To assess the interchangeability of central corneal thickness (CCT) measurements between combined scanning-slit/Placido disc topography (Orbscan-II) and specular microscopy (Topcon SP-2000P) in patients who underwent laser in situkeratomileusis (LASIK) for myopia.
Patients and methods
We recruited 118 consecutive patients who underwent LASIK for myopia. The CCT was measured using Orbscan-II and Topcon SP-2000P randomly. Orbscan-II and Topcon SP-2000P CCT data were analysed using the paired-sample t-test and the limits of agreement (LoA) were calculated with the method described by Bland–Altman.
The average CCT measurements by Orbscan-II and Topcon SP-2000P were 447.55±49.78 μm and 461.38±35.35 μm, respectively (P<0.0001; mean difference, 13.83±22.31 μm; 95% confidence interval, 9.77–17.09 μm). The Bland–Altman plot showed an inverse association between the average and the difference between the devices: Topcon–Orbscan-II=174.23 –0.353 × Average (P<0.01). The widths of the crude and regression-based 95% limits of agreement were 87.45 and 63.72 μm, respectively.
Orbscan-II measurements of CCT after myopic LASIK were significantly lower than those obtained using Topcon SP-2000P. The limits of agreement between the two devices were too broad and, therefore, both pachymetric values cannot be used interchangeably. Further, the tendency towards comparably Orbscan-II readings in thinner corneas precludes that one technique can directly replace the other. This is important for the adequate medium- and long-term follow-up of the growing LASIK patient population.
The measurement of central corneal thickness (CCT) is clinically relevant, especially considering the increasing popularity of refractive surgery. Accurate analysis of the corneal thickness is of paramount importance for assessing corneal disease and non-refractive and refractive surgical procedures.1, 2 Measurement errors could affect the preoperative assessment of candidates for primary and retreatment laser in situ keratomileusis (LASIK),3, 4, 5, 6 the intraocular lens (IOL) power calculations after LASIK,7 and the contribution of the CCT to measurement of the intraocular pressure (IOP).8
CCT can be measured using various techniques. Ultrasonic pachymetry is the current gold standard for pachymetry measurement,9, 10 but ultrasonography requires a probe contact. Thus, direct corneal trauma might occur resulting in flap dislocation,11 which also might occur with a history of minor trauma;12 the risk of microbial contamination is associated with use of a probe,13 and topical anaesthesia must be instilled. All of these factors might be associated with patient discomfort. Moreover, pachymetry measurements might be erroneous because of epithelial indentation; the accuracy will depend on the exact axial placement of the probe relative to the centre of the cornea.14 Therefore, non-contact methods are preferred for ocular biometry, and alternative techniques such as interferometry,15 corneal confocal microscopy,16 optical coherence tomography,9 non-contact specular microscopy,17 and scanning-slit technology5 are gaining popularity for assessing patients who have undergone LASIK.
In particular, the Orbscan-II (Bausch & Lomb, Rochester, NY, USA) topography system provides wide-field pachymetry analysis of the anterior and posterior corneal elevations. The corneal thickness can be calculated by measuring the distance between the anterior and posterior corneal surfaces.18
The Topcon non-contact specular microscope (NCSM) (SP-2000P; Topcon Corp., Tokyo, Japan) provides pachymetry measurements and specular microscopy simultaneously.14 Focusing on the endothelium, this apparatus supplies specular images and measures the focal distance, which can be calculated as the corneal thickness.19
Many ophthalmologists rely on the results yielded by both non-contact devices. Despite both non-contact methods are convenient, no study has analysed their interchangeability after myopic LASIK properly. The only study that compared both used correlation coefficients to assess their relationship,3 an analysing method that is flawed based on the investigations of Bland and Altman,20, 21 as well as the model of regression that relates the measurements obtained by both devices. Therefore, we evaluated whether the devices are interchangeable for patients who had undergone LASIK using the appropriate methods described by Bland and Altman.20, 21
Materials and methods
This study adhered to the principles outlined in the Declaration of Helsinki Principles. All candidates received detailed information about the nature of the investigation, and all provided informed consent. We selected 118 consecutive patients who had complete refractive stability on two successive visits at least 2 months apart. One eye of each patient was selected randomly for this investigation and the measurements were taken 9 months after LASIK. Patients were recruited over a 2-year period. Exclusion criteria consisted of suspected keratectasia, progressive myopia, or astigmatism (patients with a 0.25-diopter [D] change and/or ⩾15 degrees in cyclopegic refractive cylinder orientation were excluded); preoperative or post-LASIK hyperopia; mixed astigmatism; active ocular disease; connective tissue disorders; and pregnancy. All eyes underwent a complete ophthalmic examination before and after LASIK, including manifest and cycloplegic refractions, Orbscan-II topography, Topcon NCSM pachymetry, slit-lamp microscopy, applanation tonometry, and indirect ophthalmoscopy. Objective measurement of the corneal transparency was performed as previously reported.22
One experienced technician was assigned to each instrument to minimize variations in the results. The examiner was masked to the refraction and the postoperative time interval at each examination. Central pachymetry also was measured using the Topcon NCSM and compared with the Orbscan-II pachymetry values. The testing sequence of the measurements with both devices was randomized to avoid methodological and statistical bias.23 Examinations were carried out from 11:00 am to 1:00 pm to minimize the effect of diurnal variations on corneal thickness.24 Non-contact pachymetry measurements were always taken prior to any other ophthalmic procedure that could alter the cornea, including applanation tonometry.
