Stimulation

BAEPs are elicited most commonly by brief acoustic click stimuli that are produced by delivering monophasic square pulses of 100-μsec duration to headphones or other electromechanical transducers at a rate of about 10 Hz. A rate of exactly 10 Hz or another submultiple of the power line frequency should be avoided; otherwise, the inevitable line frequency artifact will be time-locked to the stimuli and will not be removed by the averaging process. Audiometric headphones having a relatively flat frequency response are desirable so that “broad-band” clicks, whose energy is spread over a wide frequency range, will be produced.

The stimulus intensity should be loud enough to elicit a clear BAEP waveform without causing discomfort or ear damage; 60 to 65 dB HL is a typical level. If hearing loss is present, stimulus intensity may be adjusted accordingly so that stimulation is at 60 to 65 dB SL. (It should be noted that dB HL is decibels relative to the threshold of a normal population, dB SL is decibels relative to the threshold of the ear being tested, and dB nHL is decibels relative to the threshold of the specific control population used to establish a laboratory’s normative database.) Reduced stimulus intensities are also useful during BAEP recordings, as discussed later in this chapter. The subjective click threshold should be measured in all subjects in whom this is possible, to recognize hearing loss and to determine the stimulus level corresponding to 0 dB SL.

Stimuli are delivered monaurally, so that a normal BAEP to stimulation of one ear does not obscure the presence of an abnormal response to stimulation of the other ear. An acoustic stimulus delivered to one ear via headphones can reach the other ear via air and bone conduction with a volume attenuation of 40 to 70 dB and generate an evoked potential by stimulation of the contralateral ear ( Fig. 24-5 ). To prevent this contralateral stimulation from occurring and possibly being misinterpreted as a BAEP arising from stimulation of the ipsilateral ear, the contralateral ear is masked with continuous white noise at an intensity 30 to 40 dB below that of the BAEP stimulus. Acoustic crosstalk also occurs with ear-insert transducers, though the signal reaching the opposite ear is attenuated to an even greater extent, typically 70 to 100 dB.

Brainstem auditory evoked potentials (BAEPs) to monaural stimulation from a patient with one nonfunctioning ear. A , Stimulation of the unaffected ear elicits a normal BAEP. B , When contralateral noise masking is not used, stimulation of the nonfunctioning ear produces a delayed wave V because of air and bone conduction of the stimulus to the other ear. C , When masking noise is delivered to the unaffected ear, stimulation of the nonfunctioning ear does not elicit any reproducible BAEPs.

(Modified from Chiappa K, Gladstone KJ, Young RR: Brain stem auditory evoked responses. Studies of waveform variations in 50 normal human subjects. Arch Neurol, 36:81, 1979, with permission.)

If the electrical square pulse causes the diaphragm of the acoustic transducer to move toward the patient’s ear, a propagating wave of increased air pressure, termed a compression click (also called a condensation click ) is produced. Reversing the polarity of the electrical square pulse that activates the transducer produces a rarefaction click . BAEPs to rarefaction and compression clicks may differ (most prominently in patients with a cochlear high-frequency hearing loss), and averaging the responses to the two click polarities together may produce a composite waveform with less diagnostic utility. Therefore, a single stimulus polarity should be used unless alternating polarities are necessary for canceling the electrical stimulus artifact or cochlear microphonic. Rarefaction clicks are generally preferable because they tend to yield BAEPs with better definition of the components; this may be because the initial cochlear movements produced by rarefaction clicks are in a direction that depolarizes the hair cells. In evaluating a patient’s BAEPs, the normative data used should have been acquired with the same stimulus polarity used to test the patient.

Recording

Recording electrodes typically are placed at the vertex (location Cz of the International 10–20 System) and at both ear lobes. (The ear lobes ipsilateral and contralateral to the stimulated ear are labeled Ai and Ac, respectively.) Electrodes at the mastoids (labeled Mi and Mc) may be substituted for the ear-lobe placements, although wave I tends to be smaller. Such placement, in combination with increased pickup of muscle noise, yields a poorer signal-to-noise ratio for wave I with mastoid leads than with ear-lobe leads. The ground electrode is often placed on the forehead, but its precise location is not critical. Metal cup or pellet electrodes may be used; needle electrodes should be avoided. Electrode impedance should be less than 5 kohm. Optimally, the same type of electrode should be used at all recording positions, and electrode impedance should be as consistent as possible across all recording electrodes, because mismatched electrode impedances can increase the amount of noise in the BAEP data.

