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Anterior Segment, Cataract Surgery
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Cataract Surgery and the LenSx® Femtosecond Laser System—2015 Update

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Published Online: Mar 20th 2015 US Ophthalmic Review, 2015;8(1):10–3 DOI: http://doi.org/10.17925/usor.2015.8.1.10
Authors: Sarah Makari, Richard Potvin
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Abstract
Article
Article Information
Abstract:
Overview

Femtosecond laser-assisted cataract surgery continues to gain popularity as clinicians adopt the technology with the desire to improve the safety and efficacy of cataract surgery. The technology continues to evolve as clinical experience points to improvements to better meet the needs of surgeons and patients. The effect of these system updates, and the increasing body of experience with femtosecond laser systems, has reduced complication rates and seen the technology applied to more challenging cases. This article provides an updated review of the LenSx® femtosecond Laser system, including recent system modifications and the most- recent published literature.

Keywords

Femtosecond laser, cataract surgery, docking, capsulotomy, fragmentation, phacoemulsification, incisions

Article:

Safe and effective cataract surgery is the goal for both patients and surgeons, with increasing demands for accurate refractive outcomes.1 Femtosecond laser-assisted cataract surgery (FLACS) is arguably the most significant change to cataract surgery since phacoemulsification, the adoption of which is in large part fueled by the desire for more precise and safe surgery with more predictable outcomes. In the past two years, the use of femtosecond laser systems has increased dramatically. An estimated 250,000 surgeries have been performed with these systems.1 One of the earliest and most-studied laser systems is the LenSx® Laser system (Alcon Laboratories, Inc., Aliso Viejo, California). The purpose of the current review is to update the reader on the most recent innovations of the LenSx® Laser system and the latest studies discussing clinical results.

The LenSx® Laser system uses an optical coherence tomography (OCT) and video imaging to view and plan the treatment steps, which are generally customizable by the surgeon2 and tailored to the patient’s needs.3 Clinical studies have demonstrated that the incorporation of the laser for lens fragmentation, capsulotomy, and incisions is safe and effective.2,4 Results from a large dataset showed that the surgical outcomes of FLACS was comparable to the best standard cataract surgical outcomes.2 The accurate positioning of capsulotomies appears to improve intraocular lens (IOL) overlap, which is expected to enhance IOL positioning and minimize IOL calculation errors.2 This is of particular importance for eyes with short or long axial lengths where calculating accurate IOL power is challenging and also for eyes receiving advanced technology IOLs where there are high expectations for precise refractive results.2

LenSx® Femtosecond Laser System Fundamentals
The steps performed with the LenSx® Laser may include capsulotomy and lens fragmentation, as well as corneal and arcuate incisions.2 Clinical studies have demonstrated that the level of precision for steps performed by femtosecond laser systems are superior to those performed manually.5 The recent updates to the LenSx® Laser system are designed to further improve accuracy and reduce the required phacoemulsification energy.6 A key feature of the LenSx® femtosecond Laser system is its Variable Numerical Aperture, which changes the focal characteristics of the laser to correspond with the location of the incision (cornea, lens capsule, or lens).6 This improves the overall laser efficiency.

Imaging
Proper targeting of the laser pulses is important in reducing the likelihood of complications.6 To help achieve proper targeting, the LenSx® Laser OCT provides clear images of the anterior segment and corneal cross section.6 The LenSx® Laser software update links with the VERION™ Image Guided System.7 The VERION™ system includes a diagnostic tool, called the VERION™ Reference Unit, which measures preoperative data including keratometry and pupillometry. Most importantly, it captures a high-resolution image of the eye (Measurement Module), which allows for reference features from the limbus, scleral vessels, and the iris to be used as anatomical landmarks.3,7 The reference data are transmitted directly to the VERION™ Digital Marker L attached to the laser system to prevent transcription errors.3,7 The VERION™ Digital Marker L allows for cyclorotation adjustments prior to creating the capsulotomy and incision: this allows the axis position to exactly match the intended location for incisions (see Figure 1).3,7

Docking
Docking the patient interface has been previously shown to be quick and successful.2 The LenSx® Laser system upgrade includes the SoftFit™ Patient Interface, which uses a soft contact lens that more closely matches the corneal curvature and reduces pressure on the eye,7,8 improving efficiency and eye centration.6 One study found that when the updated interface was used, there were no reported cases of anterior capsule tear or corneal fold and no additional applanation attempts were required.9 The SoftFit™ Patient Interface appears to result in lower complications compared with conventional cataract surgery results as well as with the older direct contact interface.9 The smaller size is also advantageous in small eyes because canthotomy, along with its associated risks, may be avoided.10 The docking mechanism does not require a suction ring or cup, elements that are more prone to movement and increased risk for suction loss.11

Shortening the femtosecond laser treatment duration can decrease the likelihood of suction breaks,12 pupil miosis, and conjunctival redness or hemorrhage.13 In a recent short case series, the LenSx® Laser system was shown to have much lower total suction-on time relative to the Catalys* and Victus* femtosecond laser systems.11 This could be attributed to the combination of the LenSx® Laser’s high-repetition rate and efficient incision algorithms.7

Capsulotomy
Studies demonstrate that the vast majority of laser capsulotomies are complete and free-floating.2,14 Laser capsulotomies have been previously shown to be well centered, more regularly shaped, stronger, with a more precise diameter and positioning as well as better circularity than manual capsulotomies.2 Recent updates to the LenSx® Laser system allow more flexibility in automated prepositioning of the capsulotomy.7 The capsulotomy can be centered over the dilated or undilated pupil, the visual axis, or the center of the limbus.7

Fragmentation
Previous lens fragmentation patterns included radial and cylinder patterns of varying diameters.7 The newly updated LenSx® Laser software is now capable of creating a grid fragmentation pattern of segments, called the “frag” pattern (see Figure 2).7 The advancement allows both size and spacing to be customized to meet the specific demands of a given cataract.6 Customization is particularly useful for denser cataracts6 where a greater degree of fragmentation may significantly reduce phacoemulsification energy and time requirements.7 The estimated time to complete a difficult fragmentation using the new pattern is about 40 to 45 seconds.3

Phacoemulsification
Previous studies have shown that FLACS may decrease phacoemulsification energy, potentially reducing endothelial cell loss and corneal edema when compared with conventional cataract surgery.15,16 A recent study demonstrated that effective phacoemulsification time and endothelial cell loss were lower in a FLACS-treated group compared with the conventional cataract surgical group: both groups had similar cataract grades and included grade 5 cataracts.17 Reduced phacoemulsification energy has the potential to improve visual acuity in the early postoperative period by reducing surgically induced corneal dema.18

Characteristics of Femtosecond Laser Incisions
Corneal incisions created with femtosecond laser systems have previously been shown to be precise and stable.2 FLