Tympanometry in Neonates- A Comparative Study-Juniper Publishers
Juniper Publishers-Journal of Pediatrics
Abstract
Objective: Impairment to hearing during
childhood may lead to delay in the speech and language skills, making
the communication process more difficult. Early identification and
rehabilitation can benefit the children. It is necessary to test the
hearing using accurate test procedures. Thus, aim of the study was to
compare the use of probe tones (226Hz and 1000Hz probe tone) in
tympanometry while testing the neonates for hearing before getting
discharged from hospital setup.
Method: An inclusion - exclusion criteria was
applied in selection of 60 neonates (1-17days). Hearing screening with
comparison of 226Hz and 1000Hz probe tone in tympanometry was carried
out using a comparative study design. Pressure ranging from + 200 to
-400 daPa and a pressure change rate of 600/200 daPa per second was used
for testing. Intensity of probe tone was adjusted at 85 dB SPL.
Comparison was made for type of tympanogram, ear canal volume,
compensated static peak acoustic admittance and tympanometric peak
pressure. Sampled paired t test was used to carry out statistical
analysis.
Results: 1000 Hz probe tone surpassed the
226Hz probe tone in testing the neonates using tympanometry. A
statistically significant difference was observed in all the
sub-sections except similar values for ear canal volume.
Conclusion: Many changes occur in the ears of
neonates like changes in bone density, mesenchymal loss which has an
impact on the mechanical properties of the auditory canal and middle ear
system. Thus, 1000Hz probe tone in tympanometry serves a promising
tool.
Keywords: Probe tone; Neonates; Immittance audiometry
Abbreviations:
DPOAE: Distortion Product Otoacoustic Emissions; SP: Single-peaked
tympanogram; TPP: Tympanometric peak pressure; DP: Double-peaked
tympanogram; IP: Inverted peaked tympanogram; A: Asymmetric tympanogram;
F: Flat peaked tympanogram; Ymt: Compensated static peak acoustic
admittance; ECV : Ear Canal volume
Introduction
Normal hearing ability is the main source for
development of speech and language skills. Any impairment to hearing
during childhood may lead to delay in the speech and language skills,
making the communication process more difficult. However, early
identification and rehabilitation if given can work for the benefit of
the children. Therefore in neonates, it is recommended to carry out a
complete hearing evaluation before moving out from the hospital setup
post delivery. In addition, it is necessary to focus on the test battery
used for testing the hearing of neonates. In accordance with the
literature, there still persists a debate on using 226Hz probe tone and
1000Hz probe tone for testing the neonatal hearing.
Tympanometry is an umbrella term encompassing
impedance, admittance, and their components. It is defined as mechanical
analysis of the auditory system in response to acoustic stimulation.
Acoustic immittance measures the acoustic energy transfer that occurs
when sound pressure is applied to the tympanic membrane causing its
movement. Thus it helps to evaluate the ease or opposition to this sound
energy flow within the auditory system. Today, its contribution to
clinical diagnosis has aided to better middle ear status diagnosis and
has now become a routine part of the audiological test battery approach
ranging towards neonates to geriatrics.
In the early years of life up to two years, normal
ear tympanic- ossicular system acts differently as mass is the
dominating physical feature of the ear. After this age, reaching the
adult stage, there is a change in behavior which is controlled by
stiffness and is better evaluated using probe frequency of 226 Hz [1].
Thus carrying out conventional tympanometry using 226Hz probe tone at
early years of life may not serve of much help. Therefore, condition of
the middle year in the early stages of life can be evaluated more
expeditiously using high frequency probe tones such as 678 Hz and 1,000
Hz. Conventional tympanometry using 226Hz probe tone in neonates and
infants has been used by many audiologists [1-4],
although the literature shows that the use of a single frequency is not
sensitive enough to detect all cases of middle ear pathology which
hinders accurate diagnosis [5 -8].
