Abstract
To examine the historical and conceptual divergence between refractive terminology (myopia, hyperopia, emmetropia) and ocular axial length, to quantify the relative contributions of axial length and other biometric components to refractive error, and to propose linguistic and clinical strategies to improve precision in ophthalmic communication.
Perspectives RESULT: Historical review shows refractive terms originated as descriptors of visual function rather than globe anatomy; only in the 19th century did axial elongation become linked to myopia. Contemporary biometric and modeling studies demonstrate that axial length is the dominant single contributor to refractive error but is not determinative. Population analyses report moderate-to-strong correlations between spherical equivalent and axial length and stronger correlations with composite indices such as the axial length-to-corneal radius ratio; axial length alone explains roughly 29% of refractive variance, the axial length-to-corneal radius ratio approximately 56%, while multivariable models incorporating axial length, corneal curvature, anterior chamber depth, and lens power account for >99% of variance. Therefore, the Greek-derived terms dolichophthalmia ("long eye") and brachyophthalmia ("short eye") more accurately denote globe dimensions compared to refractive terminology, while finding an appropriate term to describe an eye with "normal" or "typical" axial length remains challenging.
Refractive state and axial length are related but distinct constructs. Greater precision - by specifying structural contributors (axial, lenticular, corneal) or reporting biometric measures relative to age-adjusted norms, and by adopting anatomically explicit terminology - will improve clinical communication, risk assessment, and research clarity.