BAEPs should be recorded between Cz and either Ai or Mi. A minimum of a two recording-channel system, with Cz–Ac or Cz–Mc in the second channel, has been recommended because this channel may aid in the identification of waves IV and V, which may be fused in the channel 1 waveform. An Ac–Ai or Mc–Mi channel may assist in the identification of wave I, and can be substituted in channel 2 when necessary, or can be recorded as a standard part of all tests if more than two recording channels are available.

The raw analog data are amplified by high input-impedance differential amplifiers with a common mode rejection ratio of at least 80 dB (10,000 : 1). A typical analog filter bandpass is 100 Hz or 150 Hz to 3,000 Hz (−3 dB points). The analog gain depends on the input window of the analog-to-digital converter; a value of approximately 100,000 is typical.

Data typically are digitized over an epoch duration or analysis time of approximately 10 msec. (The analysis time in some recording systems is actually 10.24 msec.) However, a longer analysis time of 15 msec may be required for recording pathologically delayed BAEPs, BAEPs to lowered stimulus intensities (as when recording a latency–intensity study), BAEPs in children, and BAEPs during intraoperative monitoring. The Nyquist criterion requires analog-to-digital conversion with a sampling rate of at least 6,000 Hz (2 × 3,000 Hz) in each channel to avoid aliasing, but higher sampling rates are required for accurate reproduction of the BAEP waveform and precise measurement of peak latencies. The analog-to-digital conversion should use at least 256 points per epoch; sampling of a 10.24-msec epoch at 256 time points corresponds to a sampling interval of 0.4 msec and a sampling rate of 25,000 Hz.

Far-field BAEPs are too small to be visible in unaveraged raw data, and so signal averaging is required. The improvement in the signal-to-noise ratio is proportional to the square root of the number of data epochs included in the average. Automatic artifact rejection is used to exclude sweeps with high-amplitude noise from the average. The number of epochs per trial is typically 2,000, although a larger number may be required if the signal-to-noise ratio is poor (usually reflecting a low-amplitude BAEP or noisy raw data). At least two separate averages should be recorded and superimposed to assess reproducibility of the BAEP waveforms. Latency replication to within 1 percent of the sweep time and amplitude replication to within 15 percent of the peak-to-peak amplitude have been recommended as standards for adequate reproducibility.

Waveform Identification and Measurement

When recording far-field potentials such as the BAEPs, the two electrodes connected to the inputs of a differential amplifier cannot be considered active and reference electrodes. The voltage distributions of the BAEPs extend over most, if not all, of the head, and no cephalic electrode can be considered to be truly inactive for all components. For example, wave V in the Cz–Ai BAEP waveform largely reflects positivity at the vertex, whereas wave I is derived from a negativity around the stimulated ear that is picked up by the Ai electrode. Thus, both input electrodes must be specified when describing a BAEP waveform.

The Cz–Ai BAEP typically is displayed so that positivity at the vertex relative to the stimulated ear is displayed as an upward deflection, and the upward-pointing peaks are labeled with Roman numerals according to the convention established by Jewett and Williston (see Fig. 24-4 ; Fig. 24-6 ). The downward-pointing peaks are labeled with the suffix N according to the peak that they follow; for example, downward peak IN follows upward wave I. The downward deflection following wave V, which has also been labeled the slow negativity (SN), is typically wider than the positive components and the earlier negative peaks.

Brainstem auditory evoked potentials recorded simultaneously from three different recording electrode linkages following monaural stimulation. The vertical dashed lines indicate the peak latencies of waves IV and V in the Cz–Ai waveforms. Note the decreased wave IV latency and the increased wave V latency in the Cz–Ac waveforms.

Recognition and identification of the components in BAEP waveforms obtained with standard recording techniques will now be described. Modifications in the recording paradigm that can be used to enhance specific BAEP components are discussed later in this chapter.

