A total of 81 porcine lenses were obtained from the local slaughterhouse and prepared as follows, see also Table 1: Crystalline lenses of eyes in group 1 were excised in the freshly enucleated eye and tested immediately. Lenses of group 2 were excised in the freshly enucleated eye, subsequently decapsulated and tested immediately. Eyes in group 3 were stored intact at +8°C for 24 h before the crystalline lenses were excised and tested. Crystalline lenses of eyes in group 4 were excised in the fresh eyes and subsequently stored in Minimum Essential Medium (MEM) for 24 h at 8°C before the measurement. Eyes in group 5 were stored intact at −20°C for approx. 24 h before the eyes were allowed to thaw at room temperature. Subsequently the crystalline lenses were excised and tested. Eyes in group 6 were stored intact at −80°C for approx. 24 h before the eyes were allowed to thaw at room temperature, similar as in previous studies (Weeber et al., 2007).

For crystalline lens extraction (Figures 1A–E), a scalpel was used to place an incision at the scleral equator. Then the anterior part of the eyeball was separated by micro-dissection scissors. After removing the aqueous humor, the lens was dissected from the ciliary muscle. For group 2 lenses, the capsule was dissected by carefully cutting along the lens equator before peeling the capsule off with a set of tweezers.

Before the actual mechanical characterization was conducted, the intact lens geometry was recorded. All geometric assessments and mechanical measurements were conducted at room temperature. For this purpose, a commercial optical coherence tomography device (Anterion, Heidelberg Engineering, Germany) was used, with an axial and lateral resolution of 9.5 µm (in air) and 35 μm, respectively. Two structural OCT scans were conducted: one with the anterior side of the lens facing towards the OCT, and one with the posterior side facing towards the OCT. The two scans were then merged into a single scan with extended depth. Subsequently, the corresponding reflectivity profiles were retrieved and used to identify the lens nucleus and cortical regions, see Figure 2.

Two separate measurements were performed to fully determine the mechanical properties of the lens:

(i) Stress relaxation. For this purpose, the distance between the two glass lamellas was reduced to 5.4 mm for lenses with capsule, and to 4.4 mm for the decapsulated group, to induce an engineering pre-strain of the lens of 33%. The distance between the two lamella and thus of the compressed lens thickness was measured by OCT (Figure 1F). A load cell weight sensor (HX711, max. load 1 kg) positioned under the piezo electric actuator was used to record the force relaxation for a duration of 2 min (short) and 30 min (long). Force was measured in gram-force (1 gf = 9.8 mN). The relatively high initial pre-strain was necessary to achieve (a) a reliable force measurement and (b) a compression over a larger proportion of the lens.

For dynamic strain assessment during the oscillating compression, a total of 256 subsequent OCT B-scans were acquired at the same location with a frame rate of 33 Hz, resulting in an overall measurement duration of 7.6 s. The displacement that occurred between two subsequent B-scans was determined by phase-sensitive processing of the complex-valued OCT signal as described recently (Zaitsev et al., 2016; Kling, 2020). Briefly, the axial displacement is calculated from Eq. 1: ∆ z = λ . ∠ R 4 π . n z , (1) where λ = 1200 nm is the central wavelength of the OCT, n(z) is the gradient refractive index of the porcine lens and ∠ R is the angle of the complex cross-correlation which is retrieved from Eq. 2: R = ∑ j = − w z w z ∑ k = − w x w x B S z + j , x + k   ·   B S + 1 * z + j , x + k , (2) where B represents an OCT B-scan, B* its complex conjugate, and s = {1, 256} is the number of B-scans. Phase-processing windows with a size of w _z = 10 and w _x = 1 pixels were applied. Strain was approximated as the axial gradient and computed by applying a second cross-correlation with the by one pixel axially shifted first complex cross-correlation, according to Eq. 3: ε z = ∆ z ∙ n z a s u =   λ · ∠ ∑ l = − v z v z ∑ m = − v x v x R s z + l , x + m · R s * z + 1 + l , x + m 4 π   · a s u , (3) being asu = 9.5 μm the axial sampling unit (in air), which means the axial dimension of a pixel. v _z = 15 and v _x = 1 pixels were the applied strain processing windows. Note that in contrast to displacement, axial strain measured with OCE is independent of the refractive index. Also, due to the compression between two flat glass lamella, no optical distortions due to the lens geometry are expected.

Cross-sectional axial strain was recorded. In order to improve signal quality, strains were averaged across a lateral zone of 2.3 mm. Subsequently, the average strain within three distinct regions(anterior cortex, posterior cortex and the nucleus) was computed for comparison among the groups. The corresponding regions were identified from the structural OCT image (see Figure 2). For validation, the average OCE strain across the full lens thickness was computed and a homogenous refractive index (Regal et al., 2019) of 1.49 was assumed to determine the corresponding lamella distance in order to compare the OCE-measured compression with the macroscopic compression applied by the piezoelectric actuator.