Tympanometry using high frequencies help to clear up
the false-positive screening results that pass off due to pathology in
the middle ear or the presence of secretion. Adequate middle ear
assessments in the neonatal period results in suitable medical and
audiological referrals and can thereby improve the efficacy of newborn
hearing screening programs [9].
Evidence from previous literature suggests that the use of a single
frequency probe is not highly sensitive enough to identify all cases of
middle ear alterations, thereby making diagnosis difficult. Therefore,
the purpose of this study was to characterize tympanometry measurements
in neonates between 0-17days of age using 2 probe tones.
Materials and Methods
The study was undertaken with the approval of ethical
committee formed at Nitte Institute of Speech and Hearing, Mangalore.
To conduct the study, following inclusion criteria was considered for
the participants of the study:
A. Neonates of 1 to 17 days,
B. Neonates administered and screened for high risk register using Joint Committee on Infant Hearing [10] to rule out possible presence of hearing impairment,
C. Ear canal screened to examine the possible obstacles,
D. Neonates with bilateral Distortion Product Otoacoustic Emissions (DPOAE) present.
A Term of Free and Informed Consent form was
furnished to the Parents/caregivers which contained information about
the study in very clear and uncomplicated language. Once the parental
consent was signed and obtained the study was continued. The study
incorporated 60 neonates: 21(35%) female and 39 (65%) . The age ranged
between from 1day to 17 days, with an average age of 2.9 days of life. A
total of 120 years were evaluated right (100%) and left (100%).
Audiological interview was carried out to begin with
the screening assessment, which was followed by visual inspection of the
pinna and ear canal, Distortion Product Oto-acoustic Emission testing
and tympanometry measurements. Audiological interview in collaboration
with information from hospital files was carried out with the
parents/caregivers using leading questions, in simple and uncomplicated
language. The purpose was to serve the information regarding neonatal
hearing, presence of any upper respiratory tract infection, and high
risk indicators for hearing impairment.
Visual inspection of the pinna, ear canal and
tympanic membrane was carried out by an experienced clinical audiologist
to rule out any disturbances in testing of tympanometry. If any
disturbances were encountered the neonate was referred to the
Oto-rhino-laryngologist for the further evaluation.
To acquire the tympanometry measurements,
Interacoustics AT 235h impedance audiometer was used. Following the
specifications of the equipment manual, tympanometry was applied using
226Hz and 1000Hz frequencies, with the pressure ranging from + 200 to
-400 daPa and a pressure change rate of 600/200 daPa per second. The
intensity of probe tone was adjusted at 85 dB SPL for 226Hz and 1,000
Hz.
Two forty tympanograms were obtained: 114 (95%) with a
226 Hz probe tone, 109 (90.8%) with a 1,000 Hz probe tone. The
occlusion encountered during the testing procedure lead to unequal
distribution of the tympanograms. In the consequence of occlusion with a
226 Hz and 1000Hz probe tone, the probe was removed from ear and
repositioned to restart the testing.
The obtained Tympanogram shapes were categorized as
either a single-peaked tympanogram (SP) with maximum tympanometric peak
pressure (TPP), a double peaked tympanogram (DP) with two-peak TPP, an
inverted peaked tympanogram (IP) with an inverted TPP, an asymmetric
tympanogram (A) with a gradual decline of TPP ranging from +200 to -200
daPa and, or a flat peaked tympanogram (F) with no TPP. Similarly,
compensated static peak acoustic admittance (Ymt) mentions the maximum
peak admittance, where the pressures of the external and middle ear are
equal. The maximum admittance peak pressure is expressed in daPa.
With the previous literature [10-12],
using 226Hz probe tone SP or DP tympanograms were classified as normal.
For 1,000Hz frequency, tympanograms were classified using the Sutton
Protocol [13],
used for infants upto the age of 4 months. Shadowing this protocol,
tympanograms with Ymt>0 and TPP>-200 daPa were considered as
normal. Tympanograms with Ymt<0 or TPP < - 200 daPa were
considered as abnormal. On classification of tympanograms as either
normal or abnormal, the tympanograms with the two different probe tones
were compared. In addition, to the literature, single-peaked and
double-peaked tympanograms are considered normal, while asymmetric,
inverted, and flat tympanograms are considered abnormal [13-16].