The BAEP waveform typically begins with an electrical stimulus artifact that is synchronous with stimulus production at the transducer. Wave I is the first major upgoing peak of the Cz–Ai BAEP. It appears as an upgoing peak of similar amplitude in the Ac–Ai waveform and is markedly attenuated or absent in the Cz–Ac waveform (see Fig. 24-6 ). The cochlear microphonic may be visible as a separate peak preceding wave I, especially if the stimulus artifact is small. Its scalp distribution is similar to that of wave I. They may be distinguished by reversing the stimulus polarity, which will reverse the polarity of the cochlear microphonic; wave I may show a latency shift, but will not reverse polarity.

A bifid wave I is occasionally present and represents contributions to wave I from different portions of the cochlea. The earlier of the two peaks, which reflects activation of the base of the cochlea, corresponds to the single wave I that is typically present in the Cz–Ai waveform. Reversal of stimulus polarity can be used to distinguish a bifid wave I from a cochlear microphonic followed by (a single) wave I.

In contrast to wave I, wave IN is present at substantial amplitude in the Cz–Ac channel (see Fig. 24-6 ). This downgoing deflection is usually the earliest BAEP component in that waveform.

Wave II is typically the first major upward deflection in the Cz–Ac waveform because wave I is markedly attenuated or absent there. When present, wave II is usually of similar amplitude in the Cz–Ai and Cz–Ac channels (see Fig. 24-6 ). However, wave II may be small and difficult to identify in some normal subjects.

A substantial wave III is usually present in both the Cz–Ai and Ac–Ai channels. Wave III in the Cz–Ac waveform is usually substantially smaller than that in the Cz–Ai waveform (see Fig. 24-6 ). This difference helps to distinguish it from wave II, whose amplitude is little changed by the change in the ear electrode. The peak latency of wave III decreases slightly, whereas that of wave II increases slightly when the inverting amplifier input is changed from Ai to Ac; thus, the Cz–Ai waveform tends to give better separation of waves II and III than does the Cz–Ac waveform. A bifid wave III occasionally is observed as a normal variant ( Fig. 24-7 ); the wave III latency in such waveforms can be scored as midway between the peak latencies of the two subcomponents. Rarely, wave III may be poorly formed or absent in a patient with a clear wave V and a normal I–V interpeak interval; this finding is best interpreted as a normal variant waveform.

Brainstem auditory evoked potentials recorded from a normal subject following stimulation with compression (C) and rarefaction (R) clicks. Prominent differences in wave shape are evident between the two stimulus polarities. The latency of wave VI and the relative amplitudes of waves IV and V are affected markedly by the click polarity. The lowest point in the waveform after wave V precedes wave VI with compression clicks and follows wave VI with rarefaction clicks. A bifid wave III is present in the Cz–Ai waveform elicited by compression clicks.

(By permission of the Mayo Foundation.)

Waves IV and V are often fused into a IV/V complex whose morphology varies from one subject to another, and may differ between the two ears in the same person ( Fig. 24-8 ). The IV/V complex is often the most prominent component in the BAEP waveform. It usually is followed by a large negative deflection that lasts several milliseconds and brings the waveform to a point below the prestimulus baseline. Occasionally, the most negative point in the waveform follows wave VI (see Fig. 24-7 ), which could lead to misinterpretation of wave VI as an abnormally delayed wave V. The identity of wave V can be clarified by changes in recording montage or click polarity (see Figs. 24-6 and 24-7 ) or by reducing the stimulus intensity and/or increasing the stimulus rate to attenuate wave VI relative to wave V. In distinguishing between a totally fused IV/V complex and a single wave IV or V, Epstein notes that the former has a “base” that is greater than 1.5 msec in duration, whereas the width of a single wave is less than 1.5 msec.

Various IV/V complex morphologies in Cz–Ai waveforms recorded in normal subjects.

(From Chiappa K, Gladstone KJ, Young RR: Brain stem auditory evoked responses. Studies of waveform variations in 50 normal human subjects. Arch Neurol, 36:81, 1979, with permission.)

