To evaluate the efficacy of vagus nerve stimulation in reducing neuropathic pain, symptom severity, electrophysiological studies and functional outcomes in patients with diabetic peripheral neuropathy.
Diabetes is a major global health problem affecting half a billion people worldwide. Its global prevalence is rising at an alarming rate and has been forecast to reach 700 million by 2045. Diabetic neuropathy is an important and common complication of diabetes, with a lifetime prevalence of more than 50% among people with diabetes. Diabetic neuropathy is an insidious and often disabling disease. Sensory symptoms are diverse, ranging from numbness to dysesthesia, pain and allodynia, and typically begin in the feet and spread proximally. Motor function can also be affected, preventing patients from engaging in activities of daily living. More recently, the considerable psychosocial and quality of life impacts of Diabetic neuropathy have been recognized. Furthermore, Diabetic neuropathy is a major risk factor for diabetic foot ulceration, which is an independent risk factor for lower limb amputation and mortality. The associated economic burden is high; the annual cost of managing Diabetic neuropathy exceeds billions of dollars in different countries . Current treatments are purely symptomatic and the most commonly recommended first-line agents include anticonvulsants (gabapentin and pregabalin), serotonin-noradrenaline reuptake inhibitors, and tricyclic antidepressants. Unfortunately, the therapeutic effect may offset by intolerable adverse effects. In this study, evidence for a potentially effective, non-pharmacological treatment option for Diabetic neuropathy will be provided. Positive findings could lead to improved management strategies for Diabetic neuropathy, reducing the burden of chronic pain and enhancing the overall well-being of diabetic patients. Vagus nerve stimulation has emerged as a potential intervention, offering promise in modulating neuropathic pain and improving functional outcomes. Furthermore, understanding the mechanisms through which transcutaneous Vagus nerve stimulation affects pain and nerve function may offer insights into broader applications of vagus nerve stimulation in other neuropathic conditions. This research could pave the way for future studies and clinical applications, positioning transcutaneous Vagus nerve stimulation as a valuable tool in the multidisciplinary approach to managing diabetic peripheral neuropathy.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
SINGLE
Enrollment
40
Flexibility exercises: Gentle passive progressive stretching and self-stretches for lower limbs selected muscles. Muscle strengthening (using a variety of modes as appropriate e.g. isometric, graded weight progression, open and close chain) Aerobic activity. Posture and balance training (for falls prevention and stability). Gait (can improve proprioception and gait pattern in patients with diabetic neuropathy
A sterile cotton ball will be placed in the ear after sterilizing the cavum conchae and cymba conchae with 75% alcohol. The stimulation electrode will be inserted into the cotton ball, and then the cotton ball will be fixed after ensuring that the stimulator does not touch the skin; the lead wire will be connected. The therapeutic apparatus will be turned on, and the parameters will be the same as those for the transcutaneous vagus nerve stimulation group. All patients will see the lights flashing when the stimulator is running
outpatient clinic, faculty of physical therapy, Horus university
Damietta, Egypt
RECRUITINGAssessment of pain intensity
The Neuropathic Pain Questionnaire-Short Form consists of 3 items assessing tingling pain, numbness, and increased pain due to touch. Patients rate each item on a scale from 0 (no pain) to 100 (worst imaginable pain/greatest intensity). translated version of Neuropathic Pain Questionnaire-Short Form is reliable and valid for use, to evaluate and diagnose neuropathic pain among Arabic-speaking patients
Time frame: at baseline and after 6 weeks.
assessment of sensory nerve action optential.
nerve conduction studies is one of the gold standard techniques for diagnosing diabetic poly neuropathy Neuropack Nihon Kohden, Model MEB- 9400, Serial number:00218. (Figure The device is used for electrodiagnosis of diabetic peripheral neuropathy. It is used to measure the sensory nerve action optential.
Time frame: at baseline and after 6 weeks.
assessment of sensory nerve conduction velocity of lower limb
nerve conduction studies is one of the gold standard techniques for diagnosing diabetic poly neuropathy Neuropack Nihon Kohden, Model MEB- 9400, Serial number:00218. (Figure The device is used for electrodiagnosis of diabetic peripheral neuropathy. It is used to measure the Sensory conduction velocity
Time frame: at baseline and after 6 weeks.
assessment of Sensory distal latency of lower limb
nerve conduction studies is one of the gold standard techniques for diagnosing diabetic poly neuropathy Neuropack Nihon Kohden, Model MEB- 9400, Serial number:00218. (Figure The device is used for electrodiagnosis of diabetic peripheral neuropathy. It is used to measure the Sensory distal latency
Time frame: at baseline and after 6 weeks.
assessment of lower limb functional scale
is a widely used patient-reported questionnaire with 20 items to assess difficulty with daily activities due to lower limb problems, scoring from 0 (extreme difficulty) to 4 (no difficulty) for each item, totaling 0-80 points, with higher scores indicating better function.
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The antihelix and cymba concha will be sterilized with 75% alcohol, and then the nerve stimulation electrode (the ear clips) will be attached. The positive pole of the lead will be connected to the antihelix, and the negative pole will be connected to the cymba concha The device parameters include a wave width of 0.2 ms ± 30% and a pulse frequency of 20 Hz. Current intensity will gradually increase to a tolerable level of 4-6 mA, with stimulation lasting for 30 minutes. Heart rates of participants will be monitored continuously, with stimulation ceasing if rates drop below 50 beats per minute. Both the study and control groups will receive the same conventional physical therapy program.
Time frame: at baseline and after 6 weeks.
assessment of motor nerve conduction velocity of lower limb
nerve conduction studies is one of the gold standard techniques for diagnosing diabetic poly neuropathy Neuropack Nihon Kohden, Model MEB- 9400, Serial number:00218. (Figure The device is used for electrodiagnosis of diabetic peripheral neuropathy. It is used to measure the motor conduction velocity.
Time frame: at baseline and after 6 weeks.
assessment of motor distal latency
nerve conduction studies is one of the gold standard techniques for diagnosing diabetic poly neuropathy Neuropack Nihon Kohden, Model MEB- 9400, Serial number:00218. (Figure The device is used for electrodiagnosis of diabetic peripheral neuropathy. It is used to measure the motor distal latency
Time frame: at baseline and after 6 weeks.
assessment of motor nerve action optential.
nerve conduction studies is one of the gold standard techniques for diagnosing diabetic poly neuropathy Neuropack Nihon Kohden, Model MEB- 9400, Serial number:00218. (Figure The device is used for electrodiagnosis of diabetic peripheral neuropathy. It is used to measure the motor nerve action optential.
Time frame: at baseline and after 6 weeks.