Corneal cross-linking (CXL ) is actually the standard, low-invasive, safe treatment for patients affected by keratoconus [26, 27], with documented clinical progression or perceived risk of progression. Since younger patients usually show a fast progression of keratoconus [5], cross-linking in children and adolescents is actually indicated as soon as the diagnosis has been made [6].

Few authors reported clinical outcomes after CXL in pediatric patients affected by keratoconus. Caporossi et al. [4] published the largest study on pediatric CXL . This prospective study of 152 eyes of 77 patients 18 years old and under (range 10–18 years) treated by Epi-off CXL , at 36 month follow-up showed improvement in best corrected visual acuity (BCVA), K readings, asymmetry index values, and coma values. The authors then suggested that riboflavin-UVA-induced cross-linking stabilized the progression of keratoconus in all cases and led to functional improvement in 80 % of cases, with statistically significant results.

However, some are the considerations related to Epi-off technique in children: the severe pain induced by epithelial debridement and the consequent temporary visual loss that usually make postoperative management more complicated, the risk of postoperative complications (stromal haze [28] and infections [29]), and the variable period of visual recovery (2–6 months) [26, 30, 31].

Therefore, CXL performed without epithelial removal and by shortening the surgical time could represent a great advantage in children, providing local anesthesia and making the cross-linking treatment and its follow-up management more comfortable. In fact the preservation of the epithelial layer could avoid postoperative pain and visual impairment, as well as all complications related to epithelial debridement.

Recently, it has been proposed a new transepithelial CXL technique in which a iontophoresis system provides riboflavin delivery in corneal stroma [30, 31]. Iontophoresis is a noninvasive delivery system designed to enhance the penetration of molecules as well as riboflavin into tissue using a small electric current.

We published the first clinical study on transepithelial CXL by iontophoresis of riboflavin in pediatric patients [32]. We evaluated visual acuity, and refractive and corneal aberrometric changes through 15-month follow-up in 14 eyes of 14 pediatric patients (mean age 13 ± 2.4 [SD] years; range, 10–18 years) affected by keratoconus (stage 1 or 2 according to Amsler-Krumeich classification ). In opposite to previous reports on transepithelial technique in pediatric eyes [33, 34], we did not report keratoconus progression over 15 months; furthermore, we did not observe an improvement in refractive, topographic, and aberrometric parameters, excepting for BCVA.

Our unpublished data at 24-month follow-up, recorded in 27 eyes of 17 patients (mean age 14 ± 2.5), seem to confirm the same “trend” (Tables 5.1 and 5.2).

These early findings suggest that iontophoresis-assisted transepithelial CXL performed by means of riboflavin delivery could halt the keratoconus progression in pediatric patients up to 24 months. For sure longest follow-ups need to indicate if this technique could really become an alternative to Epi-off one, currently still considered the “gold standard.”

Intracorneal ring segments (ICRS ) have been demonstrated to be effective in improving visual acuity and reducing the refractive error and the mean keratometry in selected cases of keratoconic eyes of adult patients [35, 36]. However, up to now poor is the experience about ICRS implantation in pediatric patients. Estrada et al. [37] reported the outcomes of ICRS in the surgical correction of different levels of severity of keratoconus obtained in a large multicenter series of cases: 611 consecutive keratoconic eyes of 357 patients ranging in age from 10 to 73 years (mean age: 35.15 ± 11.62 years), but they did not separately analyze pediatric patients. Generally, ICRS are not preferred in the pediatric patients for aggressive nature of keratoconus, tendency of eye rubbing, and noncompliance. Kankariya et al. [38] observed that although the option of ICRS (less invasive) is not commonly utilized in pediatric eyes, in adolescent patients with end-stage keratoconus and imminent keratoplasty (more invasive), this option may be worth considering.

Pediatric keratoplasty still represents a very challenging surgery, generally performed when corneal opacification induces a visual deprivation [39]. The Penetrating Keratoplasty (PK) , actually the “gold standard” in pediatric keratoplasty, has shown a prognosis for graft survival of approximately 50–60 % [40, 41], mainly because of endothelial rejection [42, 43]. Deep anterior lamellar keratoplasty (DALK ) diffusion is currently limited in pediatric patients and few papers report outcomes after big-bubble DALK in children. Harding et al. [44] treated 13 eyes of 9 pediatric patients affected by partial thickness corneal scarring and mucopolysaccharidoses performing DALK with manual dissection, except for one eye that underwent big-bubble DALK with conversion to PK because of an intraoperative inadvertent perforation. Ashar et al. [45] observed that DALK is a feasible option in children with stromal corneal pathology. The authors evaluated 26 eyes: three underwent big-bubble procedure, while 23 layer-by-layer dissection.

Recently, the femtosecond solid-state laser was successfully used in several corneal surgical procedures and Buzzonetti et al. [46] proposed a standardized big-bubble technique in DALK assisted by femtosecond laser called Intrabubble . The laser provides a pre-Descemet’s plane lamellar dissection to a predefined corneal depth and the creation of a stromal channel, 50 μm above the thinnest corneal point, into which a smooth cannula for air injection can be introduced. The Intrabubble can be considered a standardized procedure: the femtosecond laser is accurate in achieving the desired corneal depth and the big-bubble, and provides good refractive outcomes for the good alignment of donor and recipient configuration. We successfully applied this technique also to pediatric patients [47] in an attempt to decrease the rejection percentage, to improve the refractive outcome, and thus provide an antiamblyopic effect.

We are using the IntraLase femtosecond laser (IntraLase FS Laser , Abbott Medical Optics, Inc.) that works by applying the applanation lens after obtaining a proper vacuum seal using a 10 mm diameter suction ring. However, this size can result too big to perform the treatment in smallest eyes. Thus, we experimented docking without suction ring by fixing the ocular bulb by four silk conjunctival stitches sutured over the skin (Fig. 5.2). This technique effectively provides a safe and effective applanation (Fig. 5.3).

Few authors investigated the application of femtosecond laser in pediatric keratoplasty [47–49], but long-term follow-up after big-bubble DALK has not yet been reported. In a comparison between pediatric patients that underwent big-bubble DALK using mechanical trephine (seven patients, mean age 11.4 ± 3.0; Group 1) or femtosecond laser (seven patients, mean age 11.6 ± 4.2; Group 2), 2 year after surgery (at least 16 months after complete suture removal) we observed that (unpublished data), respectively, BCVA was 0.7 ± 0.1D and 0.7 ± 0.2D (P = 0.3), spherical equivalent −4.5 ± 0.7D and −2.4 ± 1. (P = 0.09), and refractive astigmatism 4.8 ± 2.2D and 3.3 ± 1.3D (P = 0.2).