Normal Acoustic Reflex  Amplitude Growth and the Influence  of  Cochlear Hearing Loss 

Juliette Womersley B.Sc(Log) (Cape Town) 
Lucille Dickens B(Log) (Pretoria) 

Department  of  Logopaedics, 
University  of  Cape Town 

ABSTRACT 
The  nature of  acoustic reflex  amplitude  (ARA)  growth  at IKHz  and  2KHz  was investigated  in normal  hearing and  cochlear  disordered 
subjects subdivided  into Meniere's  Disease and  heterogeneous  pathology  groups. Statistical  and  graphical  analyses revealed  significant 
inter-group  variation in ARA growth  rate. The  normal  and  Meniere's  groups behaved  similarly,  while the heterogeneous  group demonstrat-
ed  a faster  ARA growth  rate. The  differential  sensitivity  of  various measurement methods  was examined.  Explanations  were put forward 
to account for  variability  in ARA data  amongst  cochlear  disordered  subjects. It  was concluded  that  the clinical  sensitivity  of  ARA measure-
ment was questionable. 

OPSOMMING 
Die toename van die  akoestiese  refleks  amplitude  (ARA)  by IKHz  en 2KHz  is in normaalhorendes  en proejpersone met kogliere  letsels 
ondersoek.  Laasgenoemde  is in Meniere  se siekte  en groepe met 'n  heterogene  patologie  onderverdeel.  'n  Betekenisvolle  variasie tussen 
groepe m. b. t. die  ARA-groeitempo  is d.  m. v. statistiese  en graflese  analises bevind.  Ooreenkomste  tussen die  normale  en die  Meniere  se 
groepe is aangetref  terwyl  daar  'n  toename in die  ARA-groeitempo  van die  heterogene  groep was. Verder  is die  sensitiwiteitsverskil  van 
verskeie  metingsmetodes  ondersoek.  Ten  einde  die  veranderlikheid  in ARA-data~tussen  proefpersone  met kogliere  letsels  te verantwoord, 
is verskeie  verklarings  gebied.  Die gevolgtrekking  is gemaak  dat  die  kliniese  sensitiwiteit  van die  ARA-meting  bevraagteken  is. 

The role of  acoustic reflex  measurement in determining the nature 
of  sensori-neural hearing loss has been well established. Tradition-
ally the acoustic reflex  threshold test, a static measure, and the reflex 
decay test, a dynamic temporal measure, are employed for  this pur-
pose (Jerger, 1975). Measurement of  other dynamic properties such 
as amplitude and latency has not yet achieved the same clinical sta-
tus. Borg (1976) however, stated that such properties may contrib-
ute significantly  to clinical diagnosis in impedance audiometry if 
they are proven to be pathology sensitive. 

Acoustic reflex  amplitude (ARA) is defined  as the change in acoustic 
impedance between quiescent and reflexive  states. ARA is intensi-
ty dependent: for  pure tone stimulation it has a dynamic range of 
20-30 dB, representing the intensity range over which the reflex 
shows an amplitude growth (Wilson and McBride, 1978). The na-
ture of  ARA growth in normal subjects has been variably reported 
in the literature. Uliel (1980) and Clemis and Sarno (1980) report-
ed a linear function  while several other investigators have report-
ed a curvilinear function  (Dallos, 1964; Sprague, Wiley and Block, 
1981; Wilson and McBride, 1978). Inter-study variability in the 
description of  normal ARA growth could have resulted from  a non-
standardised basis of  amplitude measurement; sensation level (SL) 
versus hearing level (HL) measurement methods. Sprague et al. 
(1981) employed both SL and HL in their data analysis and demon-
strated an ARA configuration  difference  accordingly. 

This lack of  agreement between researchers is also evident in the 
literature on ARA in the cochlear hearing loss population. Uliel 
(1980) investigated an ascending-descending ARA function  in nor-
mal and cochlear disordered subjects, by HL measurement. The 
growth pattern characteristic of  cochlear disordered subjects without 
concomitant loudness recruitment was similar to that of  the nor-
mal group. In contrast, cochlear disordered subjects with concomi-
tant loudness recruitment demonstrated a faster  than normal 

© SASHA 1985 

amplitude growth. An increased growth rate was also repeatedly 
observed by Clemis and Sarno (1980) in Meniere's Disease sub-
jects, at IKHz and 2KHz. 

