Evaluation of Decentration, Tilt and Angular Orientation of Toric Intraocular Lens.

PURPOSE: The aim of this study was to develop software for the universal objective evaluation of factors influencing intraocular correction of astigmatism, such as decentration, tilt, axial position and angular orientation the toric intraocular lens (IOL). PATIENTS AND METHODS: Software was developed using the MS Visual Studio environment. The analysis was presented using images of 67 eyes with an implanted IOLs of the SN6ATx model series. Decentration and angular position of the lens were obtained from images of the anterior segment of the eye, using a Visucam unit. Tilt was measured on tomographic images from OCT Avanti (in meridian of highest tilt and perpendicular meridian) and preoperative biometry parameters of eye (axial length, anterior chamber depth - ACD, ocular lens thickness - LT, limbus diameter and mean keratometry value) including postoperative anterior chamber depth (pACD) were measured using Lenstar LS900.
RESULTS: Applying the software methodology to the evaluation of individual toric IOL parameters, the following results were obtained: mean decentration 0.25 ± 0.17 mm which was observed in 61.19% of eyes, mean misalignment to the planned axis equal to 3.8 ± 3.6 degrees, mean highest inclination equal to 3.7 ± 1.2 degrees and mean difference of pACD and ACD was equal to 1.46 ± 0.31 mm. There was only a weak nonsignificant correlation between preoperative ACD versus decentration and tilt of IOL or a weak significant correlation between preoperative LT and both decentration and misalignment of IOL.
CONCLUSION: The use of the presented methodology for determining the positional parameters of the toric IOL provided comparable results with the results of recent studies. Software design can be considered as a suitable alternative to previously published techniques, with the significant advantage of the possibility of using universal input images, their graphical editing and especially the possibility of comprehensive analysis of all parameters.

Introduction

Cataract is a curable disease only by surgical removal of the clouded lens and implantation of an artificial intraocular lens (IOL). This gives the surgeon a unique opportunity to correct the refractive ametropia of the eye for optimal postoperative visual acuity and the independence of the glasses at a given distance. However, approximately up to 40% of patients diagnosed with cataract also have corneal astigmatism at least 1 D.1–5 If such astigmatism is not corrected, the patient will not be able to achieve his or her best potential visual acuity without glasses, and will partially lose contrast sensitivity, especially in the dark.

The most effective solution for astigmatism and cataract in one step is the implantation of a toric intraocular lens (TIOL). However, this presents the need to calculate the optical power of the IOLs, as well as the power of the correction cylinder value and the implant axis. Using modern non-suturing surgical techniques, optimised calculation formulas and virtual imaging systems, the surgeon is able to achieve the angular orientation of the TIOL in the correction axis with an accuracy of 1 degree.

Several studies have reported successful results in minimizing postoperative refractive astigmatism. Despite a slightly different approach to preoperative diagnosis and optimisation of calculations, a small percentage of eyes can be found in which the residual value of astigmatism exceeds a subjectively acceptable value up to 0.75 D cylinder. One of the necessary steps in the search for the cause of these individual postoperative refractive surprises is the evaluation of the positional parameters of the lens position in the capsular bag (such as axis misalignment) and subsequent estimation of their influence on residual astigmatism.6–9 However, no conventionally used methodology or comprehensive tool is available to obtain and summarize these values to determine all positional factors simultaneously. Most research on TIOL positioning in the capsular bag is limited to developing a methodology for assessing one or two parameters, with the procedure adapted only to a specific device. Therefore, the aim of this research was to design a user-friendly tool to objectively assess all positional factors such as decentration, angular orientation, tilt, and axial position of the TIOL. The main requirement for the functionality of the custom software was the ability to universally use images acquired with commonly available visualization devices and to exploit this potential to create a free online tool. This study presents the design of the proposed tool for obtaining numerical outputs of each parameter. Using sample graphical outputs and then using the given methodology, a statistical evaluation on a set of patients is presented.

Materials and Methods

The design of a software tool for postoperative evaluation of positional parameters of the toric IOL was created, using the integrated development MS Visual Studio environment with the code language of the Visual Basic (.NET) editor. The user has access to tools for graphic editing of loaded images (adjusting contrast or brightness, cropping an image, creating a negative, etc.) and also to basic methods of image segmentation (image thresholding).

