Deep brain stimulation in three Parkinson's patients produced measurable blood pressure increases of 8.24 mmHg per stimulation unit, enabling researchers to design an artificial baroreflex system. Using frequency response analysis and computer simulations, the team developed correction factors (0.12 proportional, 0.018 integral) that could theoretically counteract sudden blood pressure drops from position changes. This represents a potentially groundbreaking approach to orthostatic hypotension, which affects up to 30% of Parkinson's patients and significantly impacts quality of life. The concept of using existing DBS hardware to create an artificial autonomic reflex is ingenious, potentially offering dual benefits for movement and cardiovascular symptoms. However, this preprint awaiting peer review has critical limitations: only three patients were studied, no actual orthostatic challenges were performed, and the results remain purely computational. The safety implications of automated blood pressure manipulation through brain stimulation require extensive validation. While the proof-of-concept is compelling and could transform care for neurogenic orthostatic hypotension, larger controlled trials with actual postural testing will be essential before clinical implementation becomes feasible.