12 Clinical Trials for Auditory Stimulation
In this research study the investigators will use sleep headbands to measure brain rhythms and to improve their coordination across brain regions. The headbands will be worn at home for multiple nights. On some nights the headbands will play soft sounds at specific times during sleep. The investigators are interested in learning whether this timed auditory stimulation may be a strategy to improve the coordination of sleep rhythms across brain regions, improve network communication, and as a result, improve memory. The investigators will study 30 adults aged 18-45 with schizophrenia and 30 demographically matched healthy controls. Participants will first have a daytime MRI scan, during which they will complete a finger tapping motor sequence task (MST), followed by a week of sleep at home with a sleep headband. They will also do the MST at home on two of the nights. On the final day of the study, participants will return for a second MRI scan.
Stroke is among the leading causes of long-term disability worldwide. Post-stroke neuromotor impairments are heterogeneous, yet often result in reduced walking ability characterized by slow, asymmetric, and unstable gait patterns. Rhythmic Auditory Stimulation (RAS) is an emerging rehabilitation approach that leverages auditory-motor synchronization to retrain neuromotor control of walking. Indeed, walking with RAS can enhance walking rhythmicity, gait quality, and speed. RAS is a potentially valuable tool for walking rehabilitation after stroke; however, despite extensive research evidence on the overall benefits of RAS in people with chronic stroke, the notable variability in the walking characteristics of individual patients is likely to influence the effectiveness of RAS intervention, and thus requires study. Furthermore, beyond stroke-related factors, age-related changes may also affect how well individuals post-stroke respond to RAS. This study aims to recruit 24 individuals post-stroke and 20 older adults to evaluate the effects of stroke- and age-related neuromotor impairment on RAS intervention. Each study participant will complete two six-minute walk tests: one without RAS (baseline) and the other with RAS delivered using a metronome. The investigators hypothesize that post-stroke individuals will, on average, exhibit a positive response to RAS intervention (i.e., walk farther and with greater gait automaticity (i.e., reduced stride time variability), with the degree of response predicted by specific baseline characteristics. Furthermore, the investigators anticipate that these walking enhancements will be accompanied by improvements in gait biomechanics and a reduction in the metabolic cost of walking. The investigators hypothesize that older adults will exhibit similar, but attenuated, effects of RAS.
The purpose of this research is to identify differences in brain activity during sleep between health individuals and individuals with schizophrenia, schizophreniform, or schizoaffective disorder. This study will also investigate whether tones played during deep sleep can enhance specific features of sleep and whether enhancing such features is related to an improvement in cognitive performance.
In this study, the investigators will recruit young adults (ages 18-25 years) with elevated anxiety/depression symptoms and sleep disturbance. Participants will complete two overnights in a sleep lab. During one of the overnights, slow-wave activity will be enhanced by delivering sub-arousal auditory tones during slow-wave sleep using a headband device (Philips SmartSleep or Dreem 2). During the other overnight, tones will not be administered. Cognitive and emotional processes will be evaluated using behavioral task performance, self-report, and functional magnetic resonance imaging (fMRI). After the second overnight, participants will take the headband device home and wear it every night for approximately 2 weeks. For half of the participants, the headband will play tones every night and, for the other half, the headband will not play tones. Participants will then return for a final testing visit in which cognitive and emotional processes and anxiety/depression symptoms will be assessed using behavioral task performance and self-report.
The purpose of this study is to determine if brief sounds or tones presented within a restricted period of recovery sleep after a period of sleep deprivation will enhance restorative properties and improve performance during a subsequent period of wakefulness.
Crews of future long-duration exploration missions will have to cope with a wide range of stressors that present significant challenges for maintaining optimal performance. Crews will have to operate under conditions of high workload, reduced sleep and circadian dysregulation, limited sensory stimulation, confinement and extended separation from family and friends, and communication delays isolating them from real-time interaction with ground support, which may be particularly critical in the event of emergencies. These factors present significant risks to optimal cognitive/behavioral functioning and performance, across individuals and teams, and such challenges will only increase in criticality as human exploration moves beyond Earth's orbit to targets such as the Moon and Mars. To help mitigate these risks, Massachusetts General Hospital, along with collaborators at the Massachusetts Institute of Technology, will investigate a novel, personalized and scalable, closed-loop platform technology for on-board behavioral health management-one which adapts the local working environment to optimize performance based on biosensor feedback.
Every year, approximately 100,000 Veterans seek help at VA Audiology clinics for hearing and communication difficulties only to learn that they have normal hearing sensitivity. Unfortunately, there are very few established options to improve hearing and listening for these patients. To address this need, audiologists are increasingly prescribing hearing aids set to provide a small amount of amplification. Patients may benefit from the amplification or from modern hearing aid features such as noise reduction technology and the ability to stream sounds from a desired sound source directly to their ears thus reducing the background noise. This project will help to determine if prescribing hearing aids to patients without hearing loss is, in fact, beneficial and if so, why. It will also help to determine if some patients benefit more from hearing aids than others so that in the future, rehabilitation strategies can be better targeted toward individuals.
