In vivo ultraosound elastographic evaluation of the age-related change of human lens nuclear stiffness

It is important to understand the material properties of the lens when investigating the age-related occurrence of cataracts and modelling the age-related decline in accommodative amplitude, which results in presbyopia. Although numerous studies have been conducted in which the elastic and shear moduli of the human lens were measured in vitro, there are few techniques that can be used to measure the material properties of the human lens in vivo.

Brillouin light scattering has been performed in vivo, and the results demonstrate that the longitudinal modulus, a measure of compressibility, of the human lens nucleusis greater than that of the lens cortex at all ages [1]. It was also found ex vivo that the longitudinal modulus is linearly related to the shear modulus, and therefore, the lens nucleus is less compressibleand stiffer than the lens cortex [1].This finding is supported by the results of multiple in vitro studies involvingconical probe indentation [2], shear rheometry [3], Brillouin light scattering [4] and the bubble-based acoustic radiation force technique [5].

The in vivo changes in the velocity of A-scan ultrasound waves within the lens have been used to detect nuclear cataracts [6] and to assess whether lens material properties change during accommodation [7].Optical coherence tomography has also been used to assess the lens nuclear stiffness [8]; however, these methods cannot be used to quantify the biomechanical material properties of the lens.

Non-invasive ultrasound elastography measurements of the strain rate [9, 10] and strain rate ratio [11] constitutea unique method for qualitatively and quantitatively evaluating the material properties of the human lens in vivo. However, the currently available device requires focusing on a region of interest that has essentially uniform elastic and shear moduli. Since the minimum diameter of the ultrasound beam is approximately 6 mm, only the biomechanical properties of the lens nucleus can be assessed.In the present study, the strain rate and strain rate ratio of the lens nucleus were evaluated in individuals in three different age groups.

This prospective study was performed in the Department of Ophthalmology in Tangdu Hospital at the Air Force Medical University in China after the university institutional review board approved the study. Written and verbal consent for participation in the study was obtained from 38 males and 40 females between the ages of 19and 89 years. The 78 participants were divided equally into three separate groups of 26 by their age. In Groups A, B and C, there were 10 and 16, 12 and 14, and 13 and 13 females and males, respectively. The mean age and axial lengths of the participants in Groups A, B and C were 81 ± 5.5yearsand 23.8 ± 0.5 mm; 44 ± 3.2 years 23.8 ± 0.4 mm; and 21 ± 2.5 years and23.9 ± 0.3 mm, respectively. All participants had normal ophthalmic examination results except for cataractous changes in the older age group, Group A, with best-corrected visual acuity of 20/20 and mean IOP of 16 ± 2.5 mmHg.

Using a coupling agent, the 8 to 10 Hz ultrasonic probe of the elastographer (Model EUP2L 54 M, 7 L probe, Hitachi Ltd., Japan) was vertically aligned perpendicularly with constant pressure on the central anaesthetized cornea of the randomly selected eye. The participants were placed in the supine position and looked toward the ceiling with the contralateral eye. Once the ultrasound probe was positioned perpendicular to the anterior lens surface, the elastograher gave a signal, and an image of the lens was captured.The region of interest (ROI) was set to the minimum default size of approximately 6 mm so that only the strain rate of the lens nucleus was automatically calculated by the elastographer. Lens nuclear strain rates were recorded when the device was in the ultrasound echolucency and elastic imaging modes. In the elastic imaging mode, a pseudo-colour scale showed the relative strain rate of the lens nucleus. A blue-coloured lens nucleus implied a lower strain rate and therefore a stiffer lens nucleus than did green- or red-coloured nuclei. The mean and standard deviation of the strain rate ratios were calculated for each group, and the differences across groups were analysed by one-way ANOVA (SPSS Version 13).

The qualitative differences in the strain rates across the cornea, iris and lens nucleus are visible in the elastographic images, as shown in Figs. 1, 2 and 3.The cornea was green, and the iris was red independent of the participant’s age, demonstrating, as expected, that the iris is softer than the cornea and that the stiffness of the iris and cornea do not significantly change with age.In contrast, the lens nuclei of Groups A (older aged), B (middle aged) and C (younger aged) were dark blue, dark green anddark green, respectively.The strain rate ratios of the lens nuclei of Groups A, B and C were 0.02 ± 0.08, 0.69 ± 0.12 and 1.95 ± 0.85, respectively, as shown in Fig. 4. The differences in the lens nucleus strain rate ratios across the groups were statistically significant, with p-values < 0.05.

The elastographic strain rate ratio is definitively more strongly associated with the lens nuclear stiffness than is the elastographic strain rate. The lens nuclei in the middle and younger age groups had a similar green colour, making it difficult to discern differences in the strain rate between the two age groups (Figs. 2 and 3), while the d strain rate ratios were statistically significantly different. The lens nuclei in the middle age group had a strain rate ratio of approximately 1/3 that of the younger age group, demonstrating that the lens nuclei in the middle age group were stiffer. However, the minimal strain rate ratio of the older age group, which was approximately 35 and 100 times smaller than those of the middle and younger age groups, puts into perspective the marked stiffness of the lens nuclei in the older age group.This result in the lens nucleus is expected with octogenarians.

Ideally, the elastographer should be improved so that the ROI can be made smaller than a millimetre. This would permit us to determine the changes in the relative stiffness of the lens cortex and nucleus with age. It may also allow us to assess whether there are subtle differences in the stiffness within the lens nucleus. In this study, we examined only three specific age groups. In the future, a study of individuals of all ages should be conducted to establish the rate of change in the lens nuclear stiffness with age.

Ultrasound elastography was used to demonstrate in vivo that an older age is associated with a significantly lower lens nucleus strain rate ratio and therefore a markedly higher lens nuclear stiffness. The elastographer strain rate ratio is a convenient and simple in vivo metric that can be used to quantitatively evaluate human lens stiffness. It may also be a valuable metric for assessing the biomechanical properties of all parts of normal and abnormal eyes.