Active clinical trials for "Tinnitus"

Ultrasound Guided Versus Non-Guided Prolotherapy for Treatment of Internal Derangement of Temporomandibular joint. Rationale for conducting the research: The most critical cause for guided prolotherapy is to specify the accurate location of glenoid fossa and the disc space while prolotherapy procedure, and to adjust the needle insertion to according to articular eminence, mandibular condyle, and intra-articular space as anatomical variations. The vibration of ultrasound waves generates a heat so there is a thermal effective for prolotherapy effusion in the TMJ space.

Tinnitus is the perception of sound or noise in the absence of an external physical source. It is a highly prevalent condition and for a high percentage of patients, there is no satisfying treatment modality. For some people, tinnitus has a very severe impact on quality of life, leading to incapacity for work and sometimes even suicidality. The auditory brainstem implant (ABI) is an implant indicated for the restoration of hearing in patients with an hypo-, or aplasia of the cochlear nerve or with dysfunction of the nerve caused by tumor growth in neurofibromatosis type II. It has been shown that the standard intended effect of an ABI has reduction of tinnitus as a welcome side effect in about 66% of the cases. This is in analogy with the promising effect of a cochlear implant (CI) as a treatment for patients with unilateral tinnitus. In this study, the effect of an ABI on severely invalidating, unilateral, intractable tinnitus will be investigated. The ABI may have an advantage over the CI as tinnitus treatment, because CI-implantation leads to destruction of inner ear structures, leading to profound deafness, while an ABI is presumed to not damage anatomical structures. This is the first study to implant an ABI for the primary aim of tinnitus reduction in an intervention pilot study. In total 10 patients with unilateral, intractable tinnitus and severe hearing loss in the ipsilateral ear, will be implanted with the ABI.

This study evaluates the therapeutic effects of Etanercept (Enbrel) on the treatment of blast/noise induced tinnitus in adults. Half of the participants will receive 2 x 25mg/ Entanercept injections, and the other half will receive placebo injections.

Tinnitus, or ringing in the ears, affects 10% to 30% of the population. Of those, 20% have tinnitus bothersome enough to seek medical attention. In many people, tinnitus can significantly affect the quality of life. At this point in time, there is no effective treatment or cure available for tinnitus. It has been found that electrical stimulation of the inner ear can reduce and in some cases eliminate tinnitus. The purpose of this research is to investigate both acoustic and electrical stimulation of the inner ear as a possible treatment of tinnitus. In both acoustic and electrical testing conditions, the subjects will be instructed to be familiar with a 0-10 ranking scale of loudness. In acoustic testing, the stimulus will be presented through headphones in a noiseless environment, and the subject will be asked to report on the loudness of the presented sound and the level of the tinnitus at 20-second intervals. If the subject cannot perceive the presence of the tinnitus, a value of zero will be assigned. A typical sound will be presented for 3 to 6 minutes. Loudness will be reported for 1 to 4 minutes after stimulus offset to measure the presence and duration of residual inhibition. Electrical stimulation will be delivered to the inner ear in three ways, 1. using a cochlear implant (implant placed in the inner ear to replace hearing function), 2. Using an electrode placed in the ear canal, and 3. using a small needle inserted through the ear drum. Various electrical signals will be used to evaluate the reduction in the tinnitus perception by the subject. The subjects will rate the loudness of the tinnitus before, during, and after the electrical signal. Surveys will be used to evaluate the tinnitus loudness and the quality of life of the subjects. Hearing tests will be used before and after the procedures. The long term goal of this research is to develop a device to treat tinnitus in people who can hear and to develop programs for cochlear implants that help treat tinnitus in deaf people.

Tinnitus represents one of the most common and distressing otologic problems, and it causes various somatic and psychological disorders that interfere with the quality of life. It is well-understood that many factors, such as poor education, lower income, or occupational, and recreational activity associated with high noise exposure, influences the prevalence and risk of tinnitus. Although the economic and emotional impact of tinnitus is large, there is currently no FDA-approved medication to treat this condition. However, there are pharmacological options to address the stress, anxiety, and depression that are caused by tinnitus. In this project, we intend to use medications for patients with tinnitus in order to decrease the impact of tinnitus on their daily life and activities.

