The 3-channel Lissajous' trajectory of the auditory brain-stem response. V. Effects of stimulus intensity in the cat

Three-channel Lissajous' trajectories (3-CLTs) of the cat auditory brain-stem response (ABR) were recorded using click stimuli ranging from 10 to 70 dB impulse SPL and were analyzed using planar analysis.The number of planar segments increased from typically 4 at 10 dB to 12 at 70 dB but certain shape features of the 3-CLT (apices) were preserved across stimulus levels. As stimulus level was raised, size of individual planar segments increased. There were progressive decreases in apex latency as stimulus level was increased. The combined durations of groups of high intensity planar segments were similar to those of their low intensity forms. Shape, size and orientation of planar segments tended to change more across stimulus intensities below 40 dB than above and appear to relate to the number of planar segments at any given stimulus level.These results suggest that changes in latency seem to be primarily cochlear in origin, whereas the origin of other observed changes is uncertain. The 3-CLT ABR is sensitive to intensity, especially below 40 dB, and can thus detect changes in auditory system function in response to changes in stimulus intensity, regardless of electrode position.     

Temporal correspondence of intracranial,cochlear and scalp-recorded human auditory nerve action potentials

Conventional, vertex-ipsilateral ear records (‘A’), as well as 3-channel Lissajous' trajectories (3-CLTs) of auditory brain-stem evoked potentials (ABEPs) were recorded from the scalp simultaneously with tympanic membrane electrocochleograms (‘TME’) and auditory nerve compound action potentials (‘8-AP’) recorded intracranially using a wick electrode on the auditory nerve between the internal auditory meatus and the brain-stem. The recordings were made during surgical procedures exposing the auditory nerve.The peak latency recorded from ‘TME’ corresponded to trajectory amplitude peak ‘a’ of 3-LLT and to peak ‘I’ of the ‘A’ channel ABEP. Peak latency of ‘8-AP’ was slightly longer than the latency of peak ‘II’ of ‘A’ when ‘8-AP’ was recorded from the root entry zone and the same or shorter when recorded from the nerve trunk. ‘8-AP’ peak latency was shorter than trajectory amplitude peak ‘b’ of 3-CLT regardless of where the wick electrode was along the nerve. Peak latencies from all recordings sites clustered into two distinct groups—those that included N1 from ‘TME’, peak ‘I’ of the ‘A’ record and trajectory amplitude peak ‘a’ of 3-CLT, and those that included the negative peak of ‘8-AP’ and trajectory amplitude peak ‘b’ of 3-CLT, as well as peak ‘II’ of the ‘A’ record, when present. In one case, the latency of peak ‘II’ and trajectory amplitude peak ‘b’ was manipulated by changing the conductive properties of the medium surrounding the auditory nerve.These results are consistent with other evidence proposing: (1) the most distal (cochlear) portion of the auditory nerve is the generator of the first ABEP component (‘I’, ‘a’); (2) the proximal auditory nerve is the major contributor to the ‘A’ channel ABEP component ‘II’; (3) in addition to the auditory nerve, more central structures participate in the generation of the 3-CLT ‘b’ component.     

Three-channel Lissajous' trajectory of the binaural interaction components in human auditory brain-stem evoked potentials

The 3-channel Lissajous' trajectory (3-CLT) of the binaural interaction components (BI) in auditory brain-stem evoked potentials (ABEPs) was derived from 17 normally hearing adults by subtracting the response to binaural clicks (B) from the algebraic sum of monaural responses (L + R). ABEPs were recorded in response to 65 dB nHL, alternating polarity clicks, presented at a rate of 11/sec. A normative set of BI 3-CLT measures was calculated and compared with the corresponding measures of simultaneously recorded, single-channel vertex-left mastoid and vertex-neck derivations of BI and of ABEP L+R and B. 3-CLT measures included: apex latency, amplitude and orientation, as well as planar segment duration and orientation.The results showed 3 apices and associated planar segments (“Bd_II,” “Be” and “Bf”) in the 3-CLT of BI which corresponded in latency to the vertex-mastoid and vertex-neck peaks IIIn, V and VI of ABEP L + R and B. These apices corresponded in latency and orientation to apices of the 3-CLT of ABEP L + R and ABEP B. This correspondence suggests generators of the BI components between the trapezoid body and the inferior colliculus output. Durations of BI planar segments were approximately 1.0 msec. Apex amplitudes of BI 3-CLT were larger than the respective peak amplitudes of the vertex-mastoid and vertex-neck recorded BI, while their intersubject variabilities were comparable.     

