Keywords
Auditory Cortex - Parkinson Disease - Hearing Loss - Evoked Potentials, Auditory -
Event-Related Potentials, P300
INTRODUCTION
Increased life expectancy is a preponderant factor in epidemiological transition,
requiring greater attention to aging-related chronic and degenerative diseases,[1] including Parkinson's disease (PD),[2]
[3] whose predominance is 1 to 2 per 1000 people in the general population and 1 per
100 in those over than 65 years old.
PD was described by James Parkinson in 1917 as a paralysis agitans,[4] and its classic clinical condition is characterized by motor signs such as tremors,
stiffness, bradykinesia, and postural instability, due to the degeneration of nigrostriatal
dopaminergic neurons at the brain nuclei.[5] PD is currently recognized as a disease with a broader and more diffuse spectrum
involving not only the dopaminergic neurodegeneration of the motor system but also
the impairment of various organs and systems manifested with nonmotor signs and symptoms.[6]
[7]
[8]
Although clinical manifestations are the basis for diagnosis and analysis of the progression
of the disease, the process of neuropathological degeneration can precede the appearance
of these signs and symptoms by several years, which become evident with extensive
dopaminergic neuronal loss in the substantia nigra in more advanced degenerative conditions.[9]
Complaints related to reduced hearing sensitivity and, consequently, the search for
an audiological diagnosis in individuals with the disease are often neglected by patients
and professionals, to the detriment of the significant motor, psychiatric, cognitive,
and autonomic impairments present in the disease.[10] However, hearing loss is common in the elderly and contributes to social isolation,
reduced independence, and functional capacities, as well as worsening cognitive impairments
and emotional compromises.[11] Thus, the effects of hypoacusis can be minimized when proper diagnosis and auditory
rehabilitation strategies are performed, improving the quality of life of this section
of the population.
Studies have found that the prevalence of hearing loss exceeds 70% in individuals
with PD and that this incidence is higher than that observed in elderly people without
the disease.[12]
[13]
[14]
[15]
In addition to alterations in the peripheral auditory system, leading to hearing loss
in this population, it is known that alterations in temporal perception are also attributed
to the cognitive deficits in attention and memory that can be observed in PD, maintaining
a close relationship with impairment in noradrenergic and cholinergic neurotransmitters.[16]
[17] Therefore, alterations in the Central Auditory Nervous System (CANS) should also
be investigated.
The central hearing has been assessed with electrophysiological tests, such as auditory
evoked potentials (AEP). They assess the neuroelectric activity in the auditory pathway,
from the auditory nerve to the brain cortex, as a response to an acoustic stimulus
or event. AEPs can be recorded with surface electrodes placed in various regions of
the scalp. They are generated by the sequential and synchronic activation of nervous
fibers throughout the auditory pathway.[18]
AEPs have been studied to assess hearing in various situations, including degenerative
neurological diseases.
In a systematic review of AEP in PD, it was observed that the presence of processes
that compromise the neuroelectrophysiological conduction of the afferent auditory
pathways is controversial in individuals with PD. It has not been possible to date
to establish a pattern that clearly defines whether there are and what types of AEP
abnormalities are present in this population.[19]
Therefore, the evaluation of the peripheral and central auditory pathways is important
including auditory brainstem response (ABR) and cortical auditory evoked potential
(CAEP) assessment. Electrophysiological evaluation could support the identification
of whether the functional integrity of the peripheral and central auditory pathways
in patients with PD and monitoring of the progression of the disease, as well as the
benefit of the treatment performed.
The hypothesis of this study is that individuals with PD would have delayed latency
of both ABR and CAEP responses, and reduced amplitude of CAEP components.
Considering this, the present study aimed to characterize the audiometric responses,
and the ABR and CAEP in individuals with PD.
METHODS
A prospective cross-sectional study was performed with adults and elderly people diagnosed
with PD by a neurologist. This study was realized at the Department of Audiology and
Speech Therapy, Physiotherapy and Occupational Therapy, University of Sao Paulo Medical
School, São Paulo, Brazil. The research was approved by the institutional Ethics Committee,
under research protocol no. 3.241.829.
The exclusion criteria were as follows: consuming alcohol or other illegal drugs;
occupational exposure to high sound pressure levels; excess cerumen; history or presence
of middle ear alterations; presence of Type B or C tympanometric curve[20]; presence of moderately severe, severe, or profound sensorineural hearing loss.[21]
The study comprised 32 individuals, over 40 years old. The study group (SG) was composed
of 16 individuals with PD, and the control group (CG) was composed of 16 individuals
without PD sex and age-matched to SG. PD patients were recruited at a specific Parkinson's
Association, and individuals without PD were recruited from a convenience sample.
