From basic studies of excimer laser refractive procedures, it is known that compensatory wound healing takes place after surgery. In photorefractive surgery, stromal remodelling and new synthesis of collagen, which is laid down on the bared stroma, can affect the refractive reproducibility. After PRK and LASIK for myopia, considerable thickening of the central epithelium takes place, and this will also reduce the net refractive effect of the procedures. Up to a 10 μm increase in central epithelium has been documented by confocal microscopy over time after correction for approximately 7 diopters of myopia [3]. This is acknowledged as a result of the normal beneficial smoothing effect of the epithelium to reduce abrupt changes in the stromal surface shape. After SMILE, central epithelial thickening have also been documented by optical coherence tomography, but the thickening amounted to only 6 μm on average with considerable variation between eyes (range −2 to 13 μm) [12]. Using very high-frequency ultrasound, epithelial thickening of 15 μm has, however, been observed after SMILE [8]. A 6-μm increase in epithelial thickness corresponds to a regression of approximately 0.4 dioptres. Some of the variation in epithelial thickness changes is caused by measurement inaccuracy. However, individual differences between patients and eyes concerning epithelial hyperplasia undoubtedly are a major contributor to variations in refractive predictability after SMILE. Compared with LASIK, the effective optical zone is larger after SMILE, and this possibly explains that compensatory epithelial thickening is less after SMILE.

In SMILE, the majority of the anterior lamellae are preserved compared to the anatomical situations after LASIK, and as such, the SMILE-operated cornea is more biomechanically intact compared with the post-LASIK cornea. Mathematical simulations have confirmed this ([5], Chap. 13). The effect of individual variations in corneal biomechanics and susceptibility to development of corneal ectasia, in theory, should be less in SMILE compared with LASIK-treated eyes. Today, corneal ectasia development after SMILE has not been published although more than 100,000 procedures have been performed worldwide. Overall, it is fair to expect that individual variations in corneal biomechanical properties are less prone to affect refractive predictability after SMILE compared with LASIK.

In 2012, we published a paper on predictors for the outcome of SMILE [1]. Three hundred thirty-five patients with myopia up to 10 diopters (spherical equivalent refraction) and astigmatism up to 2 diopters were treated with small-incision lenticule extraction in both eyes (670 eyes) and followed for 3 months. The preoperative spherical equivalent averaged −7.19 D ± 1.30 D. In eyes with emmetropia as target refraction, 84.0 % obtained an uncorrected distance visual acuity ≤0.10 (logMAR) at 3 months. Mean corrected distance visual acuity improved from −0.03 to −0.05 (logMAR) (p < 0.01). 2.4 % (16 eyes) lost two or more lines of corrected distance visual acuity. The achieved refraction was 0.25 ± 0.44 D less than attempted after 3 months, and 80.1 % (537 eyes) and 94.2 % (631 eyes) were within ±0.5 and ±1.0 diopters of attempted, respectively. Multiple linear regression analyses revealed that spherical equivalent undercorrection was predicted by increasing patient age (0.1 D per decade; p < 0.01) and steeper corneal curvature (0.04 D per D; p < 0.01). The safety and efficacy of the procedure were minimally affected by age, gender, and simultaneous cylinder correction. In conclusion, the findings of an undercorrection of 0.25 diopters and small effects of patient age and corneal curvature suggest that the standard nomogram for SMILE needs only minor adjustments. However, this conclusion is related to a standard cup thickness (up to 130 μm) only. As stated in Chap. 12, thicker caps (or deeper lenticules) might need some adjustments in refractive data entered into the laser.

Here, we now extend the study to include more than 1,500 eyes treated for myopia with SMILE at Department of Ophthalmology, Aarhus University Hospital. The cohort of patients is the same as described by Ivarsen et al. [4]. After a thorough preoperative evaluation by trained optometrists, patients were thoroughly informed about keratorefractive surgery, including known side effects and complications.

From January 2011 to March 2013, 1,800 eyes of 922 consecutive patients were operated with SMILE at the Department of Ophthalmology, Aarhus University Hospital, Denmark. Patients were seen the day after surgery and again after 3 months; however, only 808 patients (1,574 eyes) attended the 3-month follow-up visit. The average preoperative patient characteristics are given in Table 15.1.

Patients underwent SMILE treatment by the VisuMax^® femtosecond laser. At the 12-o’clock position, a 30–60° incision was created for lenticule extraction. Lenticule diameter ranged from 6.0 to 7.0 mm, and the lenticule side cut was 15 μm in all cases. Cap diameter varied from 7.3 to 7.7 mm, and the intended cap thickness was 110–130 μm. All cases were operated with one of two different laser energy settings. Setting 1 used a laser cut energy index of 25–27 (~130 nJ) and a spot spacing of 2.5–3.0 μm. In setting 2, a laser cut energy index of 34 (~170 nJ) and a spot spacing of 4.5 μm were used. Laser setting 1 was used for surgery in 656 eyes, and setting 2 was used in 1,144 procedures. After the laser treatment, a blunt spatula was used to break any remaining tissue bridges, allowing the lenticule to be removed with a pair of forceps. After removal of the lenticule, the stromal pocket was flushed with saline, and patients received 1 drop of chloramphenicol and 1 drop of diclofenac.