In contrast with these findings,  Petersen and Liden (1972) and Bee-
die and Harford  (1973) reported a slower growth rate in pathologi-
cal ears of  variable cochlear etiology, than in normal ears. Both 
Uliel (1980) and Beedle and Harford  (1973) specifically  investigated 
ears with loudness recruitment and thus the discrepancy in their 
respective findings  is particularly notable. A further  confusion  is 
that Jerger and Hayes (1983) reported an abnormally slow growth 
rate to be characteristic of  a retrocochlear group. These discrepan-
cies indicate that the influence  of  cochlear pathology on ARA has 
not been unequivocally established. Furthermore, since Uliel (1980) 
did not find  an abnormal growth rate to be characteristic of  alljcoch-
lear disordered subjects, it is logical to suspect that the influence 
of  cochlear disorder on ARA might vary as a function  of  patholo-
gy. The need for  further  research on ARA in the cochlear popula-
tion is clear. However, results cannot be classified  validly as 
"faster"  or "slower" than normal, until "normal" growth has been 
unequivocally defined.  Further investigation in to the shape of  the 
ARA growth function  in normal subjects is therefore  also necessary. 

METHODOLOGY 

AIMS 

The amplitude growth of  the acoustic reflex  was investigated at 
IKHz and 2KHz, in normal hearing and cochlear disordered sub-
jects with the aim of 

1. describing the configuration  of  the ARA growth function  in nor-
mal hearing subjects for  various measurement methods, name-
ly: HL, SL, Δ HL, and Δ SL; 

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Normal Acoustic Reflex  Amplitude Growth and the Influence  of  Cochlear Hearing Loss 59 

2. investigating the influence  of  cochlear dysfunction  on the ARA 
growth function.  Specifically,  to investigate ARA in a group 
of  Meniere's Disease subjects, and a group of  subjects with vari-
able cochlear etiology, excluding Meniere's Disease; 

3. examining the variable sensitivity of  different  measurement 
methods in distinguishing between the normal and pathological 
subject groups. 

SUBJECTS 

The subject sample in this investigation comprised three groups: 
a control group (A) of  16 normal hearing subjects (mean age 24 
years; 38 test ears), an experimental group (B) of  six subjects with 
Meniere's Disease (mean age 38 years; six test ears), and a further 
experimental group (C) of  four  subjects with variable cochlear etiol-
ogy, excluding Meniere's Disease, (mean age 40 years, six test 
ears). This age limit of  20-50 years was imposed since ARA data 
has been shown to be relatively stable across this age range (Os-
terhammel and Osterhammel, 1979). Both sexes were represented. 

Subjects were selected on the basis of  case-history findings  and au-
diologic results obtained by the author from  a battery comprising 
pure tone air and bone conduction audiometry, impedance audi-
ometry, the Metz Recruitment and Rosenburg Tone Decay tests. 
Table 1 summarises the specific  criteria according to which sub-
jects were differentiated  into groups A, Β and C. 

EQUIPMENT 

A Madsen Electro-Acoustic Impedance Audiometer (model Z073A) 
which delivered a 220 Hz probe tone was used. This was calibrat-
ed according to standards set out in IEC publication 318. A Hewlett 
Packard Moseley X-Y Plotter (model 7035A) was connected to the 
impedance meter. The X-axis was activated by depression of  the 
pure tone stimulus interrupter switch on the impedance meter, result-
ing in a time-locked 2 second excursion. Presentation of  the 250 
msec stimulus followed  automatically but not immediately, allow-
ing a baseline to be plotted before  reflex  elicitation. 

The impedance meter was set at sensitivity 2 and the range of  the 
Y-axis was calibrated such that 0.05 cc = 0.04 mv = 1 mm on 
the chart paper. An acoustic reflex  was recorded as a relative deflec-
tion from  the baseline, representing an increase in input impedance 
(refer  to Figure 1). 

EXPERIMENTAL PROCEDURE 

Tympanometry was performed  on each test ear prior to experimental 
testing in order to determine the point of  maximum compliance. 
The acoustic reflex  testing was conducted by the contralateral stimu-
lus mode at lKHz and 2KHz. The starting point for  stimulus in-
tensity was subject specific:  testing began at reflex  threshold and 

Table 1 Summary of  specific  criteria for  subject selection and grouping 

GROUP A GROUP Β GROUP C 

Detailed case-history Negative history of  hearing 
difficulty,  ear pathology, 
otologic surgery, noise 
exposure and ototoxic drug 
intake. 