Initially, an anamnesis, otoscopy, and acoustic Immittance measurements were performed
to verify the patient's eligibility according to the exclusion criteria.
After this, pure tone audiometry (PTA) was performed, using an audiometer manufactured
by Grason Standler, model GSI 61, in a soundproof booth, at frequencies from 0.25
to 8 kHz by air conduction. When any frequency between 0.5 and 4 kHz had a threshold
above 20 dB HL, the bone conduction threshold was investigated.
The electrophysiological assessment lasted ∼60 minutes. During the recording of this
procedure, the subject was seated comfortably in a recliner in an acoustically and
electrically treated room.
To assess AEPs, the intelligent hearing system equipment, model Smart EP, with insert
earphones, model ER 3A was used. The individual's skin was first cleaned with abrasive
paste, and the Ag/AgCl electrodes were fixed on the scalp with electrolytic paste
and micropore tape in specific positions, according to International Electrode System
IES 10–10, as follows: the ground electrode was placed on the forehead, the reference
electrodes were placed on the left (M1) and right mastoids (M2), and the active electrode
was placed on the vertex (Cz) to record CAEP and on the forehead (Fz) to record ABR.
For the ABR, a rarefied polarity click stimulus at 80 dBnHL was used, presented monaurally
at a presentation rate of 27.7 stimuli per second, totaling 2000 stimuli. Two recordings
were obtained to check their reproducibility and confirm the presence of a response.
The CAEP was recorded using an oddball paradigm. Acoustic speech stimuli (syllables
/ba/ and /da/) and tone burst stimuli (at 1000 and 2000 Hz) were presented monaurally
at 75 dBnHL, at a presentation rate of 1.1 stimuli per second, totaling 300 stimuli,
of which 15 to 20% were target ones. The standard speech stimuli were the syllable
/ba/ and the target ones were the syllable /da/. The standard tone burst stimuli were
at 1000 Hz, and the target ones were at 2000 Hz. Subjects were instructed to pay attention
to the target stimuli and count how many times the target event occurred.
For the ABR were analyzed the absolute latencies of waves I, III, and V and the interpeaks
I-III, III-V, and I-V in milliseconds (ms). For the CAEP investigation, the P1, N1,
P2, and N2 components were identified and analyzed regarding their latency and amplitude
peak-to-peak in the trial corresponding to the standard stimuli, while P3 was identified
and analyzed in the trial corresponding to the target stimuli.
To analyze the data, the unpaired t-test was used to compare the ages between the two groups. To compare the results
of PTA and ABR between the groups, we used the mixed ANOVA test of repeated measures,
in which the ear was considered as a factor of repeated measure, and the group was
considered as a factor between subjects. Finally, to compare the CAEP results between
the groups, a mixed repeated-measures ANOVA was used, in which ear and stimulus were
considered as repeated-measures factors, and the group was considered as a between-subjects
factor. Tukey's test was used for the post hoc analysis.
For the variables that showed a significant difference between the groups, a correlation
analysis was performed with age, time of diagnosis, and time of drug use using Spearman's
Rho test or Pearson test.
A significance level of 5% (α = 0.05) was adopted for all analyses.
RESULTS
SG comprised 16 individuals (eight females and eight males), aged 40 to 81 years (58.13 ± 11.03),
and CG had another 16 individuals, matched for sex and age with SG individuals, aged
42 to 81 years (57.75 ± 10.66), with no statistically significant difference between
the groups for the age factor (t = −0.098; p = 0.923).
SG individuals had been diagnosed between 0.6 to 21.5 years ago (7.22 ± 6.40) and
had been undergoing treatment for 0.5 to 21.3 years (7.12 ± 6.39), all of whom were
taking Prolopa ([Table 1]).