When waves IV and V overlap in the Cz–Ai waveform, the wave V latency measurement used for BAEP interpretation should be taken from the second subcomponent of the IV/V complex, even if this is not the highest peak (in contrast to the amplitude measurement used to calculate the IV/V:I amplitude ratio, which is taken from the highest point in the complex). Measurement of the peak latency of wave V may be inaccurate if V appears only as an inflection on the falling edge of wave IV (see Fig. 24-8 ) and it may be impossible if they are fused smoothly. Two approaches may be used in such cases. The first involves measurement of wave V latency in a Cz–Ac recording channel. The overlapping peaks are separated more clearly there because the latency of wave IV is typically earlier, and that of wave V is later, than in the Cz–Ai waveform (see Fig. 24-6 ). However, because of these latency shifts, wave V latency values measured in a Cz–Ac waveform should be compared with normative data in which the latency of wave V was also measured in a Cz–Ac recording. The other approach is to reduce the stimulus intensity to attenuate wave IV relative to wave V and permit accurate measurement of the peak latency of wave V. That latency value cannot be compared with normative data obtained at a higher stimulus intensity, but the I–V interpeak interval can be evaluated because it is affected minimally by changes in stimulus intensity.

It is important to distinguish wave V from wave IV. If wave V were delayed abnormally, but an earlier and larger wave IV (which dominated the IV/V complex) were mistaken for wave V, the BAEP abnormality might be missed. If the latency of an apparent wave V is abnormally short, efforts should be made to determine whether this peak is, in fact, a dominant wave IV. Lesions that affect wave V almost always also affect wave IV, but rarely wave IV may be unaltered ( Fig. 24-9 ).

Brainstem auditory evoked potentials (BAEPS) to left ear stimulation recorded (Cz–Ai) during surgery for a basilar artery aneurysm. The aneurysm ruptured and the basilar artery was clipped transiently to control the bleeding. The patient suffered a brainstem infarct. A , Clear waves I through VI were present in these BAEPs recorded just before the aneurysm ruptured. B , BAEPs recorded after the clip was removed show a loss of waves V and VI. Waves I through IV were unaffected.

(Modified from Legatt AD, Arezzo JC, Vaughan HG, Jr: The anatomic and physiologic bases of brain stem auditory evoked potentials. Neurol Clin, 6:681, 1988, with permission.)

Clinical interpretation of BAEPs is based predominantly on the latencies of waves I, III, and V. Once these peaks have been identified and their latencies measured, the I–III, III–V, and I–V interpeak intervals are calculated. The latency of wave I has also been labeled the peripheral transmission time (PTT) and the I–V interpeak interval has been called the central transmission time (CTT). Differences of component latencies and interpeak intervals between stimulation of the right and left ears are also calculated.

The amplitudes of wave I and the IV/V complex are measured, each with respect to the most negative point that follows it in the waveform (I to IN and IV/V to VN), and their ratio is calculated. An excessively small IV/V:I amplitude ratio can identify as abnormal some BAEP waveforms in which all component latencies and interpeak intervals are normal ( Fig. 24-10 ). It sometimes has been called the V:I amplitude ratio. However, most studies establishing the value of this quantity measured the amplitude from the highest peak of the IV/V complex to VN, not from the wave V peak to VN. Measuring the latter may give an abnormally small ratio in normal waveforms in which the peak of wave IV is much higher than that of wave V.

Brainstem auditory evoked potential (Cz–Ai) in a 27-year-old woman with probable multiple sclerosis. The IV/V:I amplitude ratio is 0.28; all absolute latencies and interpeak intervals are normal. The stimulus intensity was 65 dB nHL.

Patient Relaxation and Sedation

The amplifier bandpass used for BAEP recordings filters out all of the delta, theta, alpha, and beta bands of the electroencephalogram (EEG), and the biologically derived noise in the recordings is derived predominantly from muscle activity. Therefore, patient relaxation during the recording session is essential to obtain “clean” waveforms with a good signal-to-noise ratio. Patients usually are tested while lying comfortably so that their neck musculature is relaxed. Patients should be requested to let their mouth hang open if the muscles of mastication are tensed. They are encouraged to sleep during testing because this aids relaxation and will not alter the BAEPs.

If the patient cannot relax sufficiently, sedation can be induced with agents such as chloral hydrate, a short-acting barbiturate, or a benzodiazepine; these have little or no effect on BAEPs in the usual sedative doses.