Positive history of  cochlear 
sensori neural hearing loss, 
negative history of  middle ear 
pathology and surgery, noise 
exposure, acoustic trauma, 
and ototoxic drug intake. 
Positive history of  Meniere's 
Disease and associated 
symptomatology, confirmed 
by an E.N.T. specialist. 

Positive history of  cochlear 
sensori-neural hearing loss, 
negative history of  middle 
ear pathology and otologic 
surgery and meniere's Disease. 

Hearing thresholds No poorer than 25 dB. No 
air-bone gap. 

Between 25-75 dB at speech 
frequencies.  No air-bone gap. 

Between 25-75 dB at speech 
frequencies.  No air-bone gap. 

Tympanometry Type-A 
tympanogram 
to rule out the 
presence of  middle ear 
disorders. 

Type-A 
tympanogram 
to rule out the 
presence of  middle ear 
disorders. 

Type-A 
tympanogram 
to rule out the 
presence of  middle ear 
disorders. 

Static Compliance 0.55cc-1.5cc. ; 0.5cc-1.55cc. 0.5cc-1.5cc. 

Reflex  Thresholds Between 70-100 
dB at all frequencies. 

Between 70-100 
dB at lKHz and 2KHz, 
contralateral^. 

Between 70-100 
dB at lKHz and 2KHz, 
contralaterally. 

Supra-threshold 
dynamic range 

Minimum of  25 
dBHL to allow for  sufficient 
ARA growth. 

Minimum of  25 
dBHL to allow for  sufficient 
ARA growth. 

Minimum of  25 
dBHL to allow for  sufficient 
ARA growth. 

Metz Test Negative. Positive: ARSL < 60 dB. ARSL < 60 dB. 

Tone Decay Test — Negative. Negative. 

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60 Juliette Womersley and Lucille Dickens 

ν 
Ό 
D 
"5. ε, < 

Φ 
CC 

u> 
3 
Ο 
o < 

mV 
0.04 mV 
= 1 mm 

2 sec. excursion 

Reflex 
Amplitude 

Figure 1 A sample reflex  response at 95 dBHL, illustrating 
the configuration  of  reflex  amplitude, 
a = interrupter switch depression: the distance 
between a and b represents the baseline before 
reflex  elecitation. 

proceeded in 5 dB increments up to 125 dBHL. In this manner a 
series of  graphical figures  (refer  to Figure 1) were obtained 
representing reflex  amplitude at consecutive stimulus levels, for 
each test ear at both frequencies. 

ANALYSIS OF RESULTS 

The graphical figures  represented the raw data. The amplitude of 
each reflex  was established by calculating the millimetre measure-
ment from  the lowest point of  the positive deflection  to the highest 
point representing the maximal increase in input impedance. Mil-
limetre measurements were converted to mV's according to the scale 
— 1 mm = 0.04 mV. mV scores used in data analysis were res-
tricted to those at hearing levels (HL) and sensation levels (SL) at 
which a reflex  response was common to all test ears. Data were 
also tabulated separately for  those normal subjects who demonstrated 
the broadest dynamic range of  amplitude growth, thus forming  a 
subgroup of  the normal sample. 

The following  analyses were performed: 

1. GRAPHICAL ANALYSIS 
Mean ARA functions  for  the three subject groups were graphi-
cally displayed with the aim of  examining the influence  of  sub-
ject group and measurement method variables on the 
configuration  of  these functions.  Data for  the subgroup of  nor-
mal subjects was graphically displayed so as to examine the ef-
fect  of  dynamic range on function  configuration. 

2 . SLOPE INDEX MEASUREMENT 
Slope index values were calculated for  each graphical figure, 
based either on the whole HL or SL stimulus range (100-125 
dBHL or 0-25 dBSL) or based only on the final  two HL or SL 
increments (120-125 dBHL or 20-25 dBSL); thus observed 
differences  in overall or 'tail-end' function  configurations  could 
be quantified. 