Three-channel Lissajous′ trajectories of auditory event-related potentials to target stimuli

Three orthogonal recordings (‘X’, ‘Y’ and ‘Z’) of event-related potentials (ERPs) evoked by auditory target stimuli were represented in 3-dimensional voltage-space, to produce 3-channel Lissajous′ trajectories (3-CLTs). Stimuli were verbal or non-verbal and were differentiated by their pitch, phonemic or phonetic attributes. Visual inspection and quantitative evaluations unexpectedly revealed that the 3-CLT of these ERPs strongly resembles a ‘hair-pin’ trajectory. This trajectory tilted in space at characteristic angles with each of the analysis axes: 133° with the ‘X’ axis, 87° with the ‘Y’ axis, and 54° with the ‘Z’ axis. The relatively small inter-subject variability observed in the geometrical measures, particularly in orientation, may be attributed to the slight variation in the underlying generators. 3-CLT analysis could be useful in future clinical as well as source studies of ERP generators.     

Tetrahedral recording of 3-D BAEPs: evidence for the centered dipole model

Three-dimensional brain-stem auditory evoked potentials (3-D BAEPs) were recorded from 12 normal subjects using a new tetrahedral montage, as well as two other bipolar montages previously described for 3-channel Lissajous' trajectories (3-CLTs). Mean responses, as well as between-subject and within-subject variability were described. A mathematical transformation was applied to the recorded trajectories to render them in a common canonical form to test the assumption that the BAEP conforms to a centrally generated dipolar field. Apex, segment, and plane orientations were measured for each trajectory, and discrepancies between montages were evaluated to judge the adequacy of the centered dipole model. For the vector means of apices, segments, and planes, median angles of discrepancy between montages ranged from 10 to 23°. These results support the validity of a centered dipole model for the BAEP and affirm the rationale for employing the 3-channel recording technique. Among the montages studied, the tetrahedron provided maximum economy by using fewer electrodes, avoided certain problematic recording sites, and produced less variable data.     

Brain-stem auditory evoked potentials in the common marmoset (Callithrix jacchus)

Brain-stem auditory evoked potentials (BAEPs) were recorded in 10 common marmosets (Callithrix jacchus) to investigate the effects of recording electrode configurations, stimulus rate, and stimulus frequency on BAEP wave forms and peak latencies. Tone burst stimulations were used to evaluate the effects of pure tone on BAEP wave forms. Five positive peaks superimposed on positive and negative slow potentials were identified in the BAEP recorded at the linkage between the vertex and the dorsal base of the ear ipsilateral to a monaural stimulus. When the reference electrode was placed at the ipsilateral mastoid or the neck, the amplitudes of positive and negative slow potentials and the incidence of wave I increased. There were no significant changes in peak latencies of BAEP waves with changes in stimulus rate from 5 to 20/s. It was possible to record the BAEPs in response to tone burst stimulations at frequencies extending from 0.5 to 99 kHz. Wave I appeared apparently at high stimulus frequencies; while waves III to V, at low frequencies. Wave II was recorded at frequencies ranging from 0.5 to 99 kHz and comprised a superposition of 2 or 3 potentials.     