This pilot study aims at evaluating the effectiveness of the treatment of unilateral or bilateral, non-pulsatile, disabling, tinnitus, without vestibular dysfunction, using Deep Brain Stimulation (DBS) of the parieto-insular right operculum 3 (OP3) in a cross-over, double study design.

The primary objective of this study is to evaluate the safety and tolerability of brexanolone in participants with tinnitus following a single 6-hour continuous intravenous (IV) infusion.

Abnormal activity in the central auditory system is the cause of subjective experience of tinnitus. Electrical stimulation can inhibit the abnormal activity of auditory related neurons in patients with tinnitus. In recent years, the application of electrical stimulation in the treatment of tinnitus is a hot research topic, and has made some progress. However, its treatment is still in the discussion stage, and there is no best scheme suitable for clinical practice. At present, scholars have found that cochlear electrode stimulation can inhibit tinnitus, but its mechanism is not clear. It is difficult to locate the origin of tinnitus, and the location of electrode stimulation and stimulation parameters still need to be further optimized. Because the implanted part of the cochlear implant contains magnets, the patients cannot perform functional MRI. However, the prevalence of tinnitus in this group is very high (67.0~100.0%, with an average of 80.0%), so it is of great value and significance to study the effect of tinnitus treatment in such patients. In this study, a new clinical electroencephalogram (EEG) technique was used to make up for the lack of MRI imaging in patients with electrode implantation. EEG analyzes the functional connection of different brain regions through EEG test electrodes, uses the traceability function of EEG software to locate the location of tinnitus, analyzes the process of tinnitus inhibition by electrical stimulation, and explains the mechanism of tinnitus inhibition by electrical stimulation from a new perspective.

nowadays, published literature affirms strong relation between tinnitus, obesity, and high lipids of blood.

Tinnitus is the perception of a sound in the absence of an audible source. Currently up to 15% of the general population suffers chronically from tinnitus. The most severe degree of tinnitus ís experienced by 2.4% of the population and is associated with insomnia, depression; anxiety and even suicide. Up to date there is no effective standard therapy. Current therapies mostly focus on treating the distress caused by tinnitus instead of reducing the actual phantom sound. Nevertheless, many patients do not benefit from the current approaches and become severe and chronic tinnitus sufferers. In these patients neuromodulation-based treatments can be a promising option. Tinnitus perception is associated with many complex changes in several different brain structures. The general accepted hypothesis is that neuronal changes occur in both auditory and non-auditory brain structures, most often as a compensating mechanism on reduced input from the auditory nerve caused by cochlear hair cell damage. These central neuronal changes include an increase in spontaneous firing rate, synchronized activity, bursting activity and tonotopic reorganization. In high-frequency deep brain stimulation (DBS) a reversible lesion-like effect is mimicked. From findings in Parkinson's disease patients who also had tinnitus and were treated with DBS, it is known that stimulation can alter or even completely diminish perception of tinnitus. It can be expected that modulation of specific structures within the complex tinnitus pathways can disrupt pathological neuronal activity and thereby alter tinnitus perception or distress caused by this phantom sensation. The investigators found in animal studies that DBS in the central auditory pathway can indeed significantly decrease tinnitus-like behavior. In a questionnaire study the investigators found that around one-fifth of the patients would be reasonably willing to accept invasive treatments and one-fifth would be fully willing to undergo invasive treatment like DBS. Based on preclinical studies and human case studies, the investigators expect that DBS of the central auditory pathway will inhibit tinnitus perception and distress caused by this phantom sensation. Based on studies performed within Maastricht University Medical Center (MUMC), the investigators selected the medial geniculate body of the thalamus (MGB) as the most potential target to treat tinnitus with DBS.