Reducing the Stimulus Artifact

The transient electrical current in the transducer that generates the acoustic stimulus produces a transient electromagnetic field, which in turn induces a voltage in the patient and in the recording leads. This voltage creates an electrical stimulus artifact that, if large and prolonged, may overlap with wave I and impair the identification and measurement of that component. Using shielded headphones and headphones with piezoelectric transducers instead of voice coil transducers can reduce this artifact. Transducers that are connected to an ear insert by flexible plastic tubing several centimeters in length may also be used to mitigate this problem. The BAEPs, including wave I, are delayed by the time required for the acoustic stimulus to propagate through the plastic tube, but the electrical stimulus artifact remains simultaneous with transducer activation; the increased temporal separation between them permits greater decay of the electrical artifact before wave I. The greater distance between the transducer and the earlobe or mastoid recording site also serves to reduce the amplitude of the electrical stimulus artifact. The delay introduced by the plastic tube must be considered when one interprets BAEP latencies; passage through the tube may also change the acoustic properties of the stimulus. Ideally, the normative data used for BAEP interpretation should have been acquired with the same techniques that are used to test the patients. When ear inserts are used, they may be covered with metal foil to serve as near-field recording electrodes for wave I, thereby yielding a larger wave I.

Responses to compression and rarefaction clicks may be averaged together to reduce the electrical stimulus artifact by cancellation. Most evoked potential recording systems have an option for alternating the click polarity during stimulus delivery. This option should be avoided if possible during diagnostic testing because the BAEPs elicited by the two click polarities may differ. Stimulus artifact is usually more of a problem in the operating room environment, and alternating click polarity is often necessary during intraoperative BAEP monitoring. In this setting, the BAEPs are being compared with signals recorded earlier in the same patient with the identical stimulus paradigm, so the admixture of responses to the two stimulus polarities is less of a problem.

Improving the Resolution of Specific Components

Wave I may be small and difficult to record in some patients, especially if hearing loss is present. Several techniques can be used to obtain a clearer wave I. Because wave I is a near-field potential, relatively small movements of the Ai/Mi recording electrode can have a substantial effect on its amplitude. Thus, alternative electrode positions around the stimulated ear can be used. An electrode within the external auditory canal yields an even larger wave I, and may take the form of a metal foil covering on an ear insert or a spring-leaf electrode that makes contact with the wall of the canal.

Although wave I appears predominantly because of the presence of a near-field negativity at the Ai electrode, the horizontal orientation of its dipole projects a small positivity to the contralateral ear. Accordingly, an Ac–Ai recording channel can yield a somewhat larger and clearer wave I than that in the standard Cz–Ai recording.

Modifications in stimulus parameters are also useful in obtaining a clearer wave I. Alternating stimulus polarity can be useful by attenuating a large stimulus artifact that is obscuring wave I or by helping to differentiate wave I from the cochlear microphonic. A reduction in the stimulus repetition rate may yield a clearer wave I. Increasing the stimulus intensity is particularly helpful in improving the clarity of wave I and may be used if that peak is not clearly identifiable at standard intensities in the presence of hearing loss. One caveat is that in patients with a high-frequency hearing loss of cochlear origin, this maneuver yields interpeak intervals that are shorter than those of normal subjects. This difference in interpeak intervals probably reflects contributions to wave I from different portions of the cochlea. At normal intensities, the earliest peak, which reflects activation of the base of the cochlea, predominates. At higher intensities, a somewhat longer-latency component becomes increasingly prominent. If the earlier component is missing because of high-frequency hearing loss, and if stimulus intensity is increased, the wave I that appears may predominantly reflect the longer-latency contribution; the I–III and I–V interpeak intervals are thus shorter than those that would have been measured from the usual wave I. Measurement of the PTT from this longer-latency subcomponent would decrease the sensitivity of the test for recognition of prolonged I–III or I–V interpeak intervals.

Wave V is often fused with wave IV into a IV/V complex in the Cz–Ai BAEP waveform. A Cz–Ac recording channel helps to identify wave V by increasing the separation between the peaks of these two components; the latency of wave IV is shorter and that of wave V is longer than in the Cz–Ai recording (see Fig. 24-6 ). Because of this latency shift, the latency of wave V in a patient’s Cz–Ac waveform should be compared with normal values derived from Cz–Ac recordings in control subjects.