Three-dimensional human somatosensory evoked potentials

Median nerve somatosensory evoked potentials were recorded from 30 normal adults using conventional scalp derivations and an orthogonal bipolar surface electrode montage. This allowed the determination of the spatial orientation of the hypothetical centrally located equivalent dipole derived from the evoked response recorded in 3-dimensional voltage space. The 3-dimensional voltage trajectory describing changes in equivalent dipole orientation and magnitude revealed 4 major apices between 5 and 25 msec, 3 of which corresponded to the traditional P14, N20 and P25 peaks. A fourth apex at 17 msec was not as evident in the conventional recordings and signaled a transition from a vertical P14–N18 generator process to a horizontal N20 generator process. The normal within- and between-subject variability of trajectory apices, segments and planes are described, along with the theoretical and practical implications of this recording technique.     

Auditory brain-stem responses in the fragile X syndrome.

Auditory brain-stem responses (ABRs) were recorded from a group of 12 mentally retarded males with the fragile X (fra[X]). The responses were analyzed in terms of ABR thresholds, absolute latencies, and interpeak latencies. One patient had increased ABR thresholds, indicating hearing impairment. Five fra(X) subjects had prolonged I-V interpeak latencies. Comparisons between the fra(X) group (excluding one possible hard-of-hearing subject) and a control group of age-matched males with normal intelligence showed that the fra(X) group's interpeak latencies were significantly prolonged for the III-V and I-V but not for the I-III. This pattern of prolongation of interpeak latencies suggests that central, as opposed to peripheral, nervous-system dysfunction predominates in many patients having this syndrome. In addition, frequently observed prolongation of the transmission time may indicate that brain-stem white-matter functioning is also apt to be involved in this syndrome.     

Wave III of brain-stem auditory evoked potentials analysed both with 3-channel Lissajous' trajectory and dipole localization method

Wave III of the BAEP was analysed both with 3-channel Lissajous' trajectory (3-CLT) and a dipole localization method. The experiments were performed on 5 normally hearing subjects. The dipole analysis used an iterative algorithm assuming a spherical head model and homogeneous media. 3-CLT planar analysis was performed with a laboratory system. The parameters of plane C (azimuth and elevation) corresponding to wave III and those of the equivalent dipole showed a similar orientation of the plane and the dipole. This result is in agreement with previous investigations and confirms the interest of 3-CLT in far-field analysis and, at the same time, validates the dipole localization model used in this study, at least for BAEP analysis.     

Computer simulation study of the shape of motor unit action potential

Motor unit action potentials (MUAPs) of brachial biceps were simulated. A simulated MUAP was obtained as a sum of single fibre action potentials (SFAPs) from all the muscle fibres of a motor unit (MU). The influence of the following factors on MUAP shape for different kinds of recording electrode was studied: fibre density, neuromuscular jitter, temporal dispersion and electrode displacements. The simulation confirms that typical MUAPs recorded with needle electrodes from muscles of low fibre density such as brachial biceps are usually triphasic. Increased fibre density produces MUAPs of more complex shape and higher amplitude. Normal neuromuscular jitter is responsible for the variability of shape of subsequent potentials from the same MU as well as for electromyographic shimmer. Pathologic (increased) jitter makes the shapes of subsequent potentials unrecognizable. The influence of temporal dispersion is interconnected with other factors but rather of minor importance. The simulation shows how big changes in MUAP shape can be expected due to electrode displacements during single experiment or during estimation of MU territory.     

Optimal signal filtering parameters for tetrode recording of neuronal activity

Extracellular recording of neuronal spiking is the main method of investigation of involvement of neurons in behavioral tasks. Development of multichannel electrodes made it possible to simultaneously record activity of the same group of neurons from different locations in the brain tissue. That method allows the researches to distinguish spiking of simultaneously recorded neurons by individual set of projection coefficients of amplitude parameters on axes corresponding to different channels of the multichannel electrode. We tested the possibility of effective separation of single unit spiking streams from multiunit activity recorded by tetrode and subjected to different filtering. We described the main limitations for effective spike identification and determined the optimal band of signal filtering for tetrode recording.     