' 3 . STATISTICAL ANALYSIS 

The two-way analysis of  variance statistic, with repeated meas-
ures on Β (2-ANOVA-RB), was used to establish whether a sig-
nificant  interaction existed between subject group (variable A) 
and stimulus level (variable B). The simple main effects  (SME) 
and Tukey's honestly significant  difference  (HSD) statistics were 
used to quantify  further  the variation in ARA between subject 
groups at specific  stimulus levels. 

All HL and SL data at lKHz and 2KHz were converted to Δ HL 
and Δ SL data, by computing the mV difference  between scores 
at consecutive stimulus levels. This data was analysed graphically 
with the aim of  examining the influence  of  Δ HL and Δ SL meas-
urement methods on inter-group trends. 

RESULTS AND DISCUSSION 

NORMALS 

The graphical representation of  data from  38 test ears at lKHz and 
2KHz, over a 100-125 dBHL range and a 0-25 dBSL range, rev-
ealed that the nature of  ARA growth was neither mathematically 
linear or curvilinear (refer  to Figure 2). This finding  contrasts with 
the relevant literature which has variably reported ARA configu-
rations in normal subject groups to be exactly linear (Uliel, 1980; 
Clemis and Sarno, 1980) or curvilinear (Dallos, 1964; Sprague et 
al., 1981; Wilson and McBride, 1978). It is possible that this dis-
crepancy between present and other research findings  is a function 
of  the small sample size and considerable variability in function 
configurations,  that characterised this study. 

mV 

ν 
•Ό 

Q. 
Ε < 
X φ 

φ CC 

ο ο < 

KEY Χ = HL,1KHz 
Ο = SL,1KHz 
• = HL,2KHz 
Δ = SL,2KHz 

_ ι _ 

100 105 

10 15 
dB SL 

110 115 
dB HL 

20 25 

120 125 

Figure 2 ARA functions  for  normal subjects at lKHz and 
2 KHz for  HL and SL data / 

The differential  effect  of  measurement method on ARA configura-
tion was visually evident at 2KHz but not at lKHz (refer  Figure 
2). There was no difference  between the HL-SL configurations  at 
lKHz, whereas at 2KHz an asymptotic function  was characteristic 
of  the SL but not the HL function.  ^ 

The obtained 'tail-end' slope index values were as follows: 
HL 0.3 mV (lKHz) SL 0.3 mv (lKHz) 
HL 0.5 mV (2KHz) / S L O.'l mv (2KHz) 

These values substantiated the graphical findings:  while there was 
no difference  between the HL and SL values at lKHz, the SL index 

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Normal Acoustic Reflex  Amplitude Growth and the Influence  of  Cochlear Hearing Loss 61 

mV 

ν 
Ό 

"5. ε < 
X φ 

φ 
CC 
ο 
ΰ ) 
3 
ο 
ο < 

30 dBSL 

100-125 dBHL 

° Key: Χ = 1 KHz Ο = 2ΚΗζ 

_L _L _ L _L _1_ _ L 
85 95 105 

dB HL 
115 125 

Figure 3 A complete ARA function  for  a sample of  10 nor-
mal subjects, with super imposed HL and SL 
ranges, at IKHz and 2KHz 

at 2KHz was reduced relative to the HL value, indicating an asymp-
totic function. 

This HL-SL configuration  difference  is in keeping with the find-
ings of  Sprague et al (1981), and requires an explanation particular-
ly in view of  it's frequency  selectively in this study. Figure 3 
illustrates an ARA function  for  the subgroup of  normal subjects who 
demonstrated a broad dynamic range (85-125 dBHL) at IKHz and 
2KHz. The superimposition of  HL and SL ranges on the graphical 
figures  reveals that the differences'in  function  configuration  descrip-
tion (such as asymptotic versus non-asymptotic) can result from  ana-
l y s e s ^ different  portions of  a wide intensity range. This possibly 
explains discrepancy in descriptions reported in the literature: linear 
versus curvilinear. Figure 3 illustrates further  that the absence of 
an asymptotic SL function  at IKHz was simply a function  of  the 
breadth of  dynamic range underi investigation, namely 25 dBSL; 
an asymptotic function  would have resulted had a 30 dBSL range 
been investigated. Considerable variability was found  in the rate and 
pattern of  ARA growth amongst normal subjects. This inter-subject 
variability was pronounced for  HL measurement and relatively 
reduced for  SL measurement, in keeping with the findings  of  Petersen 
and Linden (1972). A broad range of  normal variability might ob-
scure the clinical identification  of  mild or even moderate patholog-
ical deviance, and therefore  it is implied that SL measurement offers 
a better prognosis for  clinical sensitivity in ARA testing, than HL 
measurement, by reducing this range. 

