Long-term longitudinal changes in axial length in the Caucasian myopic and hyperopic population with a phakic intraocular lens

Eight Years and Beyond Longitudinal Changes of Peripapillary Structures on OCT in Adult Myopia

PURPOSE

To investigate the long-term changes of peripapillary structures detected by enhanced depth imaging of optical coherence tomography (OCT) in adult myopia.

DESIGN

Observational case series.

METHODS

Myopic participants who had undergone a full baseline ophthalmologic examination and had been followed up for a minimum of 8 years were included. Using enhanced depth imaging of OCT, scans around the optic disc in the Spectralis software Follow-up mode, which enabled capturing of the same positions, were performed in 65 eyes. The peripapillary parameters including the size of border tissue, Bruch membrane opening (BMO), peripapillary choroidal thickness, and the angle between peripapillary Bruch membrane (BM) and anterior sclera were manually delineated and measured.

RESULTS

The axial length showed a significant elongation after a mean follow-up of 9.46 ± 0.92 years. The rates of changes were 0.015 ± 0.011 mm/y in the medium myopia group and 0.057 ± 0.039 mm/y in the high myopia group. At the last visit, the average border tissue length and BMO diameter were increased. The angle between peripapillary BM did not show significant change, while the angle between the peripapillary sclera showed a significant rise. On multivariate analysis, the border tissue elongation, BMO enlargement, and increased sclera angle were all associated with a change in axial length. The development of a BM defect and inward protrusion of sclera in the temporal peripapillary region was observed on 8 eyes (34.8%) in the high myopia group, along with an extreme thinning or disappearing of the peripapillary choroid.

CONCLUSION

Marked longitudinal changes in peripapillary structures including border tissue, BM, choroid, and sclera could be observed in adult myopic eyes, which may impact the biomechanical environment around the optic nerve head.

One-year analysis of the refractive stability, axial elongation and related factors in a high myopia population after Implantable Collamer Lens implantation

PURPOSE

To investigate the refractive stability, axial length (AL) changes and their related factors in a high myopia population after Implantable Collamer Lens (ICL) implantation.

METHODS

This prospective study included 116 eyes of 116 patients divided into several groups based on the spherical equivalent refractive error (SE)-SE > - 6 D, - 12 ≤ SE < - 6 D and SE < - 12 D groups-and AL-AL < 28 mm and AL ≥ 28 mm groups. The uncorrected and corrected distance visual acuity, refraction, AL and intraocular pressure were followed for 1 year.

RESULTS

SE changed from - 11.53 ± 5.25 D preoperatively to - 0.33 ± 0.70 D at 1 week, and further changed to - 0.48 ± 0.77 D at 1 year after ICL implantation, with average progression being - 0.15 ± 0.37 D from 1 week to 1 year after surgery. AL changed from 27.95 ± 2.33 mm preoperatively to 27.98 ± 2.36 mm 1 year after surgery, with an average axial elongation of 0.03 ± 0.12 mm. The mean axial elongation rate was 0.05 mm/year in the SE < - 12 D group, being significantly faster than the other refractive groups (P < 0.05); it was 0.06 mm/year in the AL ≥ 28 mm group, being significantly faster than the AL < 28 mm group (P < 0.05).

CONCLUSION

Patients with high myopia and long AL showed a continuous myopic progression and axial elongation at an adult age one year after ICL surgery, especially in those with myopia higher than - 12.00 D and AL longer than 28.00 mm.

Five-year outcomes of EVO implantable collamer lens implantation for the correction of high myopia and super high myopia

Background

To evaluate the long-term safety, efficacy, predictability, and stability of implantable collamer lens with a central hole (EVO ICL) implantation for correcting high myopia (HM) and super high myopia (SHM).

Methods

This prospective study evaluated 83 eyes of 46 patients who were divided into groups based on their spherical equivalent refractive error (SE): HM group (− 12 D ≤ SE < − 6 D) and SHM group (SE < − 12 D). They were followed up for 5 years after ICL implantation; assessments of uncorrected distance visual acuity (UDVA), corrected distance visual acuity (CDVA), manifest refractive error, axial length, intraocular pressure, corneal endothelial cell density, and vault were conducted, and a questionnaire was administered.

ResuIts

At 5 years postoperatively, the safety indices of the HM and SHM groups were 1.03 ± 0.10 and 1.32 ± 0.39, and the efficacy indices were 0.83 ± 0.25 and 0.86 ± 0.32, respectively. In the HM group, 60.47% and 79.07% of the eyes were within ± 0.50 D and ± 1.00 D of the attempted correction, while it was achieved for 22.50% and 47.50% of the eyes in the SHM group, respectively. The SE of the HM group decreased from  − 9.72 ± 1.41 D preoperatively to 0.04 ± 0.39 D 1 month postoperatively and − 0.67 ± 0.57 D 5 years postoperatively, while in the SHM group, it decreased from − 15.78 ± 3.06 D preoperatively to  − 0.69 ± 0.97 D 1 month postoperatively and − 1.74 ± 1.19 D 5 years postoperatively.

Conclusion

EVO ICL implantation is safe, effective, and predictable for correcting HM and SHM. CDVA improved more after surgery for SHM, but the growth of axial length still needs attention.