Background: To verify the efficacy of caloric vestibular stimulation in patients with peripheral vestibular dysfunction after cerebral hypertensive crisis. Methods: Enrolled in the study were 60 patients with peripheral vestibular dysfunction caused by a cerebral hypertensive crisis, docu-mented by vestibulometry. Thirty patients underwent standard treatment plus caloric vestibular stimulation, and 30 control group patients received standard treatment alone. Results: After the two-week treatment course, the sensation of vertigo was observed in 40.0% ± 8.9% of treatment group patients compared with 80.0% ± 7.3% of control group patients (t = 3.46; p < 0.001). Spontaneous vestibular somatic reactions were found in 46.7% ± 9.1% of the study treatment group in contrast to 86.7% ± 6.2% of the control group (t = 3.63; p < 0.001). Spontaneous nystagmus was seen in 40.0% ± 8.9% of treatment group patients compared with 93.3% ± 4.6% of control subjects (t = 5.31; p < 0.001). Spontaneous vestibular vegetative reactions were observed in 33.3% ± 8.6% of patients receiving study treatment in contrast to 93.3% ± 4.6% of control group patients (t = 6.16; p < 0.001). Also, 53.3% ± 9.1% of study treatment group patients showed asymmetry of labyrinths compared with 86.7% ± 6.2% of patients from the control group (t = 3.03; p < 0.001). Conclusion: Caloric vestibular stimulation was shown to be an effective treatment for peripheral vestibular dysfunction in patients with cerebral hypertensive crisis. During the 14-day treatment of cerebral hypertensive crisis, complete labyrinthine function recovery occurred in 46.7% of treatment group patients who underwent caloric vestibular stimulation as opposed to 13.3% of control group patients who received standard treatment alone.
Cerebral hypertensive crisis constitutes one of the most frequent cerebrovascular diseases, comprises 13% - 15% of all acute brain vascular disorders, and is found in two-thirds of patients with transient vascular disorders of the brain. Patients affected by it most often complain of headache accompanied by nausea, vomiting, and episodes of unconsciousness. Vestibular dysfunction in general is one of the earliest and most frequent manifestations, having different cerebrovascular pathologies. The early phylogenetic formation of the vestibular system makes it highly sensitive to external and pathogenic influences. Hearing impairment has also been observed in such patients. The inner ear consists of the hearing organ, the cochlea, which is joined topographically, anatomically, and functionally to the vestibular apparatus (vestibule and semicircular channels) [
Caloric vestibular stimulation (CVS) has traditionally been used as a tool for neurological diagnosis. It is a routine diagnostic technique applied in the neurological assessment of vestibular function and brain death [
The aim of this randomized, controlled study was to verify the efficacy of CVS in patients with peripheral vestibular dysfunction after cerebral hypertensive crisis.
Sixty patients with peripheral vestibular dysfunction after cerebral hypertensive crisis were randomized into two patient groups. The study treatment group results were compared with those of the control group. Patients received inpatient treatment with CVS in the Otorhinolaryngology Department and the Neurology Department of the National O.O. Bogomolets Medical University, Ukraine. The trial study was provided as a part of scientific work of the Otorhinolaryngology Department of Bogomolets National Medical University, registration number 0113U007334. The study took place from March 2012 to September 2013 and was approved by the local ethics committee. Each participant signed an informed consent form.
The study treatment group comprised 30 patients aged 29 to 57 years, the average age being 47 ± 1 years. Sixteen patients were female and 14 were male. The average duration of disease prior to study enrollment was 6 ± 1 days. The control group included 30 patients who were 29 to 59 years old, the average age being 47 ± 2 years. Nineteen patients were female and 11 were male. The average duration of disease prior to study enrollment was 6 ± 1 days. All patients were subjected to an obligatory general clinical examination which included endoscopy. Only patients with no history of pathological changes to otorhinolaryngological organs were included in the investigation. All examined patients exhibited increased arterial pressure during cerebral hypertensive crisis, with an average systolic arterial pressure level of 169 ± 6 mm Hg. Neurologists applied the following brain hemodynamic examination methods to determine the main diagnosis of cerebral hypertensive crisis: rheoencephalography, electroencephalography, transcranial Doppler ultrasonography, nuclear magnetic resonance (NMR) imaging of the brain, and brain spiral computer tomography.
Vestibulometric examinations were conducted in the Otorhinolaryngology Department at the National O.O. Bogomolets Medical University, Ukraine. Such examinations were repeated in the study treatment group of 30 patients two weeks after beginning CVS. Patients from both groups also received standard medical therapy for cerebral hypertensive crisis. The study treatment group results were compared with the results of 30 control group patients who did not receive CVS, but instead underwent only standard therapy for cerebral hypertensive crisis.
The CVS method included external ear channel irrigation using 60 ml of cold water at 25˚C for 10 s once daily over a course of 10 days.