INTER-GROUP COMPARISONS 

Graphical representation of  the function  configurations  for  groups 
A, B, and C, for  SL data at IKHz and 2KHz revealed a marked 
trend; group C demonstrated a visually steeper ARA function  (faster 
ARA growth rate), while groups A and Β were similar regardless 
of  stimulus parameters (refer  to Figures 4 and 5). This trend was 
also characteristic of  HL data, at 1 and 2KHz, although less 
pronounced. 

Whole slope index values quantified  and confirmed  these findings: 
the highest values were consistently obtained for  group C, indicat-
ing a faster  ARA growth rate in this group than in either groups 
A or Β (refer  to Table 2). 

mV 

Φ 
•Ό 

α . 
Ε < 

Φ 
CC 

3 
Ο 
ϋ < 

KEY Χ = Group Α 
Ο = Group Β 
Δ = Group C 

15 20 25 0 5 10 
dB SL 

Figure 4 ARA functions  at IKHz, for  SL data, showing 
inter-group growth rate trends 

mV 5 KEY X = Group A 
Ο = Group Β 
Δ = Group C 

Φ 
• σ 
3 

t 3 
Ε < 

χ φ 

φ CC 

• I 2 

ο 
ο < 

1 ' 

5 10 15 20 25 
dB SL 

Figure 5 ARA functions  at 2KHz, for  SL data, showing 
inter-group growth rate trends 

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62 Juliette Womersley and Lucille Dickens 

Table 2 Whole-slope index mV values for  groups A, 
Β and C 

GROUP HL, 1 KHz SL, 1 KHz 

A 0,4 0,4 

Β 0,3 0,5 

C 0,6 0,8 

HL, 2 KHz SL, 2 KHz 

A 0,3 0,4 

Β 0,3 0,5 

C 0,8 0,8 

The 2-ANOVA-RB statistic for  HL and SL measurement at IKHz 
and 2KHz, yielded significant  F-ratio values (p<0.01, and ρ <0.05 
for  SL data at 2KHz). The SME statistic indicated that significant 
variation within all subjects (variable A collapsed), existed at specific 
stimulus levels for  IKHz and 2KHz, these levels being more numer-
ous for  SL than HL data, and for  1 KHz and 2 KHz data. These 
findings  suggest that the 1 KHz stimulus and the SL measurement 
method were more sensitive to inter-subject variation, and there-
fore  have greater potential clinical value. 

The Tukey's t-test results quantified  inter-group variability at the 
specific  stimulus levels identified  by the SME statistic. The similarity 
between groups A and Β suggested by graphical and slope index 
analyses was confirmed:  Tukey's t values in the group A - group 
Β comparison never reached statistical significance.  In contrast 
statistical significance  was revealed in the group C — group A, and 
group C — group Β comparisons, but only at specific  stimulus levels. 

These statistical results suggest that the label of  a 'faster  than nor-
mal ARA growth rate' in group C, is only valid at specific  stimulus 
levels. The discussion that follows  however, is based on overall trends 
of  inter-group comparisons, since the implications arising from 
statistical analyses on a small subject sample may be misleading. 

The finding  of  a faster  than normal ARA growth rate in the heter-
ogeneous pathology group (C) agrees with the research of  Clemis 
and Sarno (1980) who found  this to be characteristic of  cochlear 
disordered subjects, but is contrary to the findings  of  Petersen and 
Liden (1972) and Beedle and Harford  (1973) who found  a slower 
growth rate in cochlear disordered subjects. The similarity in growth 
rate between groups A and Β was unexpected since Clemis and Sarno 
(1980) repeatedly observed a faster  than normal ARA growth rate 
in Meniere's Disease subjects, as did Sprague et al. (1981) in a sin-
gle case of  Meniere's Disease. 