Brain-stem,middle latency and late cortical evoked potentials in children with speech and language disorders

The topography of the brain-stem (ABR), middle latency (MLR) and cortical (ACR) evoked responses was investigated in chilfren with nornal speech and language development and those with either a language or motor speech disorder. The aim was to determine whether it is possible to discriminate between the groups of children in terms of the evoked potential characteristics.There were significant inter-group differences, particularly relating to the amplitude of the different responses. The ABR in both the language and motor speech groups exhibited smaller amplitudes for waves I, III and V than the control group, with no change in latency. Two explanations were suggested; firstly abnormal functioning of the peripheral hearing mechanism even though the hearing thresholds were normal which could be a secondary effect due to deprivation normal speech recording effects due to differences in the electrical conductivity of tissue and the distance separating the generator site and recording electrodes. The MLR in the motor speech group was significantly larger at the mastoid and temporal electrode sites than either the control or language groups. This was considered to be an enhanced myogenic response like the other exaggerated brain-stem reflexes seen in congenital suprabulbar paresis. Significantly larger amplitudes of the ACR were also recorded from the motor speech group at the Cz electrode site. This was thought to be due to underactivity of some normal cortical inhibitory system and not a direct result of increased MLR amplitude.The ACR in the language disordered children exhibited an abnormal left temporal hemispheric dominance and a more inverted or ‘dissimilar’ wave from at the T3 electrode site on the correlation analysis. These findings suggest impaired functioning of the left temporal cortex in our children who have failed to develop language normally. We feel that this has more significance for the language abnormality than the low amplitude ABRs which were observed in both the language and motor speech disordered children.     

New head exposure system for use in human provocation studies with EEG recording during GSM900- and UMTS-like exposure

A new head exposure system for double blinded human provocation studies, which requires EEG recording during exposure with GSM900- and UMTS-like signals has been developed and dosimetrically evaluated. The system uses planar patch antennas fixed at 65 mm distance from the subject's head by a special headset, which provides minimum impairment of the test subjects and ensures an almost constant position of the antennas with respect to the head, even in case of head movements. Compared to exposure concepts operating small antennas in close proximity to the head, the concept of planar antennas at a certain distance from the head produces a much more homogeneous SAR distribution in the temporal and parietal lobe of the brain. At the same time the resulting uncertainty of exposure due to variations in head size, variations of the dielectric properties of tissues and unavoidable small changes of the antenna's position with respect to the head, is reduced to the order of approximately 3 dB, which is a significant improvement to comparable head exposure systems reported in literature in the past. To avoid electromagnetic interference on the EEG recording caused by the incident RF-field an appropriate double-shielded filter circuit has been developed. Furthermore, the effect of the presence of the sintered Ag/AgCl EEG electrodes and electrode wires on the SAR distribution inside the head has been investigated and was found to be minimal if the electrode wires are arranged orthogonal to the incident electric field vector. EEG electrode arrangement parallel to the incident field vector, however, might cause drastic changes in the SAR distribution inside the head.     

Brain-stem auditory evoked potentials (BAEPs) from basal surface of temporal lobe recorded from chronic subdural electrodes

BAEPs were recorded from the basal surface of the temporal lobe by subdural electrodes chronically implanted in 6 patients who were evaluated for surgical management of intractable partial seizures. Near-field recordings were obtained by recording between the subdural electrode closet and most distant to the brain-stem. Far-field recordings were obtained by recording between the subdural electrodes and an indifferent electrode over the spinal process of the seventh cervical vertebrae. The recordings were compared with standard ear-vertex recordings.After ipsilateral ear stimulation, the subdural electrode closet to the brain-stem recorded large amplitude waves I and II, followed by less well-defined waves of longer latencies. Recordings to contralateral stimulation showed no clearly defined waves I and II and a large amplitude wave Vn. Waves III, IV, V, Vn and VI were of opposite polarity after ipsi- and contralateral stimulation. These findings indicate that waves I and II are generated ipsilaterally to the stimulation side, whereas wave Vn has a contralateral origin. Wave Vn may be generated in the brachium of the inferior colliculus, as suggested from latency and from dipole configuration studies. This conclusion is consistent with the classical anatomical observations that the supracollicular auditory pathways are predominantly crossed.     

