discrete, frequency bands: 2.7 Hz, 3.8-5.0 Hz, 12-16 Hz and 60-63 Hz, suggesting that the possible oscillation modes may be harmonically related. Stable, intermediate 'two-in-every-three-beats' oscillation was also observed, with a repetition frequency in the 3.8-5.0 Hz band. As pe was increased, self-excited oscillations were eventually suppressed, leaving internal fluid pressure varying with no single dominant frequency as a result of turbulent jet dissipation at the downstream rigid pipe connection. Comparison of pressure-wave velocity calculated from the local pressure-area relation for the tube with fluid velocity indicated that supercritical velocities were attained in the course of the self-excited oscillations.     

Locomotion-related oscillatory body movements at 6-12 Hz modulate the hippocampal theta rhythm

The hippocampal theta rhythm is required for accurate navigation and spatial memory but its relation to the dynamics of locomotion is poorly understood. We used miniature accelerometers to quantify with high temporal and spatial resolution the oscillatory movements associated with running in rats. Simultaneously, we recorded local field potentials in the CA1 area of the hippocampus. We report that when rats run their heads display prominent vertical oscillations with frequencies in the same range as the hippocampal theta rhythm (i.e., 6-12 Hz). In our behavioral set-up, rats run mainly with speeds between 50 and 100 cm/s. In this range of speeds, both the amplitude and frequency of the "theta" head oscillations were increasing functions of running speed, demonstrating that the head oscillations are part of the locomotion dynamics. We found evidence that these rhythmical locomotor dynamics interact with the neuronal activity in the hippocampus. The amplitude of the hippocampal theta rhythm depended on the relative phase shift with the head oscillations, being maximal when the two signals were in phase. Despite similarity in frequency, the head movements and LFP oscillations only displayed weak phase and frequency locking. Our results are consistent with that neurons in the CA1 region receive inputs that are phase locked to the head acceleration signal and that these inputs are integrated with the ongoing theta rhythm.