Novel ultrasound neuromodulation therapy with transcranial pulse stimulation (TPS) in Parkinson's disease: a first retrospective analysis.

BACKGROUND: Transcranial Pulse Stimulation (TPS) has been recently introduced as a novel ultrasound neuromodulation therapy with the potential to stimulate the human brain in a focal and targeted manner. Here, we present a first retrospective analysis of TPS as an add-on therapy for Parkinson's disease (PD), focusing on feasibility, safety, and clinical effects. We also discuss the placebo response in non-invasive brain stimulation studies as an important context. METHODS: This retrospective clinical data analysis included 20 PD patients who received ten sessions of TPS intervention focused on the individual motor network. Safety evaluations were conducted throughout the intervention period. We analyzed changes in motor symptoms before and after TPS treatment using Unified Parkinson's Disease Rating Scale part III (UPDRS-III). RESULTS: We found significant improvement in UPDRS-III scores after treatment compared to baseline (pre-TPS: 16.70 ± 8.85, post-TPS: 12.95 ± 8.55; p < 0.001; Cohen's d = 1.38). Adverse events monitoring revealed no major side effects. CONCLUSION: These preliminary findings suggest that TPS can further improve motor symptoms in PD patients already on optimized standard therapy. Findings have to be evaluated in context with the current literature on placebo effects.

Safety of Clinical Ultrasound Neuromodulation.

Transcranial ultrasound holds much potential as a safe, non-invasive modality for navigated neuromodulation, with low-intensity focused ultrasound (FUS) and transcranial pulse stimulation (TPS) representing the two main modalities. While neuroscientific and preclinical applications have received much interest, clinical applications are still relatively scarce. For safety considerations, the current literature is largely based on guidelines for ultrasound imaging that uses various physical parameters to describe the ultrasound pulse form and expected bioeffects. However, the safety situation for neuromodulation is inherently different. This article provides an overview of relevant ultrasound parameters with a focus on bioeffects relevant for safe clinical applications. Further, a retrospective analysis of safety data for clinical TPS applications in patients is presented.

Functional Specificity of TPS Brain Stimulation Effects in Patients with Alzheimer's Disease: A Follow-up fMRI Analysis.

INTRODUCTION: Transcranial pulse stimulation (TPS) has been recently introduced as a novel clinical brain stimulation technique based on highly focused ultrasound pressure pulses. In a first pilot study on clinical effects of navigated and focused ultrasound neuromodulation, a dichotomy of functional effects was found: patients with Alzheimer's disease improved cognition and language but deteriorated with visuo-constructive functions. METHODS: We analyzed changes in functional connectivity measured with functional magnetic resonance imaging (fMRI) using graph analysis of a visuo-constructive network in 18 patients with Alzheimer's disease. We calculated the network's global efficiency and tested for correlation with visuo-constructive test scores to explain this dichotomy. RESULTS: Important visuo-constructive network nodes were not stimulated in the pilot setting and correspondingly global efficiency of a visuo-constructive network was decreased after TPS therapy, compatible with a natural progress of the disease. A correlation between visuo-constructive scores and changes in global efficiency was found. CONCLUSION: Results argue for a high functional specificity of ultrasound-based neuromodulation with TPS.

Over the last decade, there has been growing interest in ultrasound-based non-invasive brain stimulation techniques in neuroscience and as a potential therapy for disorders of the brain. Transcranial pulse stimulation (TPS) has been introduced as an innovative neuromodulation technique, applying ultrashort pressure pulses through the skull into neural tissue with 3D navigation in real time. In the first clinical pilot study, patients suffering from Alzheimer's disease showed an increase in memory and language functions for up to 3 months after TPS therapy. However, visuo-constructive capacities (e.g., copying a geometrical figure) worsened. Notably, brain areas relevant for such processes had been left out during stimulation. This begged the question whether the brain areas that were targeted for brain stimulation as well as functional changes could explain this diverse response pattern. We therefore analyzed functional magnetic resonance data from patients. Specifically, we compared graph theoretical functional connectivity measures in a visuo-constructive network before and after TPS therapy. We found a decrease in connectivity in a central network node, which also correlated with visuo-constructive test scores. This deterioration is likely associated with normal disease progression. Together with the already reported improvement in global cognitive functions, these results argue for a functional specific effect of TPS.

Transcranial pulse stimulation (TPS) improves depression in AD patients on state-of-the-art treatment.

INTRODUCTION: Ultrasound-based brain stimulation is a novel, non-invasive therapeutic approach to precisely target regions of interest. Data from a first clinical trial of patients with Alzheimer's disease (AD) receiving 2-4 weeks transcranial pulse stimulation (TPS) have shown memory and cognitive improvements for up to 3 months, despite ongoing state-of-the-art treatment. Importantly, depressive symptoms also improved. METHODS: We analyzed changes in Beck Depression Inventory (BDI-II) and functional connectivity (FC) changes with functional magnetic resonance imaging in 18 AD patients. RESULTS: We found significant improvement in BDI-II after TPS therapy. FC analysis showed a normalization of the FC between the salience network (right anterior insula) and the ventromedial network (left frontal orbital cortex). DISCUSSION: Stimulation of areas related to depression (including extended dorsolateral prefrontal cortex) appears to alleviate depressive symptoms and induces FC changes in AD patients. TPS may be a novel add-on therapy for depression in AD and as a neuropsychiatric diagnosis.