Participants will be asked to walk along with the metronome beats (RAS) during the participants' stimulation state (ON or OFF) for four minutes for each state. The researcher will collect the gait parameters (cadence, velocity, and stride length) of patients before, during, and after RAS in both DBS ON and OFF states. Using MDS-UPDRS, participants' gait patterns will be collected before and after RAS while both DBS is ON and OFF. Electrophysiological activity (local field potentials, LFPs) will be collected across all stages (pre, during, and post-RAS) of evaluation.
Caregivers of a person living with dementia (PLWD) experience high levels of prolonged stress that can lead to chronic problems with health, including increased risk of cardiovascular disease that is linked to autonomic dysregulation. Heart rate variability (HRV), measures of autonomic cardiovascular regulation, is decreased (worse) in caregivers of a person living with dementia. Autonomic function is linked to lateralization in the brain, and emerging neuromodulation methods that target lateralized signals in the brain, like Cereset (CR), may be able to improve heart rate variability. Therefore, this pilot study aims to test whether CR can improve HRV in caregivers of a person living with dementia experiencing stress, anxiety, or insomnia, as well as improve self-report measures of stress, sleep and caregiver burden.
Objective: Preliminary studies show that low intensity focused ultrasound (LIFU), a new type of non invasive brain stimulation (NIBS), may be able to reach deep structures of the brain involved with depression and anxiety, that remain inaccessible using current forms of NIBS with precision. In this study, the investigators will test if this technique can be used to change brain activity in areas that are connected to depression and anxiety symptoms. The primary objectives of this study are to test the safety and tolerability of LIFU, evaluate the feasibility of using LIFU to reduce brain activity, and evaluate the feasibility of simultaneous fMRI-LIFU. If the results of this study are positive, what the investigators learn will serve as a strong foundation for the future development of innovative treatments for a variety of psychiatric disorders. Research Procedures: 25 veterans will be recruited. Visits will take place at the VA Providence Healthcare System. During some visits, healthy and patient participants may undergo clinical and research neuroimaging, neuropsychological testing, complete questionnaires, and participate in clinical/neurological assessments. Healthy veterans will not receive LIFU and will only attend 2 study visits. Patients are expected to attend up to 8 visits over 6 weeks. However, some may require up to 6 extended follow-ups after visits 5 or 8, in which case they would attend a total of 11 or 14 visits over 6 months. Two patient visits will include the LIFU application, following FDA safety guidelines. Patients will be assigned either to an experiment in which LIFU stimulation will be delivered immediately prior to a task or to an experiment in which stimulation will be delivered during the task. Within each experiment, patients will be assigned to first receive either LIFU stimulation to the study target or anatomical control. Study staff, but not participants will know which location is being targeted in case safety concerns arise. Safety assessments will be conducted at follow-up visits. A clinician will be available during LIFU administration /follow-up visits. Assuming no injury or other concerns are present, patients will then repeat this process again, receiving stimulation targeting other brain area not previously selected.
Hallucinations are a core diagnostic feature of psychotic disorders. They involve different sensory modalities, including auditory, visual, olfactory, tactile, and gustatory hallucinations, among others. Hallucinations occur in multiple different neurological and psychiatric illnesses and can be refractory to existing treatments. Auditory hallucinations and visual hallucinations are found across diagnostic categories of psychotic disorders (schizophrenia, schizoaffective, bipolar disorder). Despite visual hallucinations being approximately half as frequent as auditory hallucinations, they almost always co-occur with auditory hallucinations, and are linked to a more severe psychopathological profile. Auditory and visual hallucinations at baseline also predict higher disability, risk of relapse and duration of psychosis after 1 and 2 years, especially when they occur in combination. Using a newly validated technique termed lesion network mapping, researchers demonstrated that focal brain lesions connected to the right superior temporal sulcus (rSTS) plays a causal role in the development of hallucinations. The rSTS receives convergent somatosensory, auditory, and visual inputs, and is regarded as a site for multimodal sensory integration. Here the investigators aim to answer the question whether noninvasive brain stimulation when optimally targeted to the rSTS can improve brain activity, sensory integration, and hallucinations.
Misophonia, the inability to tolerate certain repetitive distressing sounds that are common, is gaining, recognition as an impairing condition. It is not a well-understood condition and there are no known treatments. The purpose of this study is to test a new misophonia intervention that uses emotion regulation strategies and different types of brain stimulation on misophonic distress. This study will examine changes in brain activity during presentation and regulation of misophonic versus distressing sounds. The study team plans to alter activity in a key area of the brain responsible for emotion regulation circuitry over 4 sessions with the goal to test if this intervention helps misophonic distress. Sixty adult participants with moderate to severe misophonia will be recruited and taught an emotion regulation skill and randomly assigned to receive one of two types of repetitive transcranial magnetic stimulation (rTMS). The study includes 9-10 visits: the remote screening visit(s), the initial MRI, the four neurostimulation sessions, the follow-up MRI, and two additional remote 1- and 3-month follow-up visits.