Results
Tympanometry was carried out in 60 healthy neonates
using 226Hz and 1000Hz probe tone. The tympanometry measures were
compared in accordance with type of tympanogram, ECV, Ymt, TPP. The
obtained measures for 226Hz and 1000Hz were compared to know the
efficacy of the probe tones. Sampled paired t test using SPSS version:
16 was used to obtain a statistically significant difference between the
two probe tones.
On comparing the type of tympanograms, 226Hz elicited
71 Single Peaked tympanogram with maximum tympanometric peak pressure
and 49 flat peaked tympanogram (F) with no TPP. However, lGGGHz elicited
B3 Single peak tympanogram with maximum tympanometric peak pressure, 26
double peak tympanograms with two-peak TPP and llflat tympanogram with
no TPP (Figure 1).
Using sampled paired t test it is evident that 1000Hz
probe tone is more compatible for neonatal hearing testing then 226Hz
probe tone with respect to ECV, Ymt and TPP. However there is a
significant difference between the ECV and Ymt. Table 1 shows the statistical differences between the three parameters (Table 1).
Using the 226Hz and 1000 Hz probe tone, the ECV
values were almost the same. There was less variation observed using
226Hz and 1000Hz probe tone frequencies. The sampled paired t test
revealed no significant difference for the same. However, using 226Hz
and 1000Hz probe tone Ymt and TPP were not the same. Sampled Paired t
test revealed a significant difference between Ymt and TPP using 226Hz
and 1000Hz probe tone in neonates.
A significant difference was observed, when the 226Hz
and 1000Hz probe tone frequencies were compared. This indicates that
the 1000Hz probe tone surpassed the limitations of 226Hz probe tone in
the mass dominating middle ear system of the neonates with better
measurements.
Discussion
The results were earned by grouping the right and
left ears to facilitate better statistical analysis, as there was no
significant difference found between the ears in the previous studies.
In the present study a statistically significant difference across two
subsections was seen.
It determines compensated static acoustic admittance. For 226 Hz probe tone, the normal range of ECV is between 0.3 and 1.0 mL [17-19]. Literature reports a mean of about 1.5 mm [6,11]. GRASON-STADLER [20]
reports, ECV values acquired with a frequency of 678 Hz are 3 times
larger than the ECV values obtained at 226 Hz, and that at 1,000 Hz
probe tone. This difference can be up to 4.4 times larger. The current
study reports that the ECV values obtained using high frequencies are
greater with 1000Hz than values obtained with 226 Hz. Consistent with
this statement, a significant difference between the results of the 3
frequencies was found, with the mean ECV value at 1,000 Hz greater than
the mean values at 678 Hz and 226 Hz [14].
In the present study 226Hz probe tone obtained single
and flat peaked tympanograms however; 1000Hz probe tone lead to single,
double and flat peaked tympanograms. The possible tympanometry measures
leading to differences in the type of peaks could be attributed to the
possible presence of cerumen in the ear canal, placement of the probe in
the infant ear, or differences in the middle ear system of infants [20].
Similarly, the presence of unequal distribution in number of
tympanograms could be due to the presence of occlusion effect. Infants
younger than 4 months old have higher chance of obtaining occlusion
effect during the testing [11] and a low occurrence of flat tympanograms, indicate possible presence of fluid in the middle ear.
Similarly, literature reports, occurrence of single-peaked tympanograms to be predominant [11,20], while other studies indicate a preponderance of double-peaked tympanograms in neonates and infants using 1000Hz probe tone [12,21]. In addition, a higher incidence of single-peaked tympanograms [11,14], followed by flat tympanograms is also quoted [14].