Table 1
Characterization of study group individuals
|
Subject
|
Time since diagnosis (years)
|
Time of treatment (years)
|
Other comorbidities
|
Other drugs they take
|
|
1
|
2.5
|
2.4
|
Denied
|
Denied
|
|
2
|
19.8
|
19.6
|
Hypertension /diabetes
|
Losartan 25 mg (for 5 years)
Metformin (for 6 years)
|
|
3
|
21.5
|
21.3
|
Hypertension
|
Losartan 50 mg and Hydrochlorothiazide 25 mg (for 15 years)
|
|
4
|
15.2
|
15.2
|
Hypertension /diabetes
|
Chlortalidone, Amlodipine, Somalgin, Nesina, and Metformin (for 2 years)
|
|
5
|
8.4
|
8.3
|
Denied
|
Denied
|
|
6
|
7.4
|
7.4
|
Denied
|
Denied
|
|
7
|
6.8
|
6.6
|
Denied
|
Denied
|
|
8
|
2.4
|
2.3
|
Denied
|
Denied
|
|
9
|
5.6
|
5.4
|
Denied
|
Denied
|
|
10
|
2.3
|
2.3
|
Denied
|
Denied
|
|
11
|
10.1
|
10.0
|
Denied
|
Denied
|
|
12
|
3.0
|
2.8
|
Denied
|
Denied
|
|
13
|
3.9
|
3.6
|
Hypertension
|
Simvastatin and Losartan 50 mg (for 3 years)
|
|
14
|
4.0
|
3.9
|
Diabetes
|
Forxiga (for 8 years)
|
|
15
|
0.6
|
0.5
|
Hypertension
|
Atorvastatin 80 mg and Atenolol 25 mg (for 7 years)
|
|
16
|
2.2
|
2.0
|
Denied
|
Denied
|
The hearing loss was more prevalent in the SG (p = 0.049), with 12 patients (75%) in the SG having hearing loss, while in the CG hearing
loss was observed in only six patients (37.5%). The descriptive analyses of the PTA
are shown in [Table 2]. The PTA at 1 kHz showed in the left ear higher hearing thresholds than in the right
ear (F= 9.01; p = 0.005). In addition, significantly higher thresholds were found in SG only at 6 kHz
(F= 4.76; p = 0.037) and 8 kHz (F= 4.52; p = 0.042), regardless of the ear ([Figure 1]). The mean thresholds (between the frequencies of 0.25 and 8 kHz in both ears) had
a positive correlation with age, and older patients had higher hearing thresholds
(r= 0.765; p< 0.001) ([Figure 2]).
Table 2
Descriptive analysis of the hearing thresholds obtained in the ATL for each frequency
in decibel hearing level (dB HL)
|
Group
|
Ear
|
Median
|
Mean
|
SD
|
Minimum
|
Maximum
|
|
0.25 kHz
|
SG
|
RE
|
17.50
|
16.25
|
8.06
|
0.00
|
25.00
|
|
LE
|
17.50
|
20.00
|
10.65
|
5.00
|
45.00
|
|
CG
|
RE
|
12.50
|
14.38
|
7.04
|
5.00
|
25.00
|
|
LE
|
15.00
|
14.37
|
6.55
|
5.00
|
25.00
|
|
0.5 kHz
|
SG
|
RE
|
17.50
|
15.00
|
8.17
|
0.00
|
25.00
|
|
LE
|
17.50
|
18.13
|
12.09
|
5.00
|
50.00
|
|
CG
|
RE
|
15.00
|
15.63
|
5.12
|
5.00
|
25.00
|
|
LE
|
15.00
|
15.63
|
6.55
|
5.00
|
25.00
|
|
1 kHz
|
SG
|
RE
|
15.00
|
14.38
|
7.27
|
0.00
|
25.00
|
|
LE
|
15.00
|
18.44
|
11.79
|
5.00
|
55.00
|
|
CG
|
RE
|
15.00
|
15.63
|
5.12
|
5.00
|
25.00
|
|
LE
|
20.00
|
18.44
|
6.25
|
5.00
|
25.00
|
|
2 kHz
|
SG
|
RE
|
20.00
|
17.81
|
8.94
|
5.00
|
40.00
|
|
LE
|
17.50
|
21.56
|
13.75
|
10.00
|
55.00
|
|
CG
|
RE
|
17.50
|
18.44
|
6.76
|
10.00
|
30.00
|
|
LE
|
17.50
|
18.44
|
7.69
|
10.00
|
35.00
|
|
3 kHz
|
SG
|
RE
|
20.00
|
22.81
|
17.51
|
5.00
|
70.00
|
|
LE
|
20.00
|
27.50
|
16.33
|
10.00
|
65.00
|
|
CG
|
RE
|
17.50
|
19.06
|
6.12
|
10.00
|
35.00
|
|
LE
|
15.00
|
18.44
|
8.70
|
10.00
|
40.00
|
|
4 kHz
|
SG
|
RE
|
15.00
|
25.63
|
20.89
|
10.00
|
85.00
|
|
LE
|
22.50
|
29.38
|
19.23
|
10.00
|
70.00
|
|
CG
|
RE
|
17.50
|
20.00
|
10.33
|
10.00
|
45.00
|
|
LE
|
20.00
|
22.19
|
10.80
|
10.00
|
50.00
|
|
6 kHz
|
SG
|
RE
|
25.00
|
31.56
|
24.13
|
10.00
|
100.00
|
|
LE
|
25.00
|
34.38
|
24.69
|
15.00
|
95.00
|
|
CG
|
RE
|
20.00
|
21.25
|
10.08
|
10.00
|
50.00
|
|
LE
|
15.00
|
18.13
|
5.74
|
10.00
|
30.00
|
|
8 kHz
|
SG
|
RE
|
25.00
|
33.13
|
26.26
|
10.00
|
105.00
|
|
LE
|
25.00
|
35.94
|
27.82
|
10.00
|
105.00
|
|
CG
|
RE
|
20.00
|
20.63
|
5.74
|
10.00
|
30.00
|
|
LE
|
20.00
|
20.00
|
5.77
|
10.00
|
35.00
|
Abbreviations: CG, control group; kHz, kilo Hertz; LE, left ear; RE, right ear; SD,
standard deviation; SG, study group.