The first step is to log the user into the software and enter the patient’s credentials, including biometry parameters of eye, choosing laterality and model or size of the optical part of IOL. Then the user has the option to choose to enter the individual sections and then upload a suitable image for analysis. Evaluating the centring of a toric IOL consists of two steps: finding the reference point and centre of the optical part of the IOL. The reference point can be selected by the user as the centre of the visual axis (for example as an approximation by the first Purkinje image), centre of pupil or limbus. After basic graphical editing (zooming in or out, etc.), the user is able to manually mark three points as the boundary of the selected reference point and then mark the optical part of the IOL. The boundaries are visualised by a triangle bounded by a circle (Figure 1, left). The result of the decentration is presented as a decentration vector (value and direction) due to the knowledge of the diameter of the optical part. Determining the angle orientation of the TIOL depends on the quality of the image by visualising the markers. The user is able to mark two opposite marking points determining the angular orientation of the toric IOL, and the output will be a graphically displayed orientation angle to the horizontal plane (Figure 1, right). The determined angular orientation of the TIOL was compared with the planned implant axis and evaluated as a misalignment in the following analysis.

Figure 1

The resulting vector of decentration (left), the blue point is the centre of the pupil, which is highlighted by the blue circle, the yellow point is the centre of the optical part of the IOL, the edge of which is shown by the yellow circle. The decentration vector is determined by the relationship between these two points. The right part of the figure presents the determination of the angular orientation (orange line) of the toric IOL with respect to the horizontal plane (shown in green).

The tilt of TIOL was evaluated on a similar principle as in the previous angle orientation procedure. For universality of input images, the user has the additional possibility of defining the reference plane. First option is choosing reference plane himself (for example, in OCT images of the anterior segment of the eye by marking the iris plane) or use default setting (reference plane is horizontal plane of image). For tilt analysis, is necessary to upload at least two scans – scan in the critical meridian (choosing the meridian with greatest inclination) and the perpendicular scan. An example of the measurement result is presented in Figure 2.

Figure 2

The resulting angle of tilt in critical and perpendicular meridians (tilt axis orange, reference plane green). In the upper part of the Figure, the resulting value of 170 ° is not intentionally corrected, for the purpose of additional evaluation of the direction of tilt (nasal, temporal).

An additional parameter is the axial position of the IOL in the visual axis, which can be determined directly by measurement using optical biometry as a parameter of the postoperative depth of the anterior chamber (commonly called pACD). The user of the proposed software can use direct input of this value, or can use graphical measurement, as previously mentioned. It is necessary to use scans of the whole anterior segments of the eye (to define the anterior surface of the cornea and the anterior surface of the IOL), but with the condition of knowing the dimensions of the scale of the image. After all measurements, the data are presented as a final report for printing, including graphical outputs of the analysed images.

Images of 67 eyes were used to present the resulting values of the TIOL positional parameters obtained with the custom software. The inclusion criteria were as follows: an arthephakic eye underwent cataract surgery with implantation of a toric intraocular lens into a capsular bag, image capturing was performed at least 2 weeks after surgery, operated by the same surgeon (Sarka Pitrova) and methodology, implanted toric IOL from the SN6ATx model line (calculated by Barrett Toric Calculator, using Verion image guided system for centration to pupil centre and axis alignment during surgery), eye without previous or postoperative disease or condition directly affecting graphically measured parameters, at least 14 days after surgery, optimal artificial mydriasis and suitable images for analyses.

The following data and captured images were used to demonstrate the principle of the tool. Images from Visucam 500 unit were used for decentration and angle orientation of toric IOL. The reference point for decentration was the centre of the pupil. OCT Avanti with anterior module was used for evaluation of IOL tilt in 8 different meridians of tomography images of IOL in the frontal plane (followed by choosing the critical and perpendicular meridians), due to the low depth of the scans, a horizontal plane, ie, a plane perpendicular to the fixation axis, was chosen as the reference plane. Lenstar LS900 was used to determine the biometry parameters of eye. such as axial length (AL), ocular lens thickness (LT), limbus diameter (WtW), mean keratometry value (K) and especially preoperative (ACD) and postoperative anterior chamber depth (pACD), ie, the axial position of the IOL in the visual axis. So the value of pACD was entered manually.

