Clinical evaluation of toric intraocular lens implantation based on iTrace wavefront keratometric astigmatism

An estimated 40–50% of the population aged over 60 years has more than 1.0 diopter (D) of keratometric astigmatism [1‐3]. Also, 21.3–22.4% of patients with cataracts have 1.0–1.5 D of corneal astigmatism with 10.6–12.4% of patients having 1.5–2.0 D and 8.2–13.0% of patients having 2.0 D or more [4, 5]. Corneal astigmatism management has become crucial in modern cataract and refractive surgery practices. Significant postoperative astigmatism might affect both vision quality and spectacle independence, leading to unsatisfactory outcomes. Toric intraocular lenses (IOLs) have become an increasingly common technique due to their advantage of predictably, stably, and safely correcting a preexisting astigmatism.

Keratometers, corneal topographers, anterior segment tomographers, and intraoperative aberrometers can each provide corneal measurements necessary to accurately predict the ideal IOL cylinder power and alignment meridian to correct astigmatism during cataract surgery [6]. Since each device has its own characteristics, measurements obtained from different devices may not be comparable due to different refractive indices or measurement areas being used. Thus, there is no standard technique for measuring corneal astigmatism.

A wavefront analysis using an iTrace Surgical Workstation (Tracey Technologies Corp., Houston, TX, USA) integrates an aberrometer, corneal topography, and a toric IOL calculator. The iTrace toric IOL calculator offers a choice to match the keratometric values measured by wavefront aberrometry of the cornea or simulated keratometry. The iTrace wavefront aberrometry of cornea calculates steep power and axis based on the best Zernike mathematical fit from all topo data within 4 mm circle. It is supposed to be more accurate than iTrace simulated keratometry which is calculated based on only 4 points on the circle of 3 mm. However, the outcomes of using iTrace toric calculator based on wavefront keratometric (WFK) astigmatism for toric IOL planning must be evaluated. To the best of our knowledge, the present study is the first to investigate the outcomes of toric IOL planning with iTrace toric calculator based on wavefront keratometric astigmatism.

Eighty-five eyes of 63 patients with cataracts and a preoperative astigmatism of 0.83–4.92 D, as assessed by iTrace, were included. Demographic data, implanted IOLs, and their power sphere are displayed in Table 1. The AcrySof Toric IOL models are displayed in Table 2.

Factors influencing residual refractive astigmatism after cataract surgery with toric IOLs include accurate preoperative corneal astigmatism measurements, variability in the magnitude and direction of corneal incision SIA, the effects of different toric calculators, the rotational stability of different toric IOLs [8], and reported lens tilt [9]. Several diagnostic devices based on different technologies are available to measure preoperative corneal power and astigmatism, including manual and automated keratometers; Placido-based corneal, point-source color light emitting diode, Scheimpflug image-based, and scanning-slit corneal topographers; low-coherence reflectometers; and intraoperative aberrometers [10‐13]. However, none of these methods are currently considered the gold standard. In the present study, the outcomes of toric IOL implantation based on iTrace WFK and its built-in toric calculator were investigated. The iTrace WFK astigmatism is anecdotally described as being more accurate than simulated keratometry, but no prior research was clearly available to document this observation.

In this study, preoperative mean corneal topographic astigmatism was 1.91 diopters (D) ± 0.69. Postoperative mean refractive astigmatism decreased significantly to 0.48 D ± 0.34. 88.2% of the postoperative residual astigmatism were ≤ 0.75 D and 71.8% ≤ 0.5 D. These outcomes are very similar to previous studies. Potvin et al. evaluated clinical outcomes of patients whose toric IOL calculations were based on the Lenstar LS900 dual zone automated keratometer and found that 76% of eyes had ≤0.50 D of astigmatism after 3 months [14]. Results using the Barrett toric calculator show 72–80% of the cases with a residual refractive astigmatism of 0.5 D or less [15, 16].

The magnitude and direction of corneal incision SIA are essential in surgical planning. The average arithmetic corneal SIA in this study of 0.38 D ± 0.20 D (0.07, 0.94) and the centroid of 0.22@128° ± 0.37 D were close to the predicted value 0.25 D.

