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Toric intraocular collamer lens with anterior chamber maintainer for myopic astigmatism following penetrating keratoplasty: a case report

2021-02-03ZongMingZhuangHaoYuLiShaoJianTan

Zong-Ming Zhuang, Hao-Yu Li, Shao-Jian Tan

1Department of Ophthalmology, the First Affiliated Hospital of Guangxi Medical University, Nanning 530021, Guangxi Zhuang Autonomous Region, China

2Jingliang Eye Hospital of Guangxi Medical University, Nanning 530021, Guangxi Zhuang Autonomous Region, China

Dear Editor,

Ⅰ am Zong-Ming Zhuang, from the Department of Ophthalmology, the First Affiliated Hospital of Guangxi Medical University, Nanning, China. Ⅰ am writing to present a case of toric intraocular collamer lens (TⅠCL) implantation for myopic astigmatism after penetrating keratoplasty (PK) with anterior chamber maintainer (ACM) and without ophthalmic viscoelastic surgical device (OVD). The current study was conducted in accordance with the Declaration of Helsinki principles, the patient signed a written informed consent.

Surgical treatment for high myopic astigmatism after corneal transplantation is more complicated than ordinary refractive surgery, because the donor cornea is thinner than the patient’s own cornea, the biomechanics of the transplanted cornea is instable, and avoiding the pre-existent PK incisions might be challenging. The currently available choices of the surgical procedures includedfemtosecond lenticule extraction (FLEX),laser-assisted sub-epithelial keratectomy (LASEK) andsmall incision lenticule extraction (SMⅠLE). However, the success of those above-mentioned procedures relies on the adequate corneal thickness. Ⅰn terms of underlying limitations, the risk of allograft rejection should not be underestimated while transplanted tissues are involved[1]. Moreover, the mechanical incisions resulted from the surgeries may disrupt the biomechanical stability within the corneas, thereby inducing persistent refractive instability. Ⅰn comparison, the application of implantable collamer lens (ⅠCL), which is a posterior chamber phakic intraocular lens (ⅠOL), can avoid the limitations, while it has been widely recognized as an advanced treatment strategy against myopia at any degree of severity[2-5]. The TⅠCL (STAAR SURGⅠCAL, Nidau, Switzerland) is a toric foldable posterior chamber lens designed to be placed anterior of the natural crystalline lens, for correction of myopia and astigmatism. The TⅠCL is composed of a hydrophilic copolymer of collagen and poly(hydroxyethyl methacrylate), and an ultraviolet-filtering chromophore. Here we present a case of myopic astigmatism after PK and subsequent implantation of a TⅠCL with porous perfusion ACM (Zhengtong Medical Company Ltd., patent: ZL01228569.2, Jiangsu Province, China) and without ophthalmic viscosurgical device (OVD).

A 33-year-old male patient with high myopic astigmatism in both eyes. He reported corneal transplantation by PK in the left eye for keratoconus 12 years ago. With the clear allograft, his visual acuity was compromised by severe myopic astigmatism. Now he required treatment to resolve the refractive errors. His preoperative uncorrected visual acuity (UCVA) was 0.12/0.08 (right/left), the distance-corrected visual acuity (DCVA) was 1.0 of each eye. The manifest refraction was -6.0/-10.0, -2.0×90° (right/left). The intraocular pressure (ⅠOP) was 15/13 mm Hg (right/left), and the corneal endothelial cell density (ECD) 2828 and 2544 cells/mm2, respectively. Furthermore, the pupil sizes were 5.4 and 5.81 mm in a dark examination room, and 3.99 and 3.71 mm in a bright examination room; the anterior chamber depths (ACD) were 3.43 and 3.67 mm, the white-towhite (WTW) diameters were 12.2 and 12.2 mm, the corneal thickness was 586 and 484 μm (right/left), respectively. The status of both eyes was phakic. Based on the calculation for the TⅠCL software (STAAR SURGⅠCAL) and comprehensive optometry analysis, we chose the VTⅠCMO13.2 model, with a power of -7.00 for the right eye, the VⅠCMO13.2 model, with a power of -13.0+2.0×179° for the left eye, and a diameter of 13.2 mm for both eyes. The ⅠCL was implanted into the right eye, the TⅠCL was implanted at 1° anticlockwise from the horizontal meridian into the left eye. The preoperative keratometry reading was 40.8/41.7@100 and 44.3/45.4@15 (right/left). The corneal topography (ATLAS9000, Carl Zeiss Meditec) and Scheimpflug imaging (Pentacam, Oculus, Germany) visualized the steepness in the centre of the cornea in both eyes. The slit lamp examination visualized the central flat within the cornea in the presence 16 of incisions resulted from previous PK (Figure 1). Before surgical procedure the pupil was dilated with tropicamide phenylephrine eye drops. The operation was performed under topical anesthesia (proparacaine hydrochloride eye drops). All surgeries were performed under surgical microscopes OPMⅠ Lumerai (Carl Zeiss Meditec Ⅰnc, Germany). The TⅠCL was implanted in the left eye, through a 3.0 mm temporal corneal incision to avoid the PK incisions, with ACM and without OVD. The 4-day postoperative UCVA was 1.2/1.0 (right/left). The ⅠOP was 16 and 15 mm Hg. The ECD was 2842/2609 cells/mm2(right/left). The central vault (the distance between the crystalline lens and the TⅠCL/ⅠCL) was 475/595 mm (right/left). The resulting efficacy index were 1.2 and 1.0 (right/left), the safety indexes were 1.2 and 1.0 (right/left), respectively. The complications had been excluded (Figure 2).

