Effect of Transauricular Vagal Stimulation on Cardiac Function After Spinal Cord Injury

Gaziler Physical Medicine and Rehabilitation Education and Research Hospital30 enrolled

Overview

The aim of this study is to investigate the effect of transauricular vagal nerve stimulation (taVNS) on cardiac autonomic functions in patients with spinal cord injury (SCI).

Spinal cord injury impairs autonomic pathways and ultimately cardiovascular homeostasis. Spinal cord injury affects the autonomic system, resulting in impaired cardiac autonomic functions. This study is designed to evaluate the effect of transauricular vagal nerve stimulation (taVNS) on cardiac autonomic functions in patients with spinal cord injury.

Study Type

INTERVENTIONAL

Allocation

NON_RANDOMIZED

Purpose

BASIC_SCIENCE

Masking

SINGLE

Enrollment

Conditions

Spinal Cord Injury (SCI)

Interventions

Active Transauricular Vagus Nerve StimulationDEVICE

Active taVNS application was performed by stimulating a sterile acupuncture needle (0.25x25 mm) placed on the left ear cymba choncae with a stimulator. Active taVNS group received for 10 days, 30 minutes with a current intensity of 1 mA, pulse width of 200 µs, frequency of 25 Hz and biphasic sinusoidal waveform. In the sham group, stimulation was applied to the lobulus auriculae of the left ear (which is not innervated by the vagus nerve) using the same current intensity and duration as the active group.

Sham Transauricular Vagus Nerve StimulationDEVICE

Sham taVNS application was performed by stimulating a sterile acupuncture needle (0.25x25 mm) placed on the left lobulus auriculae of the left ear (which is not innervated by the vagus nerve) with a stimulator. Sham taVNS group received for 10 days, 30 minutes with a current intensity of 1 mA, pulse width of 200 µs, frequency of 25 Hz and biphasic sinusoidal waveform.

Eligibility

Sex: ALLMin age: 18 YearsMax age: 60 Years

Medical Language ↔ Plain English

Inclusion Criteria: 1. Aged between 18-60 2. Having a traumatic spinal cord injury 3. Cervical spinal cord injury patients with a history of autonomic dysreflexia 4. At least 6 months after the injury 5. Signing an informed consent form showing consent to participate in the study Exclusion Criteria: 1. Having a cardiac or neural pacemaker 2. Presence of pregnancy 3. Clinical coronary artery disease confirmed by invasive or coronary computed tomographic angiography 4. History of acute coronary syndrome (unstable angina, myocardial infarction) 5. Documented arrhythmia and/or use of antiarrhythmic drugs on ECG 6. Diagnosis of hypertension and use of antihypertensive drugs 7. Damaged skin lesion in the application area

Locations (1)

SBÜ Gaziler Fizik Tedavi ve Rehabilitasyon Eğitim ve Araştırma Hastanesi

Ankara, Turkey (Türkiye)

RECRUITING

Outcomes

Primary Outcomes

Low frequency/ High frequency (LF/HF)

Heart rate variability (HRV) is considered an indicator of neural control over the heart and is measured by analyzing the variations in NN intervals between consecutive R waves on an electrocardiogram (ECG).Frequency-domain analyses determine the power of fluctuations in heart rate signals within specific frequency bands. This analysis can be conducted using short-term Holter ECG recordings or data from 5-minute segments of a 24-hour Holter ECG. In our study, the short-term effects of taVNS on frequency domain HRV parameters will be evaluated using data obtained from 24-hour Holter ECG recordings on the pre-stimulation day (day 0) and day 11, and the acute effects will be assessed using data from 15-minute Holter recordings on day 1 and day 10.The LF/HF ratio is also one of the frequency-domain HRV parameters. LF/HF (ratio): low-to-high frequency power ratio The LF/HF ratio serves as an indicator of sympathovagal balance.