Figure 1 Comparison of the mean hearing thresholds at 6 and 8 kHz between the two groups.
Figure 2 Scatter plot between age and mean hearing thresholds for each group.
ABR analysis included a descriptive analysis of the absolute latencies of waves I,
III, and V, and the latencies of interpeak intervals I-III, III-V, and I-V per group
and ear ([Table 3]). There were no statistically significant differences between the groups, however,
longer absolute latency of the wave V was obtained in the left ear, regardless of
the group (F= 8.32; p = 0.007).
Table 3
Descriptive analysis of absolute latencies of waves I, III, and V, and latencies of
interpeak intervals I-III, III-V, and I-V per group and ear in milliseconds (ms)
|
Group
|
Ear
|
Median
|
Mean
|
SD
|
Minimum
|
Maximum
|
|
Wave I
|
SG
|
RE
|
1.59
|
1.63
|
0.14
|
1.40
|
1.83
|
|
LE
|
1.65
|
1.68
|
0.16
|
1.50
|
1.98
|
|
CG
|
RE
|
1.68
|
1.65
|
0.13
|
1.35
|
1.83
|
|
LE
|
1.63
|
1.61
|
0.11
|
1.43
|
1.85
|
|
Wave III
|
SG
|
RE
|
3.69
|
3.71
|
0.19
|
3.45
|
4.15
|
|
LE
|
3.75
|
3.76
|
0.12
|
3.56
|
3.98
|
|
CG
|
RE
|
3.79
|
3.73
|
0.19
|
3.20
|
3.93
|
|
LE
|
3.79
|
3.75
|
0.11
|
3.53
|
3.90
|
|
Wave V
|
SG
|
RE
|
5.62
|
5.58
|
0.21
|
5.30
|
6.10
|
|
LE
|
5.73
|
5.67
|
0.18
|
5.35
|
5.95
|
|
CG
|
RE
|
5.59
|
5.57
|
0.17
|
5.15
|
5.83
|
|
LE
|
5.61
|
5.62
|
0.15
|
5.25
|
5.83
|
|
Interpeak interval I-III
|
SG
|
RE
|
2.09
|
2.14
|
0.21
|
1.79
|
2.53
|
|
LE
|
2.14
|
2.11
|
0.16
|
1.78
|
2.38
|
|
CG
|
RE
|
2.14
|
2.09
|
0.22
|
1.48
|
2.38
|
|
LE
|
2.18
|
2.17
|
0.09
|
2.03
|
2.33
|
|
Interpeak interval III-V
|
SG
|
RE
|
1.84
|
1.85
|
0.14
|
1.63
|
2.10
|
|
LE
|
1.91
|
1.91
|
0.15
|
1.55
|
2.13
|
|
CG
|
RE
|
1.84
|
1.83
|
0.14
|
1.63
|
2.03
|
|
LE
|
1.89
|
1.76
|
0.11
|
1.67
|
2.05
|
|
Interpeak interval I-V
|
SG
|
RE
|
4.01
|
4.01
|
0.22
|
3.73
|
4.50
|
|
LE
|
4.07
|
4.03
|
0.28
|
3.45
|
4.52
|
|
CG
|
RE
|
3.98
|
3.93
|
0.17
|
3.43
|
4.13
|
|
LE
|
4.05
|
4.02
|
0.12
|
3.80
|
4.20
|
Abbreviations: CG, control group; LE, left ear; RE, right ear; SD, standard deviation;
SG, study group.
The CAEP analysis included a descriptive analysis of P1, N1, P2, N2, and P3 latency
values ([Table 4]) and P1-N1, P2-N2, and N2-P3 amplitudes ([Table 5]) with each acoustic stimulus.