The dissimilarity in ARA growth rate between groups Β and C was 
surprising in view of  their common lineage - both groups belonged 
to the cochlear population. This dissimilarity raises two issues for 
•discussion: firstly,  the variability in ARA data within the cochlear 
population requires an explanation, and secondly, the interpretation 
or meaning of  a faster  than normal ARA growth rate must be ques-
tioned. Clearly, a faster  than normal ARA growth rate cannot be 
interpreted as being indicative of  cochlear pathology since subjects 
in the population have also yielded a slower than normal ARA growth 
rate (Petersen and Liden, 1972) and a normal growth rate as shown 
in this study. 

The term 'recruitment' has been used by Uliel (1980) and Clemis 
and Sarno (1980) in association with a faster  than normal ARA 
growth rate. The use of  this term in this context does not agree with 
other research. Beedle and Harford  (1973) specifically  investigated 
cochlear subjects with concomitant loudness recruitment and found 
a slower ARA growth rate. Furthermore, in this study all experimen-
tal subjects demonstrated loudness recruitment on the Metz Test, 
however only those subjects in group C yielded the faster  ARA 
growth rate. 

An alternative interpretation of  intra-cochlear variability and a faster 
ARA growth rate, is based on the relationship between cochlear 
pathology and the neurological basis of  the ARA response system. 
Evans (1982) states that damage to a cochlear fibre  causes a broaden-
ing of  its frequency  threshold curve and a consequent increase in 
the rate at which adjacent cochlear fibres  become activated as a func-
tion of  increasing stimulus intensity. If  this is an acceptable expla-
nation of  a faster  ARA growth rate, then it is implied that cochlear 
fibre  functioning  in the Meniere's Disease group was normal, since 
this group yielded an ARA growth rate mapping that of  normal sub-
jects. No definitive  statements can be made regarding the differen-
tial effect  of  cochlear pathology on hair cell morphology in groups 
Β and C, however, the variability in state and stage of  disease that 
is characteristic of  Meniere's disease patients (Brackman, Selters 
and Don, 1982) may be of  significance  when contrasted with the 
profile  of  subjects in group C, all of  whom reported a minimum 
10 year history of  bilateral hearing loss with no fluctuating  symp-
tomatology. It would be of  interest in future  research to specifically 
compare a group of  subjects with known hair cell damage, with a 
group of  'early' stage Meniere's Disease patients who had shown 
symptom-reversability on Glycerol testing (thus suggesting no per-
manent hair cell damage). 

Audiogram configuration  is another variable which may have con-
tributed to the dissimilarity between groups Β and C. Five of  the 
six Meniere's subjects showed predominantly low frequency  hear-
ing loss whereas this was not characteristic of  subjects in group C. 
Future research may reveal that lower test frequencies  (below IKHz) 
are more sensitive to Meniere's Disease and therefore  elicit a faster 
ARA growth rate in these subjects. 

mV 1.25 

1.00 
<1) 
T3 
3 

Ε 0.75 < 
X 
α> 
α> a 0.50 
ο 
<0 
Ο 
ο 

< 0.25 

100-105 110-115 120-125 
dB Δ HL χ ' 

Figure 6 ARA functions  for  Δ HL data at 1 KHz, illustrat-
ing the ascending-descending configuration 
similarity between groups Β and C, relative to 
group A 

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Normal Acoustic Reflex  Amplitude Growth and the Influence  of  Cochlear Hearing Loss 63 

These explanations put forward  to account for  intra-cochlear varia-
bility are tentative owing to the use of  small sample sizes, and par-
ticularly in view of  the degree of  normal variability in ARA data 
in this study. 

Graphical analyses of  Δ HL and Δ SL data suggested that groups 
Β and C behaved similarly, in contrast with the trend revealed by 
HL and SL data (refer  figure  6). This similarity manifested  itself 
in an ascending-descending configuration  which was riot charac-
teristic of  group A. The meaning of  this configuration  is not cer-
tain, however the implication is that Δ HL and Δ SL measurement 
methods were more successful  than all other methods in distinguish-
ing between normal and cochlear subjects per se. In view of  this 
implication, it is possible that the intra-cochlear variability in this 
study was a deceptive consequence of  measurement method and not 
a real phenomenon. This does not alter the intra-cochlear variabili-
ty found  within Uliel's (1980) study and between other studies (Cle-
mis and Sarno, 1980; Petersen and Liden, 1972; Beedle and Harford, 
1973), which remains worthy of  note and is as yet not successfully 
accounted for. 