In order to retrieve the mechanical properties of the lenses tested experimentally under different conditions, inverse finite element analysis (iFEA) was performed in Abaqus (version 6.14, Dassault Systèmes). For this purpose, a 2D axisymmetric finite element (FE) model was developed to simulate the experiment. The glass lamella were modeled as rigid bodies, whilst the lens shapes were obtained from structural OCT scans of the lens without any zonular anchoring taken before any mechanical tests were performed. A representative geometry was determined for every condition.

The lens geometry was composed of the nucleus, the cortex and the capsule. To simulate the previously reported stiffness (Weeber et al., 2007) gradient within the lens and to account for the anatomical layered structure of the lens fiber cells (Kuszak, 1995; Taylor et al., 1996), the anterior part was divided into nine layers of cortex whilst the posterior was divided into 6, see Figure 3. This division was made to describe the difference in stiffness observed in the experimental tests between the anterior and posterior cortex of the lens. The stiffness of every layer of the cortex was defined by Eq. 4: C o r t e x n = N s t i f f n e s s ·   F n ·   C 10 − N ∞ , (4) where n in the exponent is the number of the respective cortical layer, being n = 1 the cortical layer closest to the nucleus. F is a form factor to differentiate the stiffness across the cortical layers. N is used to increase the relative stiffness of the nucleus with the cortex, and C 10 − N ∞ is the long-term Neo-Hookean modulus of the nucleus. Because the thickness of the posterior cortex is thinner than the anterior one, it contains only six layers. The anterior cortex contains all nine layers. To better describe the elasticity of the anterior and posterior cortex in the results section, the C 10 − n ∞ modulus was averaged as the stiffness of the layers that compose the anterior or posterior cortex, respectively, giving an average C ¯ 10 − A N T and C ¯ 10 − P O S T .

Initially, the top lamella axially compressed the lens to a thickness of L T t e s t = L T 0 − ∆ . This step was performed to assure the lens stability in the setup. The undeformed thickness L T ₀ of the decapsulated lenses was notably lower (6.6 mm) compared to all lenses with an intact capsule (8.06 mm). Therefore, L T t e s t = 4.40   m m was used for decapsulated lenses and L T t e s t = 5.40   m m for the other conditions, such that a similar compression of 33% was achieved. After the initial compression, an experimental sinusoidal micro-displacement was performed by the bottom lamella. The strains were calculated with the compressed lens configuration as a reference.

Large strains and nonlinearity were considered in this dynamic simulation. The axisymmetric conditions were imposed in the model about the y-axis. A “hard contact” behavior, strictly prohibiting penetration between the lamella and lens surfaces, was applied to maximize the realism of the simulation. No friction was applied.

The lens can be described as a visco-hyperelastic material consisting of the nucleus, cortex and capsule. The importance of accounting for the lens capsule has recently been demonstrated in a simulation study (Reilly and Cleaver, 2017) under a similar compressive loading. Therefore, following the approach of our recent study (Cabeza-Gil et al., 2023), the lens capsule was modeled with a homogeneous thickness of 60 μm and a Neo-Hookean coefficient of 0.166 MPa (equivalent to a Young’s modulus of 1 MPa). Due to the substantial strain induced during the pre-compression step, the lens nucleus was characterized by an incompressible visco-hyperelastic Neo-Hookean material model with a strain energy density function of Eq. 5: ψ C , t = C 10 − N R t   I 1 − 3 , (5) being C 10 − N R t the hyperelastic Neo-Hookean coefficient and I 1 the first invariant of the right Cauchy-Green deformation tensor. The time dependence of C 10 − N ∞ t is defined by a one term (N = 1) Prony series according to Eqs 6 and 7: C 10 − N R t = C 10 0   1 −   ∑ i = 1 N g i 1 −   e − t τ i , (6) C 10 ∞ = C 10 0 1 −   ∑ i = 1 N g i , (7) where C 10 0 is the instantaneous modulus and C 10 ∞ the long-term modulus. The Prony series parameters are defined by the pre-exponential factor g₁ and the relaxation time τ₁.

For consistency with linear elasticity in small deformations and for comparison across studies, the incompressible Neo-Hookean model can be converted to a linear elastic model according to Eqs 8 and 9 with the following relationship: µ = 2 C 10   , (8) E = 3 µ , (9) which µ is the first Lamé parameter, and E, the Young’s modulus.

The lens cortex was modeled with a hyperelastic Neo-Hookean material model, without effect of any viscous behavior as we did not observe this previously. (Cabeza-Gil et al., 2023).

Statistical analysis was conducted with IBM SPSS Statistics (Version 28.0.1.1(14)). Normality of the data was assessed with the Shapiro-Wilk test and accordingly parametric (ANOVA, Student’s t-test) and non-parametric (Independent-Samples Kruskal–Wallis test) tests were applied to compare parameters with normal and skewed distributions, respectively. Bonferroni correction was applied to account for multiple testing. A p-value of 0.05 was considered to indicate statistical significance.