Table 4
Descriptive analysis of LLAEP component latencies obtained with both stimuli in milliseconds
(ms)
|
|
Group
|
Ear
|
N
|
Median
|
Mean
|
SD
|
Minimum
|
Maximum
|
|
Tone-burst
|
P1
|
SG
|
RE
|
16
|
63.00
|
67.25
|
21.21
|
38.00
|
102.00
|
|
LE
|
16
|
67.00
|
75.38
|
23.29
|
42.00
|
121.00
|
|
CG
|
RE
|
16
|
54.00
|
58.86
|
16.01
|
38.00
|
93.00
|
|
LE
|
16
|
56.00
|
58.69
|
18.57
|
39.00
|
115.00
|
|
N1
|
SG
|
RE
|
16
|
104.50
|
104.00
|
19.87
|
70.00
|
135.00
|
|
LE
|
16
|
100.00
|
101.50
|
19.08
|
62.00
|
133.00
|
|
CG
|
RE
|
16
|
98.00
|
102.19
|
23.43
|
84.00
|
122.00
|
|
LE
|
16
|
103.00
|
99.06
|
22.71
|
39.00
|
140.00
|
|
P2
|
SG
|
RE
|
16
|
183.00
|
183.38
|
28.66
|
140.00
|
258.00
|
|
LE
|
16
|
177.50
|
182.81
|
35.34
|
120.00
|
251.00
|
|
CG
|
RE
|
16
|
185.00
|
181.56
|
31.33
|
140.00
|
255.00
|
|
LE
|
16
|
172.50
|
173.13
|
20.64
|
146.00
|
212.00
|
|
N2
|
SG
|
RE
|
16
|
223.00
|
227.75
|
34.62
|
187.00
|
323.00
|
|
LE
|
16
|
201.00
|
213.94
|
41.43
|
148.00
|
289.00
|
|
CG
|
RE
|
16
|
261.50
|
249.38
|
37.06
|
179.00
|
311.00
|
|
LE
|
16
|
217.50
|
228.06
|
38.03
|
148.00
|
289.00
|
|
P3
|
SG
|
RE
|
16
|
351.00
|
344.69
|
43.99
|
248.00
|
401.00
|
|
LE
|
16
|
332.50
|
334.50
|
27.32
|
300.00
|
395.00
|
|
CG
|
RE
|
16
|
346.00
|
349.13
|
40.93
|
288.00
|
416.00
|
|
LE
|
16
|
317.00
|
326.00
|
37.77
|
245.00
|
373.00
|
|
Speech
|
P1
|
SG
|
RE
|
16
|
71.00
|
69.81
|
10.06
|
51.00
|
88.00
|
|
LE
|
16
|
76.00
|
72.31
|
12.38
|
36.00
|
85.00
|
|
CG
|
RE
|
16
|
72.00
|
70.25
|
16.49
|
43.00
|
100.00
|
|
LE
|
16
|
70.00
|
70.31
|
18.47
|
36.00
|
120.00
|
|
N1
|
SG
|
RE
|
16
|
109.00
|
105.50
|
15.47
|
77.00
|
130.00
|
|
LE
|
16
|
110.50
|
111.31
|
17.59
|
66.00
|
143.00
|
|
CG
|
RE
|
16
|
114.00
|
112.88
|
17.84
|
81.00
|
153.00
|
|
LE
|
16
|
115.50
|
115.19
|
23.54
|
66.00
|
179.00
|
|
P2
|
SG
|
RE
|
16
|
185.00
|
186.94
|
23.06
|
122.00
|
227.00
|
|
LE
|
16
|
190.50
|
187.07
|
33.12
|
87.00
|
232.00
|
|
CG
|
RE
|
16
|
78.50
|
188.19
|
35.81
|
121.00
|
269.00
|
|
LE
|
16
|
189.00
|
189.88
|
42.12
|
87.00
|
260.00
|
|
N2
|
SG
|
RE
|
16
|
232.50
|
241.63
|
44.11
|
167.00
|
351.00
|
|
LE
|
16
|
229.00
|
231.69
|
56.03
|
107.00
|
341.00
|
|
CG
|
RE
|
16
|
232.50
|
245.25
|
42.30
|
165.00
|
326.00
|
|
LE
|
16
|
260.50
|
251.81
|
50.99
|
107.00
|
312.00
|
|
P3
|
SG
|
RE
|
16
|
330.00
|
329.69
|
34.53
|
275.00
|
412.00
|
|
LE
|
16
|
334.00
|
333.13
|
37.30
|
267.00
|
385.00
|
|
CG
|
RE
|
16
|
343.50
|
346.93
|
45.05
|
272.00
|
456.00
|
|
LE
|
16
|
323.50
|
321.31
|
29.06
|
281.00
|
386.00
|
Abbreviations: CG, control group; LE, left ear; N, sample number; RE, right ear; SD,
standard deviation; SG, study group.