Data obtained using custom software was used for file analysis. Decentration, tilt, axial position, and misalignment of the angular orientation of the TIOL relative to the planned position were evaluated using the maximum, minimum, median and mean values including standard deviation for patient group. The relationship between the IOL positional parameters and the biometry values of the eye was evaluated using Pearson’s correlation coefficient.

Results

Custom software and the above methodology were used to determine the positional parameters of the TIOL. For this study, evaluation of IOL decentration to the centre of the pupil was selected. The mean scalar decentration (independently of the direction of the vector) was 0.25 ± 0.17 mm (median = 0.21 mm), and the mean vector of decentration was equal to 0.04 mm in 139 degrees. Decentration up to 0.50 mm was found in 89.55% eyes, and in 61.19% it was up to 0.25 mm.

The mean misalignment of the intended and determined angular orientations of the toric IOL was 3.8 ± 3.6 degrees, and the median was 3.0 degrees, respectively.

In our cases, with the OCT Avanti anterior segment module, it is only possible to display an intraocular lens at a shallow depth of field (but with 8 different meridians of radial scans in one measurement), so the horizontal plane perpendicular to the visual axis is set as the reference plane. The mean tilt value in the critical meridian (most tilted meridian) was observed at 3.7 ± 1.2 degrees (median = 3.5 degrees), in the perpendicular direction 0.6 degrees (median = 0.5 degrees). A maximum value of 10 degrees was recorded for a single case, the highest frequency (33.90%) was set for a tilt of 4 degrees, but 91.5% of TIOL was tilted up to 5 degrees. The tilt in the nasal direction was defined for 96.6% of eyes, and in 64.4% of cases directly in a horizontal scan (180 degrees).

In the case of this study, only directly measured values using a Lenstar optical biometer were used. The mean pACD was equal to 4.6 mm, and the mean difference value between anterior chamber depth before (ACD) and after surgery (pACD) was equal to 1.46 mm.

The resulting values, including decentration, measured misalignment of intended correction axis, highest tilt (called critical), and difference between pre- and post-operative ACD and their correlation with the biometry parameters of the eye are presented in Table 1.

Table 1

Mean Values and Pearson’s Correlation Coefficients (r) of Determined Positional Parameters of Toric IOL

A Total of 67 Toric IOLs
	Decentration [mm]	Misalignment [Deg]	Tilt [Deg]		Δ ACD [mm]
			Critical	Perpend.
Min	0.01	0.0	1.0	0.0	0.47
Max	0.68	17.0	10.0	2.0	2.26
Mean±sd	0.21 ± 0.17	3.8 ± 3.6	3.7 ± 1.2	0.6 ± 0.5	1.46 ± 0.31
Median	0.21	3.0	3.5	0.5	1.44
AL	r = 0.10	r = −0.01	r = −0.18		r = −0.10
ACD	r = 0.23	r = −0.06	r = 0.23		r = −0.15
LT	r = −0.31	r = 0.28	r = −0.11		r = 0.10
WtW	r = 0.08	r = 0.04	r = 0.11		r = −0.03
K	r = −0.14	r = 0.06	r = −0.16		r = −0.09

Note: r = Pearson’s correlation coefficient, significant values (P<0.05) are highlighted in bold.

Abbreviations: AL, axial length; ACD, preoperative anterior chamber depth; LT, ocular lens thickness; WtW, limbus diameter; K, mean keratometry; Δ ACD, difference of postoperative and preoperative ACD.

The finding of the correlations of all determined positional parameters of the toric intraocular lens was correlated with biometric values of the eye defined before surgery. There was only weak correlation between preoperative ACD versus decentration (r=0.23, P>0.05) and inclination (r=0.23, P>0.05) or weak correlation between LT and misalignment (r=0.28, P<0.05) or weak negative correlation between LT and decentration (r=−0.31, P<0.05).

Discussion

The software design can be considered as an alternative to previously published techniques, with the significant advantage of the possibility of using universal input images, their graphical modification and especially the possibility of complex determination of all parameters.

