Closed-Loop Therapeutic Refinement Using Local Field Potentials in Parkinson's Disease (CTRL-PD)

Deep brain stimulation (DBS) of the subthalamic nucleus (STN) is an established treatment for patients with Parkinson's disease (PD), particularly for those experiencing motor fluctuations that do not respond adequately to medication. Optimal clinical outcomes depend on precise programming of stimulation parameters to effectively reduce motor symptoms, while avoiding side effects by minimizing stimulation of adjacent brain structures. During surgery, an electrode with eight contact points (1-3-3-1 design) is permanently implanted.

At the Haga Teaching Hospital, Maastricht UMC+, and Amsterdam UMC, the Medtronic Percept™ PC/RC system is commonly used for PD patients. This system provides not only stimulation but also the ability to record brain signals in the form of local field potentials (LFPs). This recording functionality can offer valuable insights for clinicians to fine-tune DBS parameters. For instance, elevated beta activity (13-35 Hz) in LFPs has been shown to correlate with the severity of symptoms such as rigidity and bradykinesia in PD patients.

In January 2025, a software update was introduced for the Percept™ system, enabling more advanced LFP measurements. This update allows the system to deliver adaptive DBS (aDBS), in which brain signals are used in real-time to continuously and automatically adjust stimulation amplitude. Although aDBS is a promising advancement, comprehensive research comparing its benefits and drawbacks to conventional DBS (cDBS) is still lacking. The only major study, ADAPT-PD, found that aDBS and cDBS result in similar durations of time spent in the "ON" phase, but it did not clarify which subgroup of patients benefits most from aDBS. Interestingly, many participants in the ADAPT-PD study expressed a desire to switch from cDBS to aDBS after the trial, though the factors influencing these preferences remain unclear. This highlights the need for detailed investigation into the relative advantages of aDBS and for whom the current form of aDBS provides the greatest benefit.

This study targets PD patients who have undergone cDBS for at least six months but are not experiencing optimal results due to persistent motor symptoms or stimulation-induced side effects that are insufficiently addressed by standard cDBS. Within this pilot study, using a combined N-of-1 trial design, outcomes of the patient's current cDBS settings and optimized conventional DBS (O-cDBS) will be objectively compared with those of optimized adaptive DBS (O-aDBS).

In an N-of-1 trial, an individual patient undergoes different test and placebo treatments in a randomized order. By conducting multiple N-of-1 trials across several patients, reliable and objective outcomes can be gathered both at the individual and population levels. In this study, each patient will test all three stimulation programs (current cDBS, O-cDBS, and O-aDBS) in a blinded and randomized sequence, each for seven days. The final outcome will be the patient's preferred program, with the patient's personal choice taking priority. To better understand the impact of switching from cDBS to aDBS-and to include effects on patient quality of life-this study will analyze not only motor symptoms but also cognitive and behavioral effects in daily life. This will be assessed through structured questionnaires, including a symptom diary and questions via the Experience Sampling Method (ESM). ESM is a validated, CE-certified digital diary method where patients provide feedback on the patient's symptoms at semi-random times, helping to reduce recall bias. By objectively analyzing the pros and cons of switching from cDBS to aDBS in these specific patient groups, this study aims to support neurologists in the clinical use of this new technology. Furthermore, the findings may contribute to more effective use of the system and ultimately to improved DBS treatment and quality of life for patients with Parkinson's disease.