Table 5
Descriptive analysis of LLAEP component amplitudes obtained with both stimuli in microvolts
(µV)
|
|
Group
|
Ear
|
N
|
Median
|
Mean
|
SD
|
Minimum
|
Maximum
|
|
Tone-burst
|
P1- N1
|
SG
|
RE
|
16
|
3.52
|
3.74
|
2.39
|
0.07
|
8.14
|
|
LE
|
16
|
3.78
|
3.77
|
2.05
|
0.65
|
8.15
|
|
CG
|
RE
|
16
|
3.94
|
4.72
|
3.13
|
0.68
|
11.40
|
|
LE
|
16
|
4.53
|
5.24
|
2.59
|
2.42
|
11.79
|
|
P2-N2
|
SG
|
RE
|
16
|
2.49
|
2.60
|
1.24
|
0.80
|
4.93
|
|
LE
|
16
|
1.89
|
2.24
|
1.17
|
0.95
|
4.47
|
|
CG
|
RE
|
16
|
4.67
|
4.37
|
1.76
|
1.10
|
7.77
|
|
LE
|
16
|
3.47
|
3.25
|
1.57
|
0.76
|
5.85
|
|
N2-P3
|
SG
|
RE
|
16
|
4.23
|
5.02
|
4.59
|
0.62
|
19.17
|
|
LE
|
16
|
3.08
|
4.73
|
3.52
|
1.01
|
11.18
|
|
CG
|
RE
|
16
|
5.74
|
6.89
|
4.87
|
1.97
|
20.13
|
|
LE
|
16
|
7.45
|
7.38
|
4.05
|
1.39
|
15.80
|
|
Speech
|
P1- N1
|
SG
|
RE
|
16
|
2.24
|
2.83
|
1.87
|
0.93
|
7.12
|
|
LE
|
16
|
2.52
|
3.26
|
1.87
|
0.71
|
7.60
|
|
CG
|
RE
|
16
|
5.08
|
5.35
|
2.87
|
0.88
|
9.62
|
|
LE
|
16
|
4.38
|
5.54
|
3.24
|
1.87
|
11.31
|
|
P2-N2
|
SG
|
RE
|
16
|
2.84
|
2.57
|
1.00
|
0.63
|
4.35
|
|
LE
|
16
|
1.87
|
2.52
|
2.12
|
0.31
|
7.35
|
|
CG
|
RE
|
16
|
2.67
|
2.84
|
1.00
|
1.60
|
5.49
|
|
LE
|
16
|
2.50
|
2.82
|
2.02
|
0.42
|
8.07
|
|
N2-P3
|
SG
|
RE
|
16
|
5.07
|
5.04
|
3.36
|
0.76
|
10.99
|
|
LE
|
16
|
5.47
|
4.90
|
3.52
|
0.32
|
11.77
|
|
CG
|
RE
|
16
|
8.11
|
8.62
|
6.00
|
0.73
|
22.40
|
|
LE
|
16
|
6.48
|
8.09
|
6.41
|
0.43
|
21.90
|
Abbreviations: CG, control group; LE, left ear; N, sample number; RE, right ear; SD,
standard deviation; SG, study group.
With regard to latency, there was no significant difference for the ear, stimulus,
or group factor in either of the CAEP components (p> 0.05).
Concerning amplitude measurements, an interaction effect between the group and stimulus
was observed for the P1-N1 amplitude, with the SG showing reduced amplitude compared
with the CG only for the speech stimulus (t = 2.849; p = 0.034). For the P2-N2 amplitude, there was an interaction effect between the group
and stimulus, with the SG having a reduced amplitude compared with the CG for the
tone burst stimulus (t = 2.910; p = 0.027). In addition, there was a significant difference according to stimulus only
in the CG, where greater amplitudes were observed with the tone burst stimulus compared
with the speech stimulus (t = 3.084; p = 0.021). As for the N2-P3 amplitude, there were significant differences between
the groups, with the SG having a lower amplitude compared with the CG ([Figure 3]).
Figure 3 Comparison of P1-N1, P2-N2 and N2-P3 amplitudes between both groups.
There was no significant correlation between the results of the P1-N1, P2-N2, and
N2-P3 amplitudes and age, diagnosis time, and treatment time (p> 0.05).