All procedures were performed by the same surgeon (MJ Maldonado). The details of the primary LASIK procedures have been reported previously.6 The preoperative CCT had to be adequate to ensure a residual stromal bed of at least 250 μm and above 55% of the total preoperative CCT after creation of a corneal flap with a superior hinge (160-μm head, Hansatome microkeratome; Chiron Vision, Claremont, CA, USA). Ablation of the appropriate cut depth was carried out using the Technolas Keracor 217z excimer laser (Bausch & Lomb Chiron Technolas GmbH, Munich, Germany).
Topographic evaluation of CCT
Orbscan-II was calibrated before each session test following the instructions of the operator's manual provided by the manufacturer.25 The patient was instructed to fixate on a flickering red light and to blink to obtain a homogeneous tear film layer that ensures more reliable results. The instrument was then aligned and the cornea was scanned using a slit beam. The Orbscan-II statistical analysis device (software version 3.12) calculated the elevation of the anterior and posterior corneal surfaces; thus, the pachymetry measurement is the result of subtraction of the elevation maps of both corneal surfaces. Although Orbscan-II displays pachymetry values at several locations, only the central pachymetry value, but not the thinnest corneal point, was taken into account for statistical analysis because of two reasons: first, the reproducibility of the thinnest corneal point is expected to be lower26 and second, Topcon NCSM does not provide the thinnest corneal value, thus precluding comparison between measurement methods. The default acoustic equivalent setting of 0.95 for software version 3.1227 was used throughout this study.
Non-contact specular microscopy evaluation of the CCT
Topcon NCSM was calibrated as previously described.28 The CCT was measured while the subject fixated on a fixation light in the specular microscope. The pachymetry of the central cornea was obtained after proper positioning of the alignment dot, square, and bar on the screen using the automatic mode. The automated image capture, low-intensity mode of the specular microscope was used as described previously.17 The CCT was determined by patient fixation as well as Orbscan-II examination.
Data from the prospectively completed forms were entered into a database and statistical calculations were performed using SPSS (version 15.0 for Windows). The mean and standard deviation (SD) were calculated for normally distributed data.
Where data did not correspond to a normal distribution, the median (50th percentile) and interquartile range (IR: values between the 25th and 75th percentiles of the distribution) were used instead. For all statistical tests, a two-tailed P<0.05 was considered significant. The paired t-test was used to establish whether or not there was a significant systematic bias between measurements.
Bland–Altman graphs of the differences against the means were plotted to check the relation between the differences and the range of measurement, and to check whether the differences between the measurements were approximately normally distributed.20, 21 We assessed the interchangeability of both measurement methods by calculating the 95% limits of agreement (LoA), defined as the mean difference in measurements±1.96 SD as suggested by Bland and Altman.20, 21
When the differences between methods of measurement tend to be in one direction for low values of the quantity being measured and in the other direction for high values, a better fit than the above-mentioned crude LoA can be found by using a regression model described by Bland and Altman.29 A regression of the difference between measurement methods on their average can be used to model the relationship between mean difference and the magnitude being measured. In a second stage of the analysis, modelling the variability in the SD of the differences, directly as a function of the level of the measurement, can be achieved using a method based on absolute residuals from a fitted regression line. Modelling is considerably simplified by the assumption that these residuals have a normal distribution. Once one can predict the mean difference and the SD from these calculations, mean±1.96 SD can be estimated for any magnitude, and can be obtained by combining the two regression equations.