Modifications of the stimulus parameters can also be used to identify wave V if it is unclear when standard recording techniques are used. Wave V is the BAEP component most resistant to the effects of decreasing stimulus intensity ( Fig. 24-11 ) or increasing stimulus rate. If either of these stimulus modifications is performed progressively until only one component remains, that peak can be identified as wave V and then traced back through the series of waveforms to identify wave V in the BAEP recorded with the standard stimulus. Occasionally, wave V may be present following stimulation with one click polarity but not the other ( Fig. 24-12 ). Therefore, recording a BAEP with the opposite stimulus polarity may be useful if wave V is not identifiable with the standard laboratory protocol.

Brainstem auditory evoked potentials (BAEPs) recorded at progressively lower stimulus intensities are shown on the left. Wave V latencies (arrows) are measured and then plotted as a function of stimulus intensity to give the latency–intensity curve on the right. This 35-year-old woman with dizziness and tinnitus had normal BAEPs and normal magnetic resonance imaging findings.

Brainstem auditory evoked potentials elicited by rarefaction (R) and compression (C) clicks of several different intensities. Wave V is absent following left ear (AS) stimulation with 70 dB SL rarefaction clicks but appears when the stimulus intensity is decreased to 55 dB SL or when stimulus polarity is reversed. A clear wave V is present following right ear (AD) stimulation with 70 dB SL clicks of either polarity. The calibration bars are 0.25 μV and 1.0 msec.

(From Emerson RG, Brooks EB, Parker SW et al: Effects of click polarity on brainstem auditory evoked potentials in normal subjects and patients: unexpected sensitivity of wave V. Ann N Y Acad Sci, 388:710, 1982, with permission.)

Stimulation at Several Intensities

In a patient with a conductive hearing loss, the stimulus intensity reaching the cochlea is less than that delivered to the external ear, and an abnormal BAEP with a delayed or absent wave I may result. If the stimulus intensity is increased to compensate for the conductive hearing loss, and no coexisting sensorineural hearing loss is present, a normal BAEP will be recorded. In contrast, BAEPs that are delayed as a result of abnormally slowed neural conduction do not normalize when the stimulus intensity is increased ( Fig. 24-13 ). Thus, increasing the stimulus intensity can help to differentiate peripheral from neural abnormalities, especially when wave I is not clear. The degree of hearing loss can be estimated by the elevation of the subjective auditory click threshold; increasing the stimulus intensity to compensate for this elevation is thus equivalent to stimulating at a specific intensity above that threshold (e.g., at 60 to 65 dB SL rather than at 60 to 65 dB HL). The normative data to which such recordings are compared should also have been recorded at a specific intensity in dB SL, rather than dB HL.

Brainstem auditory evoked potentials (BAEPs) elicited by two different stimulus intensities in two patients and recorded in Cz–Ai montage. A , Left ear stimulation at 70 dB nHL elicits an abnormally delayed wave V in a 36-year-old woman with a peripheral hearing loss in the left ear. Wave I is not visible. B , When the stimulus intensity is increased to 85 dB nHL, wave I becomes identifiable and the latency of wave V is decreased markedly. Interpeak intervals are normal. C , Left ear stimulation at 65 dB nHL in a 14-year-old boy with a fourth ventricular tumor elicits clear BAEPs with a normal wave I latency and an abnormally delayed wave V. The I–III and I–V interpeak intervals both are prolonged abnormally. D , An increase in the stimulus intensity to 85 dB nHL causes a slight decrease in all component latencies. Wave V remains abnormally delayed, and the I–III and I–V interpeak intervals remain abnormally prolonged.

If each ear is stimulated at several different intensities, and the latency of wave V is graphed as a function of stimulus intensity, a latency–intensity curve is produced (see Fig. 24-11 ). Examination of latency–intensity curves may help to classify a patient’s hearing loss. A shift of the curve to a higher intensity level without a change in its shape suggests conductive hearing loss, whereas a change in the shape of the curve with an increased slope suggests sensorineural hearing loss. Latency–intensity curves may also reveal abnormalities that are not demonstrated by BAEP recordings at the standard, relatively high stimulus intensity typically used in BAEP studies performed for neurologic diagnosis.

Rapid Stimulation

A stimulus rate of approximately 10 Hz is used for routine clinical testing; this is because some of the BAEP components become attenuated and less clearly defined and the interpeak intervals lengthen as the rate is increased substantially above this. Measurement of the BAEP threshold is based solely on the presence or absence of wave V because it is the last BAEP component to disappear as the stimulus intensity is reduced. Because wave V is relatively resistant to the effects of rapid stimulation, recordings made solely for threshold measurement can be accomplished more rapidly by increasing the stimulus rate to 50 to 70 Hz. However, rapid stimulation can make BAEPs undetectable, especially in premature infants. Thus, infants who appear to have a hearing loss on BAEP screening using rapid stimulation should be retested using a slower stimulation rate.

