Despite major advances in molecular biology, genomics, and targeted therapeutics, many chronic diseases remain resistant to definitive cure. Relapse, resistance, and long-term dependence on intervention persist even when pathological components are accurately identified and transiently suppressed. In this work, we develop a theoretical framework in which disease persistence is governed not by the continued presence of abnormal components, but by the stability properties of nonlinear biological dynamics. Modeling biological regulation as a nonlinear dynamical system with feedback, adaptation, and multiscale coupling, we show that stable pathological attractors arise generically under minimal assumptions. Using established results from dynamical systems theory, we demonstrate that finite component-level perturbations are insufficient to guarantee cure unless they induce qualitative changes in system stability. We formalize these results in the Law of Pathological Stability, which defines disease persistence as the existence of a stable pathological attractor and defines cure as the irreversible destabilization or elimination of that attractor. The framework is falsifiable and provides a unifying theoretical foundation for understanding relapse, resistance, and the limits of curability across biological systems.
Harsha Vardhan Routhu (Thu,) studied this question.