Instrumental methods, i.e., the methods of vestibular examination, consisted of: walking tests (walking along a path; flanking walk), Fukuda writing test, Fukuda stepping test, past-pointing test, finger-nose test, cephalography (the method of evaluating the quantity evaluation of balance, when a stationary apparatus is fixed at the patient’s head and registers imbalance by calculating the cephalography index (the higher the index, the higher the level of imbalance)), Barany’s rotating chair test, vestibular illusion of counterrotation test, caloric test, and electronystagmography (the study of spontaneous, positional nystagmus).
The statistical analysis was carried out using the statistics program SPSS 16.0. The results for the sensation of vertigo, spontaneous vestibular somatic reactions, spontaneous nystagmus, spontaneous vestibular vegetative reactions, and asymmetry of labyrinths were described using the following statistical parameters: mean, standard deviation, confidence interval 95%, median, 25th and 75th percentiles. The difference in the outcomes between the treatment groups was found to be significant using the Student’s t-test (p < 0.01). The regressive analysis of the X and Y variables resulted in the linear dependency Y ~ B*X, where X and Y are the certain variables and B is the certain real number.
Before treatment, the sensation of vertigo was recorded in 100% of the examined patients from both groups. Patients described the sensation of objects rotating around them or the sensation of their body rotating in one definite direction. During the antirotative vestibular illusion test, the average reaction period lasted 24 ± 3 s in the study treatment group and 25 ± 4 s in the control group. Under the vestibular illusion of counterrotation test, reaction period asymmetry was registered in 14 (46.6%) patients from the study treatment group and 15 (50.0%) from the control group.
The sensation of vertigo was noted after treatment in 12 (40.0%) patients from the study treatment group compared to 24 (80.0%) patients from the control group. The average reaction period under the antirotative vestibular illusion test lasted 18 ± 10 s in the study treatment group and 23 ± 9 s in the control group. Reaction period asymmetry under the vestibular illusion of counterrotation test persisted in 5 (16.6%) patients from the study treatment group and 10 (33.3%) from the control group.
Prior to treatment, all patients from both groups exhibited balance disturbances in the walking tests, Fukuda writing test, Fukuda stepping test, past-pointing test, finger-nose test, and in cephalography. During the Fukuda stepping test, imbalance manifesting as rectilinear body movement was observed in all patients, with the average value being 149 ± 14 cm in the study treatment group and 146 ± 16 cm in the control group. Imbalance in the form of body rotation was observed in all patients, with an average value of 92˚ ± 12˚ in the study treatment group and 91˚ ± 14˚ in the control group.
Spontaneous vestibular somatic reactions were observed in 14 (46.7%) patients after undergoing CVS as compared to 26 (86.7%) control group patients. The average pathologic deviation obtained in the Fukuda stepping test was 112 ± 12 cm in the study treatment group and 123 ± 12 cm in the control group. During this test, an abnormal body rotation angle was observed in the patients, with an average value of 45˚ ± 14˚ in the study treatment group and 62˚ ± 12˚ in the control group.
Before treatment, all patients from both groups showed significant vestibular somatic reactions, such as the appearance of spontaneous, positional nystagmus, which were recorded via electronystagmography. Visually determined spontaneous nystagmus was observed in 29 (96.6%) patients from the study treatment group. In 20 (66.6%) of these patients, it was horizontal and of the first stage of intensity, and in 9 (30.0%) patients the nystagmus was horizontal, of middle-level amplitude, and of the second stage of intensity. After conducting electronystagmography, spontaneous nystagmus was diagnosed in all patients from both groups. Positional nystagmus was also documented in all patients. Positional nystagmus combined with nonpermanent dizziness affected by moving or shaking the head was registered in 6 (20.0%) of the patients receiving study treatment. Irregular, unstable positional nystagmus was recorded in 24 (80.0%) study treatment patients.
Spontaneous and positional nystagmus was observed in 12 (40.0%) patients receiving study treatment compared to 28 (93.3%) control group patients after treatment.
Vestibular vegetative reactions were observed before treatment in all patients from both groups in all irritative tests: Barany’s rotating chair test, vestibular illusion of counterrotation test, and caloric test. Spontaneous vestibular vegetative reactions were observed in 10 (33.3%) patients from the study treatment group after applying CVS and in 28 (93.3%) patients from the control group.
Before treatment, the reaction period asymmetry under Barany’s test was documented in 15 (50.0%) patients from the study treatment group, with an average reaction period of 9 ± 1 s, and in 15 (50.0%) control group patients, with an average reaction period of 8 ± 1 s. After treatment, the reaction period asymmetry under Barany’s test was registered in 8 (26.6%) patients from the study treatment group, with the average duration of Barany’s reaction period being 16 ± 1 s, and in 12 (50.0%) patients from the control group, with the average duration of Barany’s reaction period being 12 ± 1 s.
The most informative method of determining inner ear function was the caloric reflex test (i.e., CVS) because it permitted examinations of the ears separately. Patients in the study treatment group received cold (25˚C) and warm (39˚C) irrigation courses of the external ear channels.