On the errors in assessment of severity of involuntary movements using surface EMG.

Surface electromyogram (SEMG) is a useful tool to depict involuntary movements, but evaluation of the intensity of such movements with SEMG over multiple recording instances requires awareness of factors influencing quantified SEMG signals. We investigated the differences in the amplitude of SEMGs due to electrode displacement in isometric voluntary contraction in the upper arm, forearm and lower leg in 8 healthy men. The SEMGs of gross muscle activity simultaneously recorded with 4 electrode pairs from the agonist and antagonist sides in 3 displacement conditions with respect to parallel position, interelectrode distance, and rotation were compared. The amount of EMG integration (equivalent to the average SEMG amplitude) of each electrode pair was compared to the reference electrode pair with interelectrode distance of 40 mm placed on the center of the tested muscles. The average EMG difference ratios ranged 1.1-2.2%/mm in parallel shift, 1.0-1.9%/mm in distance shift, and 0.3-0.6%/degree in rotation shift. Displacement error of electrodes in separate recording instances should be reduced using anatomical landmarks, when SEMG is applied as a quantitative method to evaluate change in the states of involuntary movements.     

High-resolution separation and accurate size determination in pulsed-field gel electrophoresis of DNA. 3. Effect of electrical field shape

The resolution of pulsed-field gel electrophoresis is dramatically affected by the number and configuration of the electrodes used, because these alter the shape of the applied electrical fields. Here we present calculations and experiments on the effect of electrode position in one of the most commonly used pulsed-field gel electrophoresis configurations. The goal was to explore which aspects of the electrical field shape correlate with improved electrophoretic resolution. The most critical variable appears to be the angle between the alternate electrical fields. The most effective electrode configurations yield angles of more than 110 degrees. A continually increasing angle between the fields produces band sharpening that greatly enhances the resolution.     

Flow microfluorometric analysis of sperm DNA content: effect of cell shape on the fluorescence distribution.

The DNA content of individual sperm from populations of acriflavine-stained cells was investigated by analysis of fluorescence frequency distributions obtained with high-resolution flow-systems instruments. Sperm with spherical or cylindrical heads from three mollusk species produce narrow, symmetric fluorescence distributions. Flat sperm heads from six eutherian species produce asymmetric distributions consisting of a peak with a lateral extension to higher fluorescence values. The unexpected shape of these distributions was shown to be due to the flat geometry and high refractive index of the sperm heads in conjunction with the orthogonal axes of flow, excitation, and detection in the flow-systems instruments. The theoretical and experimeytal results indicate that the lateral extension can be eliminated either by controlling the sperm orientation with planar flow conditions or by accounting for sperm orientation by means of orientation sensing.     

On the occurrence of adventitious branch roots on root axes of trees

Based on positive results for 11 of 17 species included in an anatomical survey of tree roots, we concluded that the origin of adventitious branch roots (ABR) on established, undisturbed woody parental root axes is a widespread occurrence. ABR were morphologically indistinguishable from branch roots formed in primary tissues of a parental axis, and they occurred without increase in branch root density. We concluded that ABR are an unrecognized component of undamaged root systems. Using continuous serial sectioning to perform a census of branch roots within parental root axes, we obtained definitive evidence that ABR participate in root turnover. Comparisons of older and younger axes, and the chronology of root formation in older axes fulfilled the expectation that with greater age of parental axis, ABR become increasingly predominant among intact branch roots. We confirmed this trend for one of the species scoring negative in the survey, which means that our survey results were probably influenced by age variation. Thus, any of the six negative results obtained in the survey may have been dependent on the young age and slenderness of the axes that were available for examination in those six species.