Time frame: At baseline (Day 0), Day 1, Day 10, and Day 11

Secondary Outcomes

Total Power

Frequency-domain heart rate variability (HRV) parameters include Total Power, Ultra Low Frequency (ULF), Very Low Frequency (VLF), Low Frequency (LF), High Frequency (HF), and the Low Frequency/High Frequency (LF/HF) ratio. Total power, represents the total power of all frequency components within the frequency spectrum. It is the sum of the very low frequency (VLF), low frequency (LF), and high frequency (HF) components. Total power is an important parameter for the overall evaluation of autonomic nervous system functions. In our study, the short-term effects of taVNS on total power will be evaluated using data obtained from 24-hour Holter ECG recordings on the pre-stimulation day (day 0) and on day 11. Total power (millisecond²: ms²): Variance of all NN(Normal-to-Normal) intervals (\<0.4 Hz)

Time frame: At baseline (Day 0) and Day 11

Ultra Low Frequency (ULF)

The ULF is also one of the frequency-domain HRV parameters. ULF represents the ultra low frequency. It indicates frequencies \<0.003 Hz. It does not directly reflect sympathetic or parasympathetic activity. In our study, the short-term effects of taVNS on ULF will be evaluated using data obtained from 24-hour Holter ECG recordings on the pre-stimulation day (day 0) and on day 11. ULF (ms²): ultra low frequency (\<0.003 Hz)

Data from ClinicalTrials.gov

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Time frame: At baseline (Day 0) and Day 11

Very Low Frequency (VLF)

The VLF is also one of the frequency-domain HRV parameters. VLF represents the very low frequency. It indicates frequencies between \<0.003 and 0.04 Hz. It has been associated with baroreceptor activity, thermoregulation, the renin-angiotensin system, and endothelial functions. In our study, the short-term effects of taVNS on VLF will be evaluated using data obtained from 24-hour Holter ECG recordings on the pre-stimulation day (day 0) and on day 11. VLF (ms²): very low frequency (frequencies between \<0.003 and 0.04 Hz)

Time frame: At baseline (Day 0) and Day 11

Low Frequency (LF)

The LF is also one of the frequency-domain HRV parameters. LF represents the low frequency. It indicates frequencies between 0.04 and 0.15 Hz. It reflects a combination of sympathetic and parasympathetic activity and is particularly associated with sympathetic activity in seated or standing positions. In our study, the short-term effects of taVNS on LF will be evaluated using data obtained from 24-hour Holter ECG recordings on the pre-stimulation day (day 0) and on day 11, while the acute effects will be assessed using data from 15-minute Holter recordings on day 1 and day 10. LF (ms2): low frequency power (0.04 to 0.15)

Time frame: At baseline (Day 0), Day 1, Day 10, and Day 11

High Frequency (HF)

The HF is also one of the frequency-domain HRV parameters. HF represents the high frequency. It indicates frequencies between 0.15 and 0.40 Hz. It reflects parasympathetic activity. An increase in HF indicates a high vagal tone. In our study, the short-term effects of taVNS on HF will be evaluated using data obtained from 24-hour Holter ECG recordings on the pre-stimulation day (day 0) and on day 11, while the acute effects will be assessed using data from 15-minute Holter recordings on day 1 and day 10. HF (ms²): high frequency power (0.15 to 0.40)

Time frame: At baseline (Day 0), Day 1, Day 10, and Day 11

SDNN: Standard Deviation of NN intervals

Time-domain HRV parameters are based on the analysis of the time intervals between normal heartbeats in 24-hour ECG recordings. In our study, the time-domain HRV parameters, including SDNN, SDNNi, SDANN, RMSSD, and pNN50, will be calculated from 24-hour Holter ECG recordings obtained before stimulation and after 10 days of stimulation. SDNN (ms): It is the standard deviation of all NN (interval between two adjacent R waves) intervals in the 24-hour ECG recording.

Time frame: At baseline (Day 0) and Day 11

SDNNi: Mean of the standard deviations of all NN intervals for all 5-minute segments

Time-domain HRV parameters are based on the analysis of the time intervals between normal heartbeats in 24-hour ECG recordings. In our study, the time-domain HRV parameters, including SDNN, SDNNi, SDANN, RMSSD, and pNN50, will be calculated from 24-hour Holter ECG recordings obtained before stimulation and after 10 days of stimulation. SDNN index (ms): It is the mean of the standard deviations of all NN intervals for all 5-minute segments within 24 hours.

Time frame: At baseline (Day 0) and Day 11

SDANN: Standard deviation of the averages of NN intervals in all 5-minute segments

Time-domain HRV parameters are based on the analysis of the time intervals between normal heartbeats in 24-hour ECG recordings. In our study, the time-domain HRV parameters, including SDNN, SDNNi, SDANN, RMSSD, and pNN50, will be calculated from 24-hour Holter ECG recordings obtained before stimulation and after 10 days of stimulation. SDANN (ms): The standard deviation of the mean of the normal RR intervals of the 5-minute segments in the 24-hour ECG recording.