Among the mean corneal astigmatism measured with 3 devices (iTrace, IOL Master, and Pentacam) a higher mean was measured with iTrace WFK than with the axial keratometry of the 3-mm (4-mm) corneal zone, the simulated keratometric astigmatism and total refractive power measured with Pentacam; however, the mean was similar to the IOL Master simulated keratometric astigmatism and WFK within a 4-mm zone calculated with Pentacam. Park et al. showed the IOL Master corneal astigmatism measurements were higher than those calculated by iTrace wavefront aberrometry and simulated astigmatism [17]. The present findings confirm that IOL Master has a tendency to provide a higher value and show a similar trend of iTrace WFK and Pentacam WFK astigmatism.

Optimal astigmatism correction with a toric IOL requires both accurate surgical alignment and rotation stability. Several factors can influence postoperative rotational stability and IOL misalignment, such as the design and material of toric IOLs, the ophthalmic visco surgical device inside the capsular bag after surgery, large white-to-white measurements, and inaccurate preoperative axis marking [18]. A needle was used to mark the axis of toric IOL in the present study to decrease variation due to broad marking and reduce the possibility of spreading and washing out the dye due to tear flow. The method is similar with that proposed by Bhandari and Nath [19]. Their study found the postoperative mean IOL deviation at 1 day and 1 month was 5.7 ± 6.5° and 4.7 ± 5.6°, respectively. Furthermore, the postoperative median IOL misalignment was 3° at 1 day and 1 month [19], consistent with the present outcomes. A recent study shows that 28% of the mean toric IOL axis misalignment measured postoperatively is caused by intraoperative misalignment rather than postoperative rotation [20]; also, rotation between 1 h and 1 day postoperatively was rare [20]. At 1 postoperative year, the mean toric IOL axis misalignment was 6.67°, of which 1.87° were caused by surgical misalignment and 4.80° were caused by toric IOL rotation.¹⁹ Previous research suggested that a digital overlay system, including intraoperative wavefront aberrometry, and a digital marking system results in lower intraoperative misalignment and postoperative astigmatism than traditional manual marking [18, 21, 22]. Mayer et al. found statistically significant differences between manual marking and digital marking with better toric IOL alignment in the digital marking group (2.0 degrees versus 3.4 degrees) [18]. In this study, the intended axis was used as the baseline instead of the actual axis at which the IOL was positioned. Digital navigation was not used to the mark toric IOL axis. The average 1-week postoperative rotation median of the toric IOL axis was 4 degrees; therefore, part of the toric IOL misalignment might be caused by interoperative misalignment.

Pallas et al. found that the toriCAM application, used in the present study, potentially can significantly reduce reference marking errors, thus potentially improving the accuracy of both marking methods; hence, toriCAM use appears to be of greater benefit to the freehand than the slit-lamp method of marking [23].

There are several limitations to this study. Twenty-two patients had both eyes enrolled in this study, which represents a study limitation. A needle was used to mark the toric IOL axis without digital marking system assistance. Also, the toric IOL axis was not able to be observed accurately at the end of the surgery. Therefore, it was not possible to distinguish between intraoperative toric IOL axis misalignment and postoperative rotation. we suggest that further studies should be carried out to compare outcomes or theoretical outcomes between the iTrace WF keratometric astigmatism and the other measurement methods. The study showed that iTrace built-in toric calculator with wavefront keratometric astigmatism was safe and effective for toric IOL planning, but no comparison between clinical or theoretical outcomes between the iTrace WF keratometric astigmatism and the other measurement methods, further studies should be done to find out which method is better.

The iTrace wavefront aberrometry of cornea calculated steep power and axis based on the best Zernike mathematical fit from all topo data within 4 mm circle. It included more information of the central corneal topography data than simK. To the best of our knowledge, this is the first study evaluating the clinical outcomes of using iTrace wavefront keratometric readings to plan a toric IOL implantation.

The results indicated that toric IOL planning according to iTrace WFK values and the built-in calculator received comparable clinical outcomes to the previous studies. It proved the efficacy and safety of toric IOL planning based on iTrace.