For 67 eyes, mean values of decentration relative to the pupil centre (mean = 0.25 ± 0.17 mm), tilt (3.7 ± 1.2 degrees), misalignment from intended axis orientation (3.8 ± 3.6 degrees) and mean difference of postoperative and preoperative ACD (mean diff = 1.46 ± 0.31 mm) were determined. A significant weak negative correlation was found for preoperative LT and decentration, and a weak significant positive correlation for LT and misalignment. The other parameters did not reach a significant correlation.

There are several studies involving different approaches to the methodology and various models of IOL. Most of the research has acquired images for evaluation of decentralisation and tilt using Scheimpflug imaging systems10,11 (SchIS) or the anterior segment OCT12,13 (ASOCT) imaging system, each with its own customised image processing software. Contact measurement methods, such as ultrasonic biomicroscopy14 inducing inaccuracies due to eyeball deformation or methods using Purkinje image reflections (from refractive interfaces) with their own software solution or using the Purkinje-meter,15,16 are not clinically widely used. The simplest method of evaluating intraocular lens decentration in ophthalmic practice can be determined using a slit-lamp by subjectively evaluating the distance between the edges of the optical part of the intraocular lens to the edges of the pupil in mydriasis.17,18 However, toric IOL alignment could also be determined, either subjectively by optical cut rotation19 or by image capture and subsequent analysis in graphics editors,20,21 or by the alternative use of aberrometry to separate corneal and lens-induced (respectively internal) astigmatism.22

The main factors influencing the change in positional parameters of the intraocular lens in the capsular bag are the size of the capsulotomy and the design of the intraocular lens or haptic.23 Experimental and optical simulations of aberrations caused by IOL decentration according to Lawu et al24 and Perez-Gracia et al25 or Ashena et al26 concluded that the critical value of decentration is the limit of about 0.50 mm.

The resulting values of decentration and tilt of this study (mean dec = 0.21 ± 0.17 mm, mean tilt = 3.7 ± 1.2 degrees) were compared with the published results of other authors (independent of different IOL models and methods of measurement and selection of meridian of tilt): Assia et al:17 dec <0.50 mm (125 eyes, slit-lamp, pupilar axis) tilt not evaluated; Baumeister et al:18 mean dec = 0.19 ± 1.46 mm for spheric and 0.27 ± 0.16 mm for aspheric IOL (21 eyes, slit-lamp, pupilar axis) and mean tilt = 2.89 ± 1.46 degrees (spheric IOL) and 2.85 ± 1.36; Rosales et al:27 dec = 0.21 mm and tilt = 1.54 degrees (21 eyes, SchIS); de Castro et al:10 dec = 0.228 mm and tilt = 0.243 (12 eyes, SchIS, pupilar axis); Wang et al:13 dec = 0.56 ± 0.31 mm and tilt = 2.94 ± 0.99 degrees (39 eyes, AS-OCT, pupilar plane).

For misalignment comparison with the results of this study (mean deviation = 3.8 ± 3.6 degrees), the following results of alternative studies were chosen (regardless of the length of the postoperative period, only for SN6ATx models): Bauer et al:28 misal. = 3.50 ± 1.90 degrees (53 eyes, slit-lamp); Mendicute et al:29 misal. = 3.63 ± 3.11 degrees (30, slit-lamp); Mingo-Botin et al:30 misal. 3.65 ± 2.96 degrees (20 eyes, photo editor); Visser et al:31 misal. = 3.20 ± 2.80 degrees (67 eyes, slit-lamp); Grohlich et al:32 misal. = 4.92 ± 4.10 (41 eyes, not technique not specified); Zhu et al:33 misal. = 8.83 ± 5.26 degrees (75 eyes, photo editor).

Conclusion

Software and methodology for the objective evaluation of factors such as decentration, tilt, angular orientation (and possibly postoperative axial position) of the toric IOL affecting the correction of astigmatism have been successfully developed. The measured parameters generally correspond to the results of alternative methodologies. The software can be considered as a suitable alternative for the evaluation of the above-mentioned parameters in further studies, especially thanks to the possibility of graphical analysis using universal input images.