Capsular contraction syndrome (CCS) continues to pose challenges in the era of premium intraocular lenses, where optical precision is crucial for success.Toric and extended depth-of-focus (EDOF) IOLs are particularly sensitive to small positional shifts; even minor decentration or tilt can degrade image quality, induce astigmatism, and cause unwanted visual phenomena. 1While advances in surgical technique, IOL biomaterials, and capsule management have improved consistency, the interplay between the biology of lens epithelial cell (LEC) proliferation and the biomechanics of the capsular bag still determines long-term stability. 2CCS develops when residual LECs on the anterior capsule transform into myofibroblasts that contract circumferentially, causing centripetal shrinkage of the capsule.Ideally, these forces are evenly distributed, maintaining lens centration. 3However, any asymmetry due to zonular laxity, incomplete cortical clean-up, or uneven capsulorhexis overlap can create local variations in tension that distort the IOL's position.Even a few degrees of tilt or fractions of a millimetre of decentration can meaningfully alter optical performance, particularly in multifocal or toric lenses. 4From a biomechanical perspective, the capsular bag may be conceptualized as an elastic shell under competing forces: radial tension (T z ) from the zonules and circumferential contraction force (F c ) from the anterior capsule.The net force acting across the equator is expressed as: 5When contraction becomes asymmetric such that Fc(1)Fc(2), a torque is generated around the IOL's center, described by This torque induces a tilt angle () proportional to the rotational stiffness (k r ) of the IOL-capsule system: For single-piece hydrophobic acrylic IOLs, k r averages 2.5 10 4 Nm/degree.Modeling shows that a 15% asymmetry in the capsular contraction radius (r/r) can cause a tilt of approximately 4.5, enough to reduce modulation transfer function by 20% in an EDOF optic.To visualize this effect geometrically, the capsule equator can be approximated as an ellipse with major and minor axes a and b.The eccentricity of the ellipse determines the optical decentration () according to where represents the axis of maximum contraction.For example, if a=5.0 mm and b=4.7 mm, the resulting decentration () is approximately 0.3 mm equivalent to a 6 rotation in a 2.25 D toric IOL. 6Such small geometric deviations can have
Gurnani et al. (Wed,) studied this question.