Active clinical trials for "Hallucinations"

Transcranial alternating current stimulation (tACS) can modulate and restore neural oscillations that are reduced in patients with psychiatric illnesses such as schizophrenia. Here, we performed a open-lable study of clinical trial in 30 schizophrenia patients with auditory hallucinations to show that tACS is effective for auditory hallucinations.

The potential of non-invasive Transcranial Magnetic Stimulation (TMS) as a therapeutic tool for improving schizophrenic symptoms, in particular resistant hallucinations, has been increasingly studied over the past decades. Several studies have demonstrated that low-frequency patterns of repetitive TMS (rTMS) applied over the left Temporoparietal Junction (TPJ), which are known to decrease local activity, significantly reduced auditory verbal hallucinations in schizophrenic patients. In spite of highly promising results, a high level of inter-individual variability in the responses to non-invasive brain stimulation treatments, and the fact that rTMS may prove ineffective in some patients, keep spurring controversy about the efficacy of these approaches (as currently performed), as well as about how to increase its efficacy and consistency. Accordingly, the objectives of this project are to better understand the impact of rTMS on the brains of patients with resistant auditory hallucinations, and to use this information not only to better understand this condition but to develop more efficient and consistent therapies. Thus, in this study, the investigators focus more specifically on resistant auditory hallucinations in schizophrenia, which is a common symptom in schizophrenic patients, and can be treated by rTMS. The investigators hypothesize that there is a baseline difference in anatomical and/or functional connectivity between responder and non-responder patients who are treated with rTMS. Therefore, our project will aim to determine some anatomical and functional connectivity markers of response to rTMS treatment in patients with schizophrenia

One hundred schizophrenia patients with auditory hallucinations will be recruited and randomized into group A and group B. Participants of group A will firstly receive a speech competition training for 2 weeks, and those in group B will firstly receive music intervention as placebo treatment. Specifically, speech competition training include voice competition training twice a day in adjunction with drug treatment, and the patients will be required to perform voice-related tasks according to the instruction. The reaction time, accuracy rate and the number of auditory hallucinations during the task will be recorded. On the other hand, the placebo treatment includes soothing music twice a day for a fixed period of time while patients receiving drug treatment. After 2 weeks, the interventions for group A and group B will be switch. Clinical symptoms will be evaluated using the auditory hallucinations rating scale, positive and negative syndrome scale, belief about voices questionnaire-revised at baseline, 2-week follow up and 4-week follow up. All the data will be analyzed with the Statistical Product and Service Solutions(SPSS) software.

the regions which are assumed to underlie the pathophysiology of schizophrenia, namely hypoactivity at the prefrontal level and pathological hyperactivity of the associative regions of the language located in the left temporoparietal region. to assess the effuicacy of tDCS on auditory hallucinations we perfor an randomized double blind versus placebo trial. In each arms patients will receive two tDCS sessions a day during two weeks

Auditory hallucinations are among the most distressing aspects of psychotic illness, and between 10 and 30% of people with hallucinations do not respond to antipsychotic medications. The authors have used computational modeling of behavior to link brain activity to development of auditory hallucinations in the hope of guiding new treatment development. The proposed studies take the first step toward individualized treatment approaches to hallucinations by attempting causal, pharmacological manipulation of relevant model parameters underlying these phenomena.

Schizophrenia is a severe neuropsychiatric disorder of the brain and is also one of the top ten disabling diseases. A common symptom of schizophrenia (SCZ) is hearing voices inside one's heads which others do not. Despite adequate medication, SCZ patients may continue to hear voices that are often rude or unfriendly and cause distress to the patients. Transcranial direct current stimulation (tDCS) is a safe, non-invasive brain stimulation technique that reduces 'hearing voices'. However, how and why add-on tDCS works is unclear. The brain can change itself in response to its environment; this is called neuroplasticity. tDCS possibly changes the brain's environment and/or enhances the brain's ability to respond favourably to its environment. This theory will be examined here by studying changes in brain functions before and after giving tDCS to schizophrenia patients hearing voices. The aim of this study is to examine the brain's neuroplasticity potential as the biological phenomena driving treatment effects of tDCS in Schizophrenia patients with clinically significant and persistent auditory verbal hallucinations. The secondary aims are to answer whether the brain's neuroplasticity potential in schizophrenia patients can predict their responsivity to tDCS treatment for auditory verbal hallucinations, and if chronicity of illness effects tDCS treatment response. The brain's neuroplasticity potential will be examined using neuroimaging and neurophysiological techniques that give information about the integrity of the brain's signal processing efficiency, the chemical concentration of certain bio-molecules within it, and how well different areas of the brain communicate with each other. With this information, the potential role of the brain's neuroplasticity potential in facilitating treatment effects of tDCS can be better understood. With this knowledge, it could be possible personalize tDCS treatment, profile tDCS responders and non-responders based on demographic and biological factors, and prescribe tDCS at the appropriate time within the illness course for maximal benefit to the SCZ patients.

The study is a randomised, assessor-blinded parallel-groups superiority clinical trial, allocating a total of 266 patients to either the experimental intervention or standard intervention. The participants will be randomised to either 12-weeks of virtual reality therapy or supportive counselling. All participants will be assessed at 12- and 24 weeks post baseline. A stratified block-randomisation with concealed randomisation sequence will be conducted. Independent assessors blinded to the treatment will evaluate outcome. Analysis of outcome will be carried out with the intention to treat principles.

This study uses a noninvasive technique called transcranial magnetic stimulation (TMS) to study how hallucinations work in schizophrenia. TMS is a noninvasive way of stimulating the brain, using a magnetic field to change activity in the brain. The magnetic field is produced by a coil that is held next to the scalp. In this study the investigators will be stimulating the brain to learn more about how TMS might improve these symptoms of schizophrenia.

Repetitive transcranial magnetic stimulation (rTMS) can alleviate persistent auditory verbal hallucinations (AVH) in schizophrenic patients, but the classical procedure with low-frequency stimulation for several weeks upon the left temporoparietal junction have shown modest therapeutic effects, and there is currently no robust predictive factor to the response of the treatment. In a previous multicentric, randomized, and double-blind controlled study, it has been demonstrated that a high-frequency rTMS over an anatomical target can rapidly affect AVHs. Moreover, an intensification of the classical procedure delivering 20-Hz rTMS over a 2-day period was used in addition to a personalized anatomical stimulation target and neuronavigation guidance. Besides the significant efficacy of the procedure, the efficacy was maximal at two weeks after the end of the treatment. In this project, the hypothesis is that the two-day cure could benefit from maintenance rTMS sessions every week for one month and then every two weeks for 3 months to provide an optimal strategy for a long-lasting AVH reduction. This has for now never been tested. Predictive factors to the response of the treatment are also investigated.

Auditory verbal hallucinations (AVH) are prevalent among patients with psychiatric disorders. Not only being highly stressful and functionally impairing, AVH often persist despite treatment. Recent attempts to treat AVH with add-on repetitive transcranial magnetic stimulation (rTMS) when targeting the temporoparietal junction (TPJ), a language node in the brain, has gained limited success. The aim of this investigation is to reduce AVH with rTMS using continous theta-burst stimulation over a novel target, the supplementary motor area (SMA), in participants with frequent AVH, while also assessing potential neurophysiological mechanisms underlying the symptom.