During the experimental nystagmus examination under load reactions in the caloric reflex test (i.e., CVS), asymmetry of the labyrinths was shown to exist in all cases before treatment. Hyperreflection of the labyrinths was observed in 10 (33.3%) patients from the study treatment group and in 9 (30.0%) patients from the control group. Hyporeflection was seen in the other 20 (66.6%) study treatment patients and in 21 (70.0%) control group patients.
Labyrinthine function returned to normal after CVS. Asymmetry of the labyrinths was observed in 16 (53.3%) patients in the study treatment group and in 26 (86.7%) patients in the control group. Hyperreflection of the labyrinths was present in 5 (16.7%) patients from the study treatment group and in 8 (26.7%) patients from the control group. Hyporeflection was seen in another 11 (36.7%) treatment group patients and in 18 (60.0%) control group patients.
In patients with vestibular dysfunction after cerebral hypertensive crisis, the results from the vestibular apparatus function examination of patients who had undergone two weeks of CVS showed significant improvement in the indices of all vestibulometric tests compared to the results of the control group patients.
The sensation of vertigo, spontaneous vestibular somatic reactions, spontaneous nystagmus, spontaneous vestibular vegetative reactions, and asymmetry of the labyrinths were the main indices of vestibulometry, which was used to determine the vestibular function of the labyrinths (
Thus, the sensation of vertigo was observed in 40.0% ± 8.9% of patients from the study treatment group compared to 80.0% ± 7.3% of patients from the control group (t = 3.46; t > 3; p ≤ 0.001). Spontaneous vestibular somatic reactions were reported in 46.7% ± 9.1% of patients from the study treatment group compared to 86.7% ± 6.2% of control group patients (t = 3.63; t > 3; p ≤ 0.001). Spontaneous nystagmus was documented in 40.0% ± 8.9% of patients from the study treatment group in comparison to 93.3% ± 4.6% of control group patients (t = 5.31; t > 3; p ≤ 0.001). Spontaneous vestibular vegetative reactions were seen in 33.3% ± 8.6% of patients receiving the study treatment in contrast to 93.3% ± 4.6% of patients from the control group (t = 6.16; t > 3; p ≤ 0.001). Asymmetry of the labyrinths was reported in 53.3% ± 9.1% of patients from the study treatment group compared to 86.7% ± 6.2% of patients from the control group (t = 3.03; t > 3; p ≤ 0.001). Thus, an absence of inner ear dysfunction was documented in 46.7% ± 9.1% of study treatment group patients compared to 13.3% ± 6.2% of control group patients (t = 3.03; t > 3; p ≤ 0.001).
After analyzing the results, we agree with other authors about the effects of CVS in a wide range of contexts in
Indices of vestibulometry | Percentage of patients with disorder, P | Disparity P1 - P2* | p1* | p2* | t* | p-value | |
---|---|---|---|---|---|---|---|
Study treatment group | Control group | ||||||
Sensation of vertigo | 40.0 | 80.0 | 40.0 | 8.9 | 7.3 | 3.46 | <0.001 |
Spontaneous vestibular somatic reactions | 46.7 | 86.7 | 40.0 | 9.1 | 6.2 | 3.63 | <0.001 |
Spontaneous nystagmus | 40.0 | 93.3 | 53.3 | 8.9 | 4.6 | 5.31 | <0.001 |
Spontaneous vestibular vegetative reactions | 33.3 | 93.3 | 60.0 | 8.6 | 4.6 | 6.16 | <0.001 |
Asymmetry of labyrinths | 53.3 | 86.7 | 33.4 | 9.1 | 6.2 | 3.03 | <0.001 |
Absence of inner ear dysfunction | 46.7 | 13.3 | 33.4 | 9.1 | 6.2 | 3.03 | <0.001 |
*P1: Percentage of study treatment group of patients with vestibular dysfunction in cerebral hypertensive crisis after the two-week application of CVS. P2: Percentage of control group of patients with vestibular dysfunction in cerebral hypertensive crisis after the two-week application of standard therapy. p1: Mean error of P1. p2: Mean error of P2. t: Reliability criterion.
the cognitive and clinical neurosciences [
The mechanism by which peripheral labyrinthine function improved after CVS may be explained as the result of the activation of the entire vestibular apparatus, i.e., the inverse response of the brain to the irritated peripheral receptors. It seems reasonable to presume that vestibular stimulation leads to the interaction between the somatosensory system and the vestibular apparatus [
Caloric vestibular stimulation was observed to be an effective treatment for peripheral vestibular dysfunction in patients with cerebral hypertensive crisis. This treatment method resulted in the complete recovery of labyrinthine function in almost half of all patients (46.7%) who received it. In contrast, only 4 out of 30 (13.3%) patients who underwent standard therapy experienced complete recovery of labyrinthine function. Our study results suggest that caloric vestibular stimulation should be prescribed to all patients with peripheral vestibular dysfunction after cerebral hypertensive crisis.
We would like to thank Gena Kittel and Marie-Josefine Joisten for their editorial assistance.