DISCUSSION
This study aimed to characterize the audiometric responses and the ABR and CAEP with
both tone burst and speech stimuli in adults and elderly people diagnosed with PD
(SG) in comparison with ones without PD diagnosis (CG).
SG individuals had been diagnosed 0.6 to 21.5 years before and had begun treatment
0.5 to 21.3 years before; all of them were taking Prolopa, corroborating with other
ones, which also verified that the drug most used by PD patients was Prolopa.[22]
[23]
The PTA showed that individuals with PD had higher hearing thresholds than CG subjects
at 6 and 8 kHz. This finding corroborates previous studies in which the authors also
observed a worsening of hearing thresholds in PD patients, especially at higher frequencies,
even without clinical symptoms.[10]
[12]
[13]
[24]
[25]
[26]
[27]
[28] Their hypothesis is that the failure to release dopamine in the lateral olivocochlear
efferent fibers may affect the synapse between inner hair cells and afferent dendrites
of ganglion cells, thus altering the sound information conducted to the cochlear nucleus,[10] which can mainly damage the basal region of the cochlea.
Also, a recent study evaluated a family of five G protein-coupled dopamine receptors
(D1, D2, D3, D4, and D5) in mice and observed the expression of these receptors in
various cochlear regions, except for D3, with D2 receptors being expressed at much
higher levels compared with the others. Thus, it is possible that dopaminergic suppression
causes cochlear nerve fibers to be damaged when exposed to moderate sound pressure
levels.[29] This finding provides new insights into the physiological alterations present in
PD, which may underlie the hearing alterations observed in these patients.
Previous studies have reported an asymmetry of auditory function in PD, with greater
impairment being observed in the ear ipsilateral to the most affected side by motor
symptoms.[25] Another study also observed greater left-sided hearing impairment correlated with
motor system asymmetry in PD, and this decline in peripheral auditory function was
associated with basal ganglia dopamine transporter availability.[26]
Unfortunately, no information was collected on the side most affected in PD patients
and this was a limitation of this study, which should be considered in future studies.
Despite this, although a higher average hearing threshold was observed in the left
ear, this difference was only statistically significant for the frequency of 1 kHz,
and it was also a difference observed in both patients with and without PD. Therefore,
this asymmetry cannot be explained by PD and should be better studied in future studies.
Considering that PD mainly affects the elderly population, it may be that the hearing
loss observed in these patients is due to age. In the present study, there was a positive
correlation between the increase in hearing thresholds with increasing age; however,
it was observed that the slope of worsening was greater among patients with PD, which
suggests that PD may further aggravate the deterioration in hearing sensitivity in
the elderly. Furthermore, in this study, care was taken to match the age of the groups
to minimize the effects of this variable. Thus, considering that the patients in both
groups were the same age, it is apparent that the higher thresholds observed at high
frequencies were probably due to the deleterious effects of PD on the auditory system.
Despite the difference observed in the PTA, it is believed that this factor did not
influence the electrophysiological responses, since the click frequencies used to
record the ABR comprise frequencies between 2 and 4 kHz; likewise, for the CAEP with
tone burst, tones of 1 and 2 kHz were used, and for the speech stimulus, the spectrum
comprised the main speech frequencies, between 0.5 and 4 kHz.
About ABR no difference was found between the groups in either absolute or interpeak
latencies, which suggests that the neural conduction time was still intact in the
study population, similar to the CG individuals.
These findings corroborate previous studies that also did not find abnormal ABR latencies
in PD patients, suggesting that their auditory pathways in the brainstem were intact.[3]
[12]
[27]
However, unlike the present study, some authors reported slow electrophysiological
responses of the neural auditory pathways in the brainstem of PD patients in studies
that researched ABR.[24]
[30]
[31]
[32]
[33]
[34] The specialized literature reports that PD patients have abnormal acoustic information
processing in the brainstem, which can be visualized more frequently by the increase
in absolute latencies of waves III and V or latencies in interpeak intervals I-III
and I-V. Even though the literature usually describes an increase in these interpeak
latencies, the increase in interpeak interval I-III described in some studies cannot
be dismissed. It suggested that PD patients may have changes in the auditory pathway
in both the high and low brainstem.[24]
[30]
[31]
[32]
The specialized literature reports that PD incidence and prevalence increase progressively
after 60 years old.[23] In the present study, more than half of the patients were under 60 years old, as
their median age was 58 years. This occurred because younger and less impaired patients
had easier mobility and therefore were more willing to attend the place of examinations
to participate in the research – which was a limitation of this study. This factor
may explain the lack of abnormalities in the study population. Hence, further studies
should be developed, assessing subjects older than 60 years.
