Decoding Gene Editing: The Ultimate Equation

Decoding Gene Editing: The Ultimate Equation Ce[{(0rxy-x-y)⇒H}]1xyz,1xy-z,1x-yz,1x-y-z,-1-xyz,-1-xy-z,-1-x-yz,-1-x-y-z) ⇒c}] F1=1xyz,1xy-z,1x-yz,1x-y-z,-1-xyz,-1-xy-z,-1-x-yz,-1-x-y-z}F2=1xyz,1 xy-z,1x-yz,1x-y-z,-1-xyz,-1-xy-z,-1-x-yz,-1-x-y-z]F3=1xyz,1xy-z,1x-yz ,1x-y-z,-1-xyz,-1-xy-z,-1-x-yz,-1-x-y-z)F4=1xyz,1xy-z,1x-yz,1x-y-z,-1-xyz, -1-xy-z,-1-x-yz,-1-x-y-z}F5=1xyz,1 xy-z,1x-yz,1x-y-z,-1-xyz,-1-xy-z,-1-x-yz,-1-x-y-z]F6=1xyz,1xy-z,1x-yz,1x- y-z,-1-xyz,-1-xy-z,-1-x-yz,-1-x-y-z ⇒H)}] Ce= eukaryotic cell c= carbon H= hydrogen r= radius x= axis y= axis -x= axis -axis z= axis -z= axis F= faces ⇒= implies Evolution = f(PA, SN, SA, T) Equation of Gene Editing E = Ce * (Δrxy - Δx - Δy) * (H + c) * (1 - PA) * (SN + SA) * T Variables 1. E = Gene Editing 2. Ce = Eukaryotic Cell 3. Δrxy = Radius variation (mutation) 4. Δx, Δy = Axis variation (mutations) 5. H = Hydrogen 6. c = Carbon 7. PA = Loss of ancestry 8. SN = Natural selection 9. SA = Artificial selection 10. T = Time Gene Editing Function E(Ce, Δrxy, Δx, Δy, H, c, PA, SN, SA, T) = { Ce * (Δrxy - Δx - Δy) * (H + c) * (1 - PA) * (SN + SA) * T, if E > 0 0, otherwise } Constraints 1. Δrxy, Δx, Δy ∈ [-1, 1] (mutation limits) 2. PA, SN, SA ∈ [0, 1] (selection limits) 3. T ≥ 0 (non-negative time) 4. H, c ∈ [0, 1] (hydrogen and carbon concentrations) Notes 1. This equation is a mathematical simplification. 2. Real gene editing involves complex processes. 3. Consult experts in genetics and molecular biology. References 1. "Molecular Genetics" (Alberts et al., 2019) 2. "Gene Editing" (CRISPR Therapeutics, 2022) 3. "Molecular Evolution" (Kimura, 1983) Evolution Evolution = f(PA, SN, SA, T ) Where: 1. Evolution: genetic divergence between groups. 2. PA: loss of ancestry. 3. SN: natural selection. 4. SA: artificial selection. 5. T: time. References 1. "Molecular Genetics" (Alberts et al., 1998). al., 2019) 2. "Gene Editing" (CRISPR Therapeutics, 2022) 3. "Molecular Evolution" (Kimura, 1983)