We certify that all applicable institutional and governmental regulations concerning the ethical use of human volunteers were followed during this research. This study was approved by the University of Navarra Clinic Review Committee.
The average CCT measurements by Orbscan-II and Topcon NCSM were 447.55±49.78 μm (range, 343–548 μm) and 461.38±35.35 μm (range, 392–540 μm), respectively, a difference that reached statistical significance (P<0.0001). The Orbscan-II readings were lower than those of the Topcon NCSM by an average of 13.83±22.31 μm (95% confidence interval, 9.77–17.09 μm). Corneal opacification was almost non-existent (median and IR, 0 gray levels (range, 0–3)).
A Bland–Altman plot, which was created to assess the difference in individual measurement as a function of the mean of two measurements (Figure 1a), revealed poor agreement due to a systematic bias, and the crude LoA were also too wide (87.45 μm; range: −29.89 μm to 57.53 μm). Nevertheless, the distribution of the difference between methods was approximately normal (Figure 1b).
We also found an inverse association between the average of both measurements and the difference between Topcon NCSM and Orbscan-II for CCT measurements (Figure 2a); the regression of difference on average gave a significant relationship (P<0.01):
Therefore, there was a trend in the bias, a tendency for the mean difference to decrease with increasing magnitude. The regression-based 95% LoA:
are shown in Figure 2a and exhibit almost coincident significant slopes (0.351 and 0.355, both P<0.01). The residuals from the regression of difference on average had a normal distribution (Figure 2b), which indicates the suitability of this method for this data set. The regression-based 95% LoA were also rather wide (63.72 μm; range: ±31.86 μm).
An accurate assessment of the CCT is essential in several clinical situations, especially for refractive surgery. LASIK currently is the most popular technique; thus, precise corneal thickness measurements are mandatory to reduce the risk of complications related to refractive surgery. Erroneous pachymetry measurements might mislead the clinical decision making regarding LASIK enhancement, because retreatment can be performed only when biomechanical corneal stability has been confirmed and corneal thickness allows for further ablation to avoid keratectasia.6 Measurement errors also can result in miscalculation of the IOL power in patients who have undergone LASIK7 and might affect the screening of patients with glaucoma due to a reduced IOP measurement.8
Although ultrasound pachymetry is the most commonly used method in clinical practice, access to accurate non-invasive pachymetry is important to reduce the risk of corneal epithelial damage or flap displacement resulting from probe contact, and to avoid the risk of microbial contamination during follow-up of patients after LASIK.2, 4, 13 Therefore, non-contact methods have been developed to avoid these complications.
In the current study, the results of non-contact pachymetry showed that on average Orbscan-II provides lower CCT values than Topcon NCSM in patients who have undergone myopic LASIK. Our results agree with those obtained by Kawana et al,3 which also showed Orbscan-II pachymetric underestimation by 22.3 μm as compared with Topcon NCSM after LASIK. In the current study, Bland–Altman plots showed that Orbscan-II tends to underestimate CCT as compared with Topcon NCSM, which is defined as a systematic bias. This bias in measuring CCT using different acquisition methods in healthy unoperated corneas was reported previously; Tam and Rootman30 compared CCT measurements using specular microscopy and ultrasound and reported a systematic bias towards higher CCT values using specular microscopy. Similar underestimation was also described when pathologically thinned corneas in keratoconus patients were measured using different acquisition techniques, scanning-slit/Placido disc topography and Topcon NCSM.14
In our study, the Bland–Altman plot also showed a downward trend of the scatter plot; therefore, there is a tendency for the mean difference to fall with higher magnitudes when the Topcon NCSM and Orbscan-II CCT measurements are compared. Although the regression-based LoA improved the data fit in comparison with the crude LoA, which ignored this relationship, both 95% LoA were too wide (63.72 and 87.45 μm) for the two pachymetric methods to be considered interchangeable. Chakrabarti et al2 and Cheng et al31 also reported such a tendency when scanning-slit and ultrasound techniques were compared after LASIK. This type of bias was also seen in normal corneas when Amano et al32 studied the interchangeability of scanning-slit and ultrasound pachymetric methods. They found that Orbscan-II tended to underestimate lower CCT values and overestimate higher CCT values, although the difference was not significant.
