1
From: "Human Potential & Development."
Split Justification: Development fundamentally involves both our inner landscape (**Internal World**) and our interaction with everything outside us (**External World**). (Ref: Subject-Object Distinction)..
2
From: "Internal World (The Self)"
Split Justification: The Internal World involves both mental processes (**Cognitive Sphere**) and physical experiences (**Somatic Sphere**). (Ref: Mind-Body Distinction)
3
From: "Somatic Sphere"
Split Justification: The Somatic Sphere encompasses all physical aspects of the self. These can be fundamentally divided based on whether they are directly accessible to conscious awareness and subjective experience (e.g., pain, touch, proprioception) or whether they operate autonomously and beneath the threshold of conscious perception (e.g., heart rate, digestion, cellular metabolism). Every bodily sensation, state, or process falls into one of these two categories, making them mutually exclusive and comprehensively exhaustive.
4
From: "Autonomic & Unconscious Somatic Processes"
Split Justification: ** All unconscious somatic processes are fundamentally regulated through either the dedicated neural pathways of the autonomic nervous system or through the intrinsic, self-regulating mechanisms of other physiological systems (e.g., endocrine, immune, cellular, local tissue systems). These two categories comprehensively cover all autonomous and unconscious bodily functions and are mutually exclusive in their primary regulatory mechanism.
5
From: "Non-Neural Autonomous Physiological Processes"
Split Justification: Non-neural autonomous physiological processes can be fundamentally divided based on the scale and transport mechanism of their primary regulatory signals. One category encompasses regulation achieved through chemical messengers (such as hormones, circulating cytokines, or antibodies) that are transported via body fluids (blood, lymph, interstitial fluid) to exert widespread or distant effects throughout the organism. The other category comprises processes that are intrinsic to the cell or local tissue itself, relying on internal cellular mechanisms (e.g., metabolism, gene expression), direct physical or chemical responses within the immediate tissue environment, or paracrine/autocrine signaling confined to the immediate vicinity, without requiring systemic transport for their primary regulatory action. These two categories are mutually exclusive, as a regulatory mechanism either relies on systemic transport for its primary action or it does not, and together they comprehensively cover all non-neural autonomous physiological processes.
6
From: "Cellular and Local Intrinsic Regulation"
Split Justification: Cellular and Local Intrinsic Regulation encompasses all non-systemic, non-neural physiological processes that are intrinsic to a cell or its immediate local tissue environment. These processes can be fundamentally divided based on whether they operate strictly within the confines of a single cell (Intracellular Regulation, covering internal cellular mechanisms like metabolism, gene expression, and autocrine signaling) or whether they involve interactions between multiple adjacent cells or with the immediate non-cellular components of the local tissue environment (Local Intercellular and Tissue Microenvironment Regulation, covering paracrine signaling, juxtacrine signaling, and regulation of the extracellular matrix and local physiochemical conditions). These two categories are mutually exclusive, as a regulatory process is either contained within a single cell or involves elements external to it but still within the local vicinity, and together they comprehensively cover all forms of non-systemic, non-neural intrinsic regulation.
7
From: "Local Intercellular and Tissue Microenvironment Regulation"
Split Justification: Local Intercellular and Tissue Microenvironment Regulation can be fundamentally divided based on whether the primary regulatory mechanism involves direct physical contact or connection between adjacent cells, or whether it relies on signals or influences mediated by the extracellular matrix and interstitial fluid. The former category encompasses mechanisms requiring direct cell-to-cell physical interaction (e.g., juxtacrine signaling, gap junctions, adherens junctions). The latter category includes regulation via chemical messengers that diffuse through the interstitial fluid to nearby cells (e.g., paracrine signaling), as well as the influence of the extracellular matrix's physical and chemical properties and local physiochemical conditions (e.g., pH, oxygen levels) on cellular function. These two categories are mutually exclusive, as a regulatory interaction either fundamentally requires direct cellular contact or it does not, and together they comprehensively cover all forms of local intercellular and tissue microenvironment regulation described by the parent node.
8
From: "Contact-Dependent Intercellular Regulation"
Split Justification: ** All contact-dependent intercellular regulation mechanisms fundamentally establish either a direct physical channel connecting the cytoplasms of adjacent cells, allowing for the passage of ions and small molecules, or they involve interactions exclusively at the cell surface through membrane-bound molecules or structural complexes that do not create cytoplasmic continuity. These two categories are mutually exclusive, as a mechanism either provides direct cytoplasmic connection or it does not, and together they comprehensively cover all forms of direct cell-to-cell contact regulation.
9
From: "Direct Cytoplasmic Junctions"
Split Justification: Direct Cytoplasmic Junctions can be fundamentally divided based on the structural barriers they overcome to establish cytoplasmic continuity. One category encompasses junctions that solely bridge the narrow intercellular space between apposed plasma membranes of adjacent cells, typical of animal cells. The other category includes junctions that additionally traverse a rigid cell wall, extending through it to connect the cytoplasms of neighboring cells, characteristic of plant cells and some fungi. These two categories are mutually exclusive, as a direct cytoplasmic junction either encounters a cell wall as an additional barrier or it does not, and together they comprehensively cover all known forms of direct cytoplasmic connection between cells.
10
From: "Direct Cytoplasmic Junctions Bridging Intercellular Space"
Split Justification: All direct cytoplasmic connections bridging the intercellular space are fundamentally established either through the precise assembly of specific transmembrane protein complexes that form a regulated channel between cells, or they arise from processes involving incomplete cellular division (cytokinesis) or the direct physical fusion of adjacent cells. These two categories represent distinct and mutually exclusive mechanisms for achieving cytoplasmic continuity, as a connection is formed either by protein channel assembly or by incomplete division/fusion, and together they comprehensively cover all known forms of such connections in animal cells.
11
From: "Transmembrane Protein-Channel Forming Junctions"
Split Justification: ** All transmembrane protein-channel forming junctions that bridge the intercellular space are fundamentally established either as discrete, relatively static protein pore complexes that directly connect the cytoplasms of adjacent cells (e.g., gap junctions), or as dynamic, extended membrane conduits that physically bridge cells, supported by transmembrane proteins and the cytoskeleton (e.g., tunneling nanotubes). These two categories are mutually exclusive, as a direct cytoplasmic connection is either formed by a fixed, localized protein pore or by an extended, tube-like membrane structure, and together they comprehensively cover all known forms of such junctions in animal cells.
12
From: "Junctions Formed by Discrete Protein Pores"
Split Justification: ** Junctions formed by discrete protein pores, such as gap junctions, are constructed from two opposing hemichannels, each contributed by an adjacent cell. These channels are fundamentally differentiated by the molecular composition of these paired hemichannels: either both hemichannels are composed of identical protein subunits (forming a homotypic pore), or they are composed of different protein subunits (forming a heterotypic pore). This dichotomy is mutually exclusive, as a pore is either homotypic or heterotypic, and comprehensively exhaustive, covering all possible structural compositions of discrete protein pores that bridge intercellular space, with significant implications for their specific permeability, conductance, and regulatory properties.
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Topic: "Heterotypic Pores" (W6205)