A new detailed theory is developed for how isotopes of nonzero nuclear magnetic moments (NMMs) provide nuclear pressures for hidden stimulations for driving transportations locally for agitations; for transformations for chemical, catalytic and enzymatic activities; for thermodynamics for novel energetic, equilibrium and entropic redistributions; and for transmutations reversibly and fractionally. Such are basis for normal life activities by positive NMMs of 1H, 14N and 31P and other less abundant NMMs from stable isotopes of other elements as in vital minerals: 25Mg, 63Cu, 65Cu, 64Zn, 66Zn, 67Zn, 68Zn, 57Fe, 43Ca, 23Na, 55Mn, 95Mo, 97Mo, 53Cr, 77Se, 19F, 39K, 40K and 41K and others. Where bolds have negative NMMs, boldless have positive NMMs, and italics have 100% or nearly compositional 100% relative abundances. On the basis of such more details are added for aging of living organisms as isotopes redistribute in biomolecules for clumping into specific chemical bonds on nanoscales and possibly gradual to cataclysmic enrichments in nano-domains of uncommon isotopes of 13C, 15N, 17O, 25Mg, and 33S for altering the nuclear pressures for dissipative cycles of 1H, 14N, and 31P for causing aging and disease. The passage of these isotopes are considered during cellular replications. The catalytic prominent role of 17O for aging and cancer is demonstrated. The basis for accelerated enrichment by external electromagnetic waves and static magnetic fields and electric fields is developed. The stronger property shift by greater altering electrons is reasoned by multiple cataclysmic fractional, reversible fissing and fusing. Distinct effects of nanodomains of all positive NMMs, all negative NMMs, homogeneous mix of positive and negative NMMs, and heterogeneous mix of positive and negative NMMs are developed. The contributions of these different stable isotopes by their NMMs to normal logistics and cancer logistics are developed. The differing impacts of these stable isotopes are reasoned based on their electronic states and the change in NMMs by replacing common primordial isotopes by uncommon nonprimordial isotopes.