The first column of Figure 4 shows the structural scan of the lens of the different groups before compression. As can be noticed, storage in MEM and freezing at both, −20 and −80°C, resulted in a significantly increased lens thickness by +0.85 mm (p < 0.001), +1.27 mm (p < 0.001) and +0.69 mm (p < 0.001), compared to the fresh condition, see also Figure 5A. In contrast, a significant decrease in lens thickness by −0.76 mm (p < 0.001) was observed after decapsulation, compared to the fresh group.

In agreement with the thickness changes, a higher initial maximal force applied (Figure 5B) in the relaxation test was measured for MEM (11.0 gf, p = 0.001) and frozen groups at −20°C and −80°C (8.49 gf, p = 0.013 and 9.66 gf, p = 0.005), compared to fresh lenses (5.35 gf). The correlation of the maximal force with the lens thickness was statistically significant (r = 0.775, p < 0.001). As expected, the minimal force measured at the end of the relaxation was significantly (p < 0.001) higher for short relaxation times compared to the longer one (on average 7.52 vs. 2.30 gf). There was also a significant correlation between lens thickness and the min force after relaxation, both at short (c_sp = 1.0, p < 0.01) and long (c_sp = 0.98, p < 0.001) relaxation times. Figure 6 presents the strongest correlations observed among the experimental parameters.

The second and third columns in Figure 4 show representative axial strain maps obtained during the oscillating relaxation and compression test. The strain distribution refers to the mean amplitude during relaxation (second column) and compression (third column). Notice that this corresponds to a dynamic strain distribution superposed on top of the pre-strain, which was applied during the initial compression. For better visibility, the pre-strain is omitted here. After freezing at −20°C, the lenses showed the highest strain ratio between the cortex: nucleus with a factor of 2.59 versus the fresh condition with a factor of 1.23 (p < 0.001), Figure 5C. Freezing at −80°C induced changes in the same direction but of lower amplitude (1.70, p = 0.005). No significant differences were observed between short and long relaxation times. When comparing the absolute strain amplitudes in the nucleus (Figure 5E) and cortex (Figure 5E), freezing at −20°C induced both, a significant decrease in the nuclear strain amplitude by −4.23‰ (p < 0.001) and an increase in the cortical strain amplitude by +6.43‰ (p < 0.001). Freezing at −80°C induced more subtle changes in nuclear (−1.74‰, p < 0.001) and cortical strains (+2.40‰, p = 0.005). Decapsulation resulted in a reduced nuclear strain amplitude of −1.30‰ (p = 0.010) and an increased cortical strain amplitude by +1.19‰ (p = 0.041), compared to the fresh group.

When comparing the different lens conditions in terms of the time delay between nucleus and cortex (Figure 5F), freezing at −20°C and −80°C demonstrated a significantly higher delay than the fresh group (−132 ms vs. −176 ms and −173 ms, p ≤ 0.015). No differences were found between short and long relaxation times. Supplementary Figure S1 show the average oscillation pattern in different regions of the lens (cortex and nucleus) for the different conditions.

Figure 7 presents the mechanical parameters retrieved from iFEA. The inverse fitting was best in the refrigerator condition (91.6%, 91.8%)—with short and long relaxation times, respectively –, followed by MEM (89.8%, 91.6%), decapsulated (88.8%, 86.8%), fresh (87.0%, 82.0%), frozen80 (85.2%, 88.0%) and frozen20 (89.0%, 80.0%) conditions, as determined by the R² (R square) value.

Over all conditions, τ₁ (1.43 ± 2.07 s vs. 0.82 ± 1.17 s, p = 0.023) and the form factor F (0.94 ± 0.16 gf vs. 0.92 ± 0.10 gf, p = 0.039) were significantly higher with short compared to long relaxation times. Yet, no significant differences between short and long relaxation times were observed at the level of an individual group.

N_stiffness was significantly higher in frozen, both at −20°C and −80°C, and MEM conditions compared to fresh lenses (5.76 ± 0.89, 3.00 ± 0.00 and 4.53 ± 4.67 vs. 1.00 ± 1.69, both p < 0.01). Form factor F was significantly higher in decapsulated (0.985 ± 0.18, p = 0.005), frozen20 (0.943 ± 0.05, p = 0.005) and MEM (1.01 ± 0.13, p < 0.001) conditions compared to intact fresh lenses. The ratio between nuclear and cortical strains C 10 − N ∞ C ¯ 10 − A N T (7.18 ± 1.17 vs. 3.79 ± 0.51, p = .004) and C 10 − N ∞ C ¯ 10 − P O S T (6.78 ± 0.92 vs. 3.04 ± 0.62, p < 0.001) were both increased after freezing at −20°C (but not at −80°C), compared to the fresh condition.