When stimuli are delivered at a rate of about 10 Hz, the neural elements generating the BAEPs have approximately 100 msec to recover after responding to one stimulus before they must respond to the next. It has been speculated that, in some pathologic states, action potential propagation or synaptic transmission occurs normally with recovery times of this magnitude but is delayed when recovery times are shorter. If this were the case, more rapid stimulation would demonstrate BAEP abnormalities in some patients with normal BAEPs to the standard stimuli, thus increasing the sensitivity of the test. Rapid stimulation has been reported to increase the test sensitivity of BAEPs in patients with neurologic abnormalities in some, but not all, studies.

Alternative Auditory Stimuli

The standard BAEP stimulus is a “broad-band” click produced when an electrical square pulse is delivered to the headphone or other electromechanical transducer. It is generated predominantly by the region of the cochlea responding to 2,000- to 4,000-Hz sounds, although wave V may also receive contributions from lower-frequency regions of the cochlea. BAEPs have also been recorded following stimulation with brief tone pips, in an effort to probe specific parts of the cochlea. This method can be used to determine thresholds at different frequencies for BAEP audiometry. Tone pips most often are generated with stimuli consisting of brief bursts of sine waves. The burst cannot be stopped and started abruptly because an audible “click” containing many frequencies would be produced. Instead, the sine wave stimulus is amplitude-modulated with a rise-time, plateau, and fall-time to reduce (although not eliminate) the energy content of the stimulus at other frequencies. A filtered click, which is obtained by passing a broad-band click through a bandpass filter, has also been used as a frequency-specific stimulus.

Another technique that can be used to obtain frequency-specific information from BAEPs is acoustic masking. In one approach, the broad-band clicks used to elicit the BAEPs are superimposed on white noise that has been highpass-filtered by using different cut-off frequencies in different runs. Each BAEP waveform is generated predominantly by the unmasked region of the cochlea and represents a response to frequencies lower than the cut-off frequency used during that run. Subtraction of one such response from another yields a “derived” response that estimates the response to the frequency band between the cut-off frequencies of the two runs ( Fig. 24-14 ). The subtraction process yields waveforms with relatively poor signal-to-noise ratios, however.

Derivation of frequency-specific brainstem auditory evoked potentials (BAEPs) with high-pass noise masking. Alternating-polarity, 170-μsec-duration clicks at an intensity of 60 dB SL were delivered at a rate of 13 Hz. The noise, which was delivered to the same ear, was highpass-filtered with cascaded filters to produce a filter function with a slope of 96 dB per octave. The BAEPs elicited by the clicks in the presence of the masking noise are shown in the left column; the number at the left of each waveform indicates the cut-off frequency of the noise filter. The uppermost waveform (marked “∞”) is the conventional BAEP, without masking noise. The derived responses, obtained by calculating the differences between pairs of adjacent BAEPs from the left column, are shown in the right column. CF, central frequency assigned to each derived waveform, based on the characteristics of the noise filter.

(From Don M, Eggermont JJ: Analysis of the click-evoked brainstem potentials in man using high-pass noise masking. J Acoust Soc Am, 63:1084, 1978, with permission.)

Frequency-specific stimuli and frequency-specific masking can be combined by embedding tone pips in continuous notched noise. The latter is white noise that has been notch-filtered to remove the basic frequency of the tone pip. Shaping a pure tone into a pip with an onset and an offset introduces power at other frequencies into its frequency spectrum, which would impair the frequency specificity of the test, but the notched noise masks the responses to frequencies other than the basic frequency of the tone pip. BAEP audiograms produced with such stimuli are similar to behavioral audiograms in the same subject. Wave V is broader in the frequency-specific BAEPs elicited by the lower frequencies; when these are recorded, reducing the low-cut (high-pass) analog filter in the evoked potential averager to 30 Hz may yield a clearer wave V and more reliable results.

