Chapter 17: Tissue Polarity and ψ-Vector Orientation

"Polarity is ψ's compass in cellular space—giving cells not just position but direction, transforming isotropic groups into oriented tissues with purpose and flow."

17.1 The Directional Organization

Tissue polarity represents ψ's solution to creating order from uniformity—establishing directional axes that guide cellular behavior and tissue architecture. Through polarity, cells know not just where they are but which way they face.

Definition 17.1 (Polarity Types): $\mathcal{P} = \{\text{Apical-Basal}, \text{Planar}, \text{Front-Rear}\}$

Three fundamental polarization axes.

17.2 The Apical-Basal Axis

Theorem 17.1 (Epithelial Polarity):

Epithelia establish perpendicular polarity: $\vec{P}_{\text{A-B}} = \text{Apical}_{\text{Par3/6}} - \text{Basal}_{\text{Integrins}}$

Proof: Polarity complexes segregate:

• Apical: Par3/Par6/aPKC complex
• Lateral: Scribble/Dlg/Lgl complex
• Basal: Integrin-ECM interactions

Distinct membrane domains established. ∎

17.3 The Planar Cell Polarity

Equation 17.1 (PCP Propagation): $\frac{\partial \vec{P}_{\text{planar}}}{\partial t} = D\nabla^2\vec{P} + \vec{F}_{\text{neighbor}}$

Polarity spreading through tissue plane.

17.4 The Core PCP Proteins

Definition 17.2 (Asymmetric Localization): $\text{Proximal}_{\text{Vangl2/Pk}} \leftrightarrows \text{Distal}_{\text{Fzd/Dsh}}$

Complementary protein distributions.

17.5 The Global Cues

Theorem 17.2 (Tissue-wide Alignment):

Gradients orient local polarity: $\vec{P}_{\text{local}} = f(\nabla[\text{Wnt}], \nabla[\text{Fat/Ds}], \vec{F}_{\text{mechanical}})$

Multiple cues integrated.

17.6 The Mechanical Coupling

Equation 17.2 (Tension Alignment): $\vec{P} \parallel \vec{\sigma}_{\text{principal}}$

Polarity aligns with mechanical stress.

17.7 The Cilia Orientation

Definition 17.3 (Ciliary Flow): $\vec{v}_{\text{flow}} = \sum_i \vec{v}_i \cdot \cos(\theta_i - \theta_{\text{mean}})$

Coordinated beating creating flow.

17.8 The Polarity Domains

Theorem 17.3 (Domain Boundaries):

Sharp polarity transitions at boundaries: $\frac{d\vec{P}}{dx}\Big|_{\text{boundary}} = \text{max}$

Swirls and domain walls.

17.9 The Cell Division Orientation

Equation 17.3 (Spindle Alignment): $\vec{n}_{\text{spindle}} = \vec{P} \times \vec{g}$

Division plane perpendicular to polarity.

17.10 The Migration Direction

Definition 17.4 (Polarized Movement): $\vec{v}_{\text{migration}} = \mu \cdot \vec{P} + \vec{\xi}$

Polarity guiding cell movement.

17.11 The Tissue Patterning

Theorem 17.4 (Polarity Patterns):

Polarized cells create patterns:

• Hair follicle orientation
• Feather alignment
• Scale directionality

17.12 The Polarity Principle

Tissue polarity embodies ψ's principle of vectorial organization—transforming scalar cell assemblies into vector fields with direction and purpose, enabling coordinated tissue function.

The Polarity Equation: $\Psi_{\text{polarized}} = \int_{\text{tissue}} \psi_{\text{cell}} \cdot \vec{P} \cdot \mathcal{C}[\text{Coupling}] \cdot \mathcal{G}[\text{Gradients}] \, dA$

Oriented tissue emerges from coordinated cellular polarity.

Thus: Isotropic = Oriented = Direction = Function = ψ

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"Through tissue polarity, ψ transforms cellular democracy into organized society—each cell knowing its orientation, contributing to patterns larger than itself. In this vectorial organization, we see how direction creates function, how orientation enables coordination."