The discrepancy in measurements with Orbscan-II and Topcon NCSM after LASIK might be attributed to their distinct methods of acquiring data. This hypothesis about the discrepancy in measurements might be similar to those in other studies that compared Orbscan-II pachymetry with ultrasound pachymetry, which also showed Orbscan-II underestimation in patients who underwent LASIK.4, 5 The underestimation of Orbscan-II pachymetry measurements might be associated with alterations in the postoperative optical quality of the cornea.4, 33, 34 A significant correlation has been established between the grade of corneal transparency loss and the decrease in Orbscan-II pachymetry readings.33 However, in our series of patients assessed 9 months after surgery, the corneal transparency was comparable to that of a normal cornea. Although no patients had noticeable post-LASIK haze during the slit-lamp examination, confocal microscopy analysis shows increased cell density in LASIK patients,5 which produces loss of transparency. This loss increases the reflectivity in the interface with a consequent systematic measurement error.5 Another theory suggests that media opacities might bend the light rays passing through the cornea and cause displacement of the slit emitted by Orbscan-II, producing an inaccurate posterior corneal profile.4 Another hypothesis suggested that in ablated corneas the newly formed type-III collagen and proteoglycan debris-filled vacuoles resulted in a high level of light scatter, with an ensuing increase in the corneal refraction index.34 All authors agreed that loss of corneal transparency progressively decreases with time, thus improving the accuracy of Orbscan-II.4, 5
Another source of Orbscan-II pachymetry underestimation might be the change in corneal shape after LASIK. The normal healthy cornea is usually prolate, but after myopic LASIK the corneal curvature is altered and tends to become oblate.2 The reconstruction algorithms, using lower order polynomials, which create elevation data in the Orbscan-II may be properly designed in a normal corneal surface, but they might be ineffective in a post-LASIK corneal surface.2
The main limitation of the current study is that the reason for the variability between measurements showed a wide distribution between methods was not completely addressed, although it can be explained by the measurement repeatability of Orbscan-II being generally lower than that of Topcon NCSM in postmyopic LASIK patients.35 In addition, this study included only patients who had undergone LASIK to treat myopia, and, therefore, the conclusions cannot be applied to patients with hyperopia, in whom the postoperative corneal shape is more prolate. Finally, ultrasonic pachymetry was not performed in the study eyes, thus precluding direct comparison of both non-contact methods with the gold standard in order to find out which of the two is closer to the ‘true’ value. However, such a comparison has already been extensively reported,2, 3, 5, 10, 27, 31, 36, 37 and has been included in the discussion of our results with those of previously published studies.
In conclusion, these non-contact methods are not interchangeable in patients who underwent LASIK for myopia, because there is a systematic bias between acquisition methods and there is also a tendency for the mean difference to decrease with increasing magnitude. Thus, although the devices were calibrated appropriately, an acoustic factor was changed10 or a subtraction method applied,36 one cannot reliably replace the other. A tendency and a systematic bias also were described when each scanning-slit and specular pachymetry, respectively, were previously compared with ultrasonic pachymetry in patients who underwent LASIK.31, 37 Therefore, ophthalmologists should be aware that not only contact and non-contact pachymetry are not interchangeable after LASIK, but also that these non-contact pachymetry methods cannot be used interchangeably in these patients. This is important for the adequate medium- and long-term follow-up of the growing LASIK patient population.
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This work was supported in part by RETICS RD07/0062 (Oftalmología) and the Spanish Ministry of Education and Science through research project FIS2005-05020-C03-03.
The authors declare no conflict of interest.
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Cite this article
López-Miguel, A., Nieto, J., Díez-Cuenca, M. et al. Agreement of non-contact pachymetry after LASIK: comparison of combined scanning-slit/Placido disc topography and specular microscopy. Eye 24, 1064–1070 (2010). https://doi.org/10.1038/eye.2009.233
- central corneal thickness
- specular microscopic pachymetry
- Orbscan-II pachymetry