Stimulation with relatively prolonged, low-frequency tone bursts (e.g., 200- to 500-Hz tone bursts lasting 10 to 15 msec each) produces an evoked potential that contains oscillatory components at the frequency of the tone ( Fig. 24-15 ). The frequency-following response and the BAEPs do not appear to have the same neural generators. Whereas the BAEPs reflect activity originating in the base of the cochlea, the frequency-following response predominantly reflects activity originating in lower-frequency regions of the cochlea. However, the clinical utility of frequency-following responses for assessing hearing in the lower frequencies has been limited by the technical difficulties associated with recording them and by their relatively high thresholds.

Averaged frequency-following response to a 500-Hz tone burst, recorded between the vertex and linked ears with amplifier filter bandpass of ( A ) 8 Hz to 10,000 Hz and ( B ) 200 Hz to 1,000 Hz. The acoustic stimulus, recorded by a microphone at the subject’s earpiece, is shown at the top. Note the latency shifts between the onset and the offset of the stimulus and the response.

(From Marsh JT, Brown WS, Smith JC: Far-field recorded frequency-following responses: correlates of low pitch auditory perception in humans. Electroencephalogr Clin Neurophysiol, 38:113, 1975, with permission.)

BAEPs may also be elicited by bone-conducted stimuli. This is most useful in assessing patients who may have conductive hearing losses, such as neonates in whom BAEPs performed with air-conducted stimuli are suggestive of a hearing loss.

BAEPs to Electrical Stimuli

BAEPs can also be recorded following electrical stimulation of eighth nerve fibers through the electrodes of a cochlear prosthesis. This can be used to assess the proximity of these electrodes to the spiral ganglion during implantation and the adequacy of eighth nerve stimulation during programming of the processor, though recording of the evoked eighth nerve compound action potential through a different set of electrodes may prove to be a more useful tool for the latter application. Recording of BAEPs to electrical stimulation at the promontorium has proven to be a poor predictor of the success of cochlear implantation in children. However, recording of BAEPs to electrical stimulation via an intracochlear electrode has been shown to correlate well with auditory outcomes, and may prove to be useful in guiding therapy in young children with questionable auditory nerve integrity.

Magnetic Recording of BAEPs

Since the BAEP generators are far from the surface of the head, it is difficult to record the magnetic fields corresponding to the BAEPs, and such recordings are not practical for clinical use. However, prolonged averaging with a large number of epochs per average can yield magnetic signals within the latency range of the BAEPs. Studies of these signals may produce evidence about the generators of the BAEPs. The most consistent peaks of the magnetic BAEPs correspond in latency to waves IN and V of the electrical BAEPs that are elicited by the same acoustic stimulus.

Stimulus Polarity

Responses to rarefaction and compression clicks delivered to the same ear may differ (see Fig. 24-7 ). Component latencies following rarefaction clicks are usually, although not always, shorter than those following compression clicks. The BAEP latency differences between the two stimulus polarities tend to be greatest in patients with cochlear high-frequency hearing loss. BAEP peaks tend to be clearer with rarefaction clicks because of fusion of adjacent components when compression clicks are used, although again there are exceptions. The presence of wave V following one click polarity, but not the opposite, has been reported as an uncommon finding in patients referred for BAEP studies (see Fig. 24-12 ); the significance of this finding is unclear.

Stimulus Intensity

As the stimulus intensity is decreased, the latencies of all BAEP components increase (see Fig. 24-11 ). The increase is caused predominantly by a latency shift of wave I; the interpeak intervals are relatively constant until the stimulus intensity nears threshold. Component amplitudes decrease as the stimulus intensity is lowered, but with different patterns. Wave I shows the most rapid attenuation as the stimulus intensity is lowered, and it usually is lost before waves III and V. Wave V is attenuated to a lesser degree at lower stimulus intensities and is the last peak to disappear; its disappearance defines the BAEP threshold. At lower intensities, the IV/V:I amplitude ratio is increased because of the greater degree of attenuation of wave I.

Stimulus Rate

Increasing the stimulus rate increases both the absolute latencies of the BAEP components and the interpeak intervals. As the stimulus rate is increased above approximately 10 per sec, component amplitudes decrease and the peaks tend to become less well defined. Wave V is most resistant to these effects. Thus, a stimulation rate of approximately 10 Hz is preferable for routine clinical testing, but more rapid rates may be used to facilitate recordings to measure the wave V threshold.