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This work presents the Continuum Paradigm, an architectural framework for the integration of industrial fusion reactor subsystems under a unified electromagnetic interpretation. Conventional fusion reactor design is typically organized around disciplinary separation, where plasma physics, thermal extraction, materials engineering, and fuel-cycle management operate as partially decoupled domains. While effective at the component level, this approach introduces structural inefficiencies, increased recirculating power demands, and limited cross-domain coordination. The Continuum Paradigm proposes a reorganization of this structure by treating the reactor as a coupled electromagnetic system, in which plasma behavior, magnetic infrastructure, liquid metal blanket dynamics, and fuel conditioning processes are interpreted as interdependent layers of a single operational architecture. Within this framework, the liquid metal blanket is redefined as an active interaction layer operating in the inductionless magnetohydrodynamic regime (Rm ≪ 1). It does not generate or significantly modify the confining magnetic field, but responds to externally imposed fields through coupled flow–current–force interactions. This enables distributed sensing via wall potential measurements and localized actuation through externally driven current injection, expanding the role of the blanket beyond passive heat extraction while remaining consistent with established MHD constraints. The architecture is structured into four functional modules: — Partial internal support of magnetic infrastructure through MHD direct energy recovery and superconducting magnetic energy storage— Active magnetohydrodynamic blanket operation as a sensing-and-response layer under externally imposed magnetic fields— Dynamic isotope composition management using helium-3 as a plasma stability buffer via ion cyclotron resonance overlap— Plasma-based MHD centrifuge loops for real-time fuel recycling and isotopic conditioning The central contribution of this work is not the introduction of new physics, but the integration of established mechanisms into a coherent system-level architecture. By increasing coupling between subsystems traditionally treated in isolation, the paradigm aims to improve operational stability, reduce recirculating power, and enable more flexible transitions toward advanced fusion regimes. This document should be interpreted as an architectural proposal grounded in known physical principles, intended to explore new pathways for fusion system integration rather than to assert fundamentally new physical effects.