CONCLUSIONS 

The configuration  of  ARA growth functions  obtained for  normal 
hearing subjects were shown to be influenced  by the method of  ARA 
measurement, namely HL versus SL measurement. This variable 
determined which area of  dynamic range of  amplitude growth was 
analysed, and consequently determined the asymptotic versus non-
asymptotic configuration  difference.  The same variable may also 
account for  discrepancies in ARA configuration  description in the 
literature. If  this hypothesis is correct then the implication is that 
a standardised methodological basis for  ARA is required, because 
without reliable normative data the relative influence  of  hearing im-
pairment cannot be successfully  determined. 

On the basis of  HL and SL measurement methods, the Meniere's 
Disease group yielded an ARA growth rate similar to that of  nor-
mal subjects, while the heterogeneous pathology group showed a 
faster  than normal ARA growth rate. This intra-cochlear variabili-
ty has also been found  in other studies and suggests that ARA meas-
urement has a poor prognosis for-clinical  sensitivity. This is implied 
since'faster  than normal ARA growth rate (positive result) might 
indicate cochlear disorder but a negative test result would not con-
traindicate cochlear disorder. 

Δ HL and Δ SL measurement methods distinguished, to a certain 
extent, between the normal and cochlear disordered subjects per 
se, and therefore  offer  a better prognosis for  test sensitivity than 
either the HL or SL methods. It could be the purpose of  future 
research, therefore,  to examine and compare these and other alter-
native measurement methods with the aim of  improving clinical sen-
sitivity to the degree that would be necessary if  ARA measurement 
was to be included in the impedance audiometry test battery. 

REFERENCES 

Beedle, R.K., and Harford,  E.R. Comparison of  the acoustic reflex 
and loudness growth in normal and pathological ears. J.  Speech 
Hear.  Res., 16, 271-281, 1973. 

Borg, E. Dynamic characteristics of  the intra-aural muscle reflex. 
In Acoustic Impedance  and  Admittance  — the measurement of 
middle  ear function.  Feldman, Α., Wilber, L. (Eds.). The Wil-
liams & Wilkins Co., Baltimore, U.S.A., 1976. 

Brackman, D.E., Selter, W.A., and Don, M. Auditory evoked 
responses. In Otolaryngology  1: Otology,  Gibb, A.G. & Smith, 
H. (Eds.) Butterworth & Co., London, 1982. 

Clemis, M.D., and Sarno, C.N. The acoustic reflex  latency test: 
clinical application. Laryngoscope, 90, 601-610, 1980. 

Dallos, P. Dynamics of  the acoustic reflex:  phenomenological 
aspects. J.  Acous. Soc.  Am., 36, 2175, 1964. 

Evans, E.F. Recent advances in cochlear physiology. In Otolaryn-
gology  1: Otology.  Gibb, A.G., & Smith, M. (Eds.) Butterworth 
& Co., London, 1982. 

Jerger, J. Handbook  of  Clinical  Impedance,  Chap. 7. American Elec-
tro Medics Corp., New York, 1975. 

Jerger, J., and Hayes, D. Latency of  the acoustic reflex  in eighth 
nerve tumour. Arch. Otolaryngol.,  109, 1-5, 1983. 

Osterhammel, P., and Osterhammel, D. Age and sex variations for 
the normal stapedial reflex  thesholds and tympanometric com-
pliance values. Scand.  Audio.,  8, 153-158, 1979. 

Petersen, J. and Liden, G. Some static characteristics of  the stapedial 
muscle reflex.  Audiology,  11, 97, 1972. 

Sprague, B.H., Wiley, T.L., and Block., M.G. Dynamics of  acous-
tic reflex  growth. Audiology,  20, 15-40, 1981. 

Uliel, S. Acoustic reflex  measurements and the loudness function 
in sensori-neural hearing loss. S.A.J.  Commun. Dis., 27, 58-77, 
1980. 

Wilson, R.H. and McBride, L.M. Threshold and growth of  the 
acoustic reflex.  J.  Acous. Soc.  Am., 63, 147-154, 1978. 

Die Suid-Afrikaanse  Tydskrif  vir Kommunikasieafwykings,  Vol.  32, 1985 

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