Objectives: Deep brain stimulation (DBS), which uses an implantable device to modulate brain activity, is clinically superior to medical therapy for treating advanced Parkinson's disease (PD). We studied the cost-effectiveness of DBS in conjunction with medical therapy compared to best medical therapy (BMT) alone, using the latest clinical and cost data for the U.S. healthcare system.
Materials and methods: We used a decision-analytic state-transition (Markov) model to project PD progression and associated costs for the two treatment strategies. We estimated the discounted incremental cost-effectiveness ratio (ICER) in U.S. dollars per quality-adjusted life-year (QALY) from the Medicare payer perspective, considering a ten-year horizon, and evaluated the robustness of our projections through extensive deterministic sensitivity analyses.
Results: Over ten years, DBS treatment led to discounted total costs of $130,510 compared to $91,026 for BMT and added 1.69 QALYs more than BMT, resulting in an ICER of $23,404 per QALY. This ICER was relatively insensitive to variations in input parameters, with neurostimulator replacement, costs for DBS implantation, and costs for treatment of disease-related falls having the greatest effects. Across all investigated scenarios, including a five-year horizon, ICERs remained under $50,000 per QALY. Longer follow-up periods and younger treatment age were associated with greater cost-effectiveness.
Conclusions: DBS is a cost-effective treatment strategy for advanced PD in the U.S. healthcare system across a wide range of assumptions. DBS yields substantial improvements in health-related quality of life at a value profile that compares favorably to other well-accepted therapies.
Keywords: Cost-effectiveness; Parkinson's disease; deep brain stimulation.
© 2016 International Neuromodulation Society.