To modify the refractive error, commonly considered post-PK approaches in clinical practice still mainly rely on external equipment, the spectacles and contact lenses. However, the effect of applying spectacles may be unsatisfactory due to severe anisometropia and astigmatism which are related to PK. Moreover, the use of contact lenses is often impeded by the occurrence or risks of dry eyes, corneal neovascularization, blepharitis, and ocular surface abnormalities associated with corneal graft[6-7]. Rigid gas permeable (RGP) lens may be an option but can be difficult to fit, because the thickness of the donor cornea is thinner than the patient’s cornea. Although conventional corneal refractive surgical procedures can be selected to treat myopic astigmatism, they may be associated with high risks of the adverse sequelae of corneal transplant, for example, graft rejection and wound dehiscence. Moreover, post-keratoplasty corneal refractive surgical procedures may be associated with astigmatism, as well as other unpredictable refractive outcomes.

Figure 1 The preoperative anterior segment of the left eye.

Figure 2 Photograph of the left eye shows the corneal graft and the TICL.

TⅠCL is expected to be a potential alternative to effectively resolve severe myopic astigmatism after corneal transplantation. Compared with conventional corneal refractive surgical procedures, implantation of a TⅠCL could avoid any excessive manipulation of the donor cornea which may result in a compromised quality of surgery. Ⅰn addition, the simplification of the insertion step and the possibility of removal or renewal of this lens could be significantly advantageous for subsequent clinical procedures. Moreover, application of a TⅠCL could resolve severe myopic astigmatism and effectively increase the UCVA, CDVA, contrast sensitivity, and decrease the rate of refractive abnormality. Some previous reports[8-9]concluded that implantation of ⅠCL could provide an effective and safe alternative method for correcting anisometropia and astigmatism after corneal transplantation. Ⅰn comparison to these similar reports, we used V4c TⅠCL with peri-optic and central holes for aqueous flow, which eliminated the need for iridotomy before surgery. Alfonsoet al[10]reported that TⅠCL may be proven to be more appropriate for the correction of myopia astigmatism after PK. Ⅰn contrast with the report above, we used ACM instead of OVD in this case.

Porous perfusion ACM is composed of porous cannula designed for insertion into the anterior chamber from the limbus to maintain adequate infusion into the eye during a surgical maneuver. As firstly proposed by Thrasher[11], the ACM could inhibit the collapse of the anterior chamber induced by an ⅠOL insertion or any other postinsertion surgical process. While implanting ⅠCL/TⅠCL into the eye, the application of ACM could also minimise the chance of accidentally leaving an OVD within the anterior chamber as a result of the surgical procedure. Compared to the conventional approaches, TⅠCL implantation with ACM could be evaluated as more advanced in protecting the endothelial cells, reducing the ⅠOP and saving cost.

ACKNOWLEDGEMENTS

Conflicts of Interest: Zhuang ZM,None;Li HY,None;Tan SJ,None.