Single-peaked and double-peaked tympanograms are considered normal,
while asymmetric, inverted, and flat tympanograms are considered
abnormal [13-16].
Literature reports different findings with 226Hz and 1000 Hz probe
tones. The uncommon characteristics of the tympanograms obtained from
newborns and babies, may be attributed to the physiological differences
concerning the ears from newborns and adults [22].
Literature reports high frequency tympanometry provides more detailed
information about the state of the mechanics and acoustics of the ear,
especially for changes related to the mass factor [23-24],
as well as the possibility of middle ear pathology at the initial or
final stage. To conclude, 1000Hz probe tone reduces prevalence of flat
tympanograms in newborns and 1000 Hz probe tone has also been identified
as having greater sensitiveness to identify mild middle ear disorders [25].
The differences observed in obtaining tympanometric
curves in neonates can be attributed mainly to normal variations in the
subject population and also by the differences in the age of neonates.
During growth there are many changes that occur in the ears of neonates,
which have an impact on the mechanical properties of the auditory
canal. Among the physical changes, differences are seen in the external
ear and in the middle ear growth such as enlargement of the external
ear, mastoid and middle ear cavity, changes in tympanic membrane
orientation and tympanic annulus fusion. Some other variations such as
changes in bone density and mesenchynal loss occuring during development
could also play a major role. These changes could be related to the
acoustic changes influencing the recording of the tympanogram with
compensated static peak acoustic admittance [6, 16, 26, 27].
In addition, mass components are larger in high
frequency and lower in the low frequency tympanometry [6, 22]. The
normal middle ear is primarily dominated by the stiffness of low
frequency sounds (226 Hz). In a higher frequency (for instance: 1000
Hz), the relative participation of each anatomical structure is changed
and the acoustic admittance measured at the middle ear inlet becomes
more predominated by the mass [12].
The admittance measurement in tympanometry indicates
changes in the middle ear, literature reports higher mean Ymt values at
1,000 Hz compared to 226 Hz [11,13]. Mean Ymt values equal to 1.06 mmho when evaluating neonates [28].
The results of the current study are in acceptance with the literature.
On statistical analysis 1000Hz probe tone obtained higher values of Ymt
in comparison to 226Hz probe tone. Low frequency tympanometry in
newborns and babies younger than six months has low sensitivity, in
other words, the high level of false-negatives.
While comparing the tympanometric peak pressure (TPP)
obtained with 226 Hz and 1000Hz. The current study indicated a higher
TPP value with 1000 Hz than with 226 Hz. Similar findings have been
reported in the literature [3, 6]. Although there were statistically
significant differences between the frequencies with respect to TPP,
none of the differences were clinically significant. That is, the
results for all 2 frequencies were within the normal range [13].
In addition, testing neonates using tympanometry,
tympanograms with probe tone of 1000 Hz are reliable, easier to
interpret than 226Hz probe tone. It is easy to interpret and more
reliable (91%) using 1000Hz than the 226 Hz (35%) probe tone, which
shows a significantly better result in the assessment of the middle ear
system. Similarly, in infants younger than 3 months of age, 226 Hz probe
tone resulted in 58% of false-positive results [25].
The results of the current study are in accordance
with the findings in the literature. These findings provide evidence for
further obtaining normative values at different ages to adapt clinical
practice to the use of high frequency probe tones with young children.
Conclusion
The current study aimed at comparing the two probe
tones and its measurements in tympanometry. The neonates were considered
as the subjects of the study. The difficulties met by 226Hz probe tone
were seen to be surpassed by 1000Hz probe tone in neonatal tympanometry
acoustic measurements. Neonates can be well diagnosed using a 1000HZ
probe tone using tympanometry. However, further is warranted as the
sample size used in current is small.
Informed consent
Informed oral consent was obtained from all individual participants included in the study.
Ethical approval
All procedures performed in studies involving human
participants were in accordance with the ethical standards of the
institutional and/or national research committee and with the 1964
Helsinki declaration and its later amendments or comparable ethical
standards.
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