Time frame: At baseline (Day 0) and Day 11

RMSSD: Root Mean Square of the Successive Differences

Time-domain HRV parameters are based on the analysis of the time intervals between normal heartbeats in 24-hour ECG recordings. In our study, the time-domain HRV parameters, including SDNN, SDNNi, SDANN, RMSSD, and pNN50, will be calculated from 24-hour Holter ECG recordings obtained before stimulation and after 10 days of stimulation. RMSDD (ms): is the root of the mean of squares of consecutive NN interval differences over the 24-hour recording.

Time frame: At baseline (Day 0) and Day 11

pNN50: Percentage of successive NN intervals that differ by more than 50 ms

Time-domain HRV parameters are based on the analysis of the time intervals between normal heartbeats in 24-hour ECG recordings. In our study, the time-domain HRV parameters, including SDNN, SDNNi, SDANN, RMSSD, and pNN50, will be calculated from 24-hour Holter ECG recordings obtained before stimulation and after 10 days of stimulation. pNN50 (%): The proportion of differences between consecutive NN intervals greater than 50 ms during the 24-hour recording

Time frame: At baseline (Day 0) and Day 11

Heart rate response to the tilt test

The Ewing's battery parameters (EBP) are the most popular among clinical autonomic test batteries. In our study, the tilt test, heart rate and blood pressure changes, respiratory heart rate changes, and the Valsalva maneuver selected from the EBP clinical autonomic tests. This test is used to evaluate the hemodynamic response to changes in body position. When moving from a supine to an upright position, venous pooling in the lower extremities leads to a decrease in stroke volume, resulting in a rapid increase in heart rate within the first 30 seconds. The normal response is characterized by a slight increase in heart rate (by 5-20 beats per minute), and the 30/15 ratio in the test is used to assess the initial phase of adaptation to standing. After tilting to an 80-degree upright position using a tilt table, the ratio of the longest R-R interval around the 30th beat to the shortest R-R interval around the 15th beat is calculated. A ratio lower than 1.04 is considered abnormal.

Time frame: At baseline (Day 0) and Day 11

Blood pressure response to the tilt test

It is another of the clinical autonomic tests in our study. This is another test used to evaluate the hemodynamic response to changes in body position. When moving from a supine to an upright position, blood moves to the lower extremities, reducing venous return and stroke volume. This test is performed to identify the presence of orthostatic hypotension (OH). After measuring the patient's baseline blood pressure in the supine position, the patient is brought to an 80-degree upright position using a tilt table and is kept in this position for 5 minutes. A decrease in systolic blood pressure by ≥20 mmHg or in diastolic blood pressure by ≥10 mmHg is considered a positive test result.

Time frame: At baseline (Day 0) and Day 11

Heart rate response to the Valsalva maneuver (Valsalva ratio)

It is another of the clinical autonomic tests in our study. The Valsalva maneuver is a test used to evaluate baroreceptor function and reflects parasympathetic activity. In this test, the patient lies in a supine position with the head elevated to 30 degrees, takes a deep breath, and then performs a forced expiration against a closed airway for 15 seconds, followed by a 45-second rest period of normal breathing. The ratio of the longest R-R interval to the shortest R-R interval is recorded. Three maneuvers are performed, and the average of the three ratios is calculated. A value below 1.2 indicates parasympathetic dysfunction.

Time frame: At baseline (Day 0) and Day 11

Respiratory heart rate variability

It is another of the clinical autonomic tests in our study. This test is based on the phenomenon of respiratory sinus arrhythmia, which becomes particularly evident when breathing at a rate of six breaths per minute. The test is used to assess the effect of the parasympathetic nervous system on heart rate. In this test, the patient lies in a supine position with the head elevated to 30 degrees and is instructed to breathe in and out six times over one minute, with a 5-second inspiration and a 5-second expiration cycle. The difference between the maximum and minimum heart rate within the one-minute cycle is measured. The cycle is repeated three times, and the average of the heart rate differences is calculated. A variability of less than 10 beats per minute indicates parasympathetic dysfunction.

Time frame: At baseline (Day 0) and Day 11