Directional pressure failure occurs when the execution index X=E×Iv×It×B is below threshold T, causing identical inputs to destabilize; stability returns when X≥T enabling downward load redistribution.
This preprint defines high gain in Directional Pressure Failure (DPF) terrain as threshold proximity within a constrained distributed-load biological system. Building on the Vertical Terrain Axis framework of Lantern of Sulfur (LoS), Concept B2 formalizes a material compliance gate: X = E × Iᵥ × Iₜ × B Where execution direction (concentration vs redistribution) is determined not by input magnitude but by the product of: E — Exit availability / permission Iᵥ — Vascular interface integrity (glycocalyx) Iₜ — Tissue transmission integrity (ECM / interstitium) B — Buffering medium capacity (sulfur-linked buffering / redox / charge–water behavior) When X falls below a state-dependent threshold T(s), identical inputs execute as upward pressure concentration (DPF). When X meets or exceeds T(s), execution proceeds as downward redistribution (coherence). This module clarifies sulfur-linked buffering and structured hydration not as supplement strategies but as material properties governing interface compliance and load transmission. The Acid Window is formalized as a timing-dependent execution surface in which exit permission and buffering margin align to permit redistribution without increasing force. No treatments, dosing strategies, or clinical protocols are proposed. This paper defines portable operators used by subsequent DPF / LoS modules.
Beth Martell (Fri,) conducted a other in Humans conceptualized in high-gain distributed-load biology with directional pressure failure (DPF) terrain involving compromised sulfur-linked buffering and sulfated interface integrity. Directional pressure failure occurs when the execution index X=E×Iv×It×B is below threshold T, causing identical inputs to destabilize; stability returns when X≥T enabling downward load redistribution.