Furthermore, according to Ferraz,[22] the use of levodopa is one of the most effective and viable ways of restoring neurotransmission,
since levodopa penetrates the central nervous system and, through the action of the
dopa decarboxylase enzyme, is converted into dopamine, helping with motor symptoms.
Most articles on PD patients do not provide information on medication, which makes
this analysis difficult. In this study, all the patients started treatment with Prolopa
as soon as the diagnosis was confirmed. It is therefore believed that the use of the
drug from the beginning of the disease may have slowed down the progression of the
disease.
Similarly, the analysis of cortical processing speed showed no significant differences
between the groups. This result corroborates another study,[3] which assessed the CAEP P3 component in patients with a previous diagnosis of PD,
not finding latencies different from the normal limits for age. These authors also
found intact auditory pathways in PD patients.
PD patients had smaller amplitudes than individuals without PD. P1-N1 amplitude was
smaller with speech stimuli; P2-N2 amplitude was smaller with tone burst stimuli;
and N2-P3 amplitude was smaller with both stimuli.
These results corroborate other studies in the literature, which also demonstrated
decreased CAEP component amplitudes, particularly P3[35]
[36]
[37]
[38] and P2 amplitudes,[35] justifying that PD, its duration and severity, and attentional and cognitive disorders
can impair the processing/habituation of new acoustic stimuli. This would decrease
the number of responsive neurons and, consequently, wave amplitudes.
Although a previous study reported that PD patients had improved CAEP component amplitudes,
especially P3 (increased amplitude), after drug treatment with dopamine,[39] the present study did not find the same result, as PD patients, even with drug therapy,
still had smaller P2-N2 and N2-P3 amplitudes than individuals without PD. This corroborates
the previous report[35] that did not demonstrate improved P2 and P3 amplitudes with the medicines.
It is known that the amplitude of the electrophysiological response is related to
the number of neural fibers responsive to the stimulus. Thus, the present result suggests
a decrease in neurons for cortical processing of acoustic information in PD, regardless
of how long the disease has been present, the length of treatment, or the age of the
patient.
According to Galhardo et al.,[40] a review of the literature found that alterations in cognitive functions are present
in PD, some of which are significantly reflected in language. Studies linking cognitive
functions and PD have shown alterations in memory, language, visual-spatial ability,
and executive functions, and have characterized PD as dementia, which often manifests
its symptoms several years after the patient is diagnosed.
Studies with larger samples are needed, with a control group matched by gender and
age, and which can also carry out longitudinal monitoring of the peripheral and central
auditory pathways, correlating this with an assessment of the patient's clinical condition,
with different dosages of medication and with the side that presented worse motor
symptoms, since the absence of this data was a limitation of the present study.
It is known that CAEP is widely used and studied in various population profiles to
investigate possible alterations in the processing of auditory information, especially
in individuals with difficulties in behavioral tests due to various physical and cognitive
impairments. Although the recording of CAEP is of the utmost importance, the literature
consulted found few studies mentioning this assessment in individuals with PD.
Furthermore, the importance of otorhinolaryngological and speech and hearing assessment
of these patients is highlighted to monitor the audiological responses of this population.
Considering the results of this study together with those reported in the literature,
the importance of assessing hearing thresholds using PTA is highlighted. This can
be complemented by electrophysiological assessment using CAEP, which can help monitor
the intervention and the evolution of the clinical condition.
Such assessments are often neglected, as other signs and symptoms are more prominent
and become the main focus of attention for family members and professionals. However,
considering the higher incidence of hearing loss in PD patients and the decline in
peripheral hearing function, especially at higher frequencies, and central auditory
skills, it is important to advise patients and their families about the difficulties
of communicating due to hearing loss, as well as to advise them about strategies to
facilitate communication, since they have altered acoustic processing of information.
It is also worth highlighting the need for patients with hearing loss to be referred
for rehabilitation fitting assistive listening devices since the brainstem neural
response did not indicate any additional impairment for PD itself, which suggests
a prognosis of success in the rehabilitation process.
In conclusion, the results of this study showed a significantly higher threshold in
higher frequencies in patients with PD compared with patients without PD. The auditory
evoked responses showed no differences between the groups at the brainstem level,
however, the decrease in amplitude of all components in patients with PD in the CAEP,
suggests a deficit in both automatic and attentional cortical processing of acoustic
stimuli.
Bibliographical Record
Rafaela Valiengo de Souza, Liliane Aparecida Fagundes Silva, Carla Gentile Matas.
Auditory pathway abnormalities in Parkinson's disease. Arq Neuropsiquiatr 2025; 83:
s00451801844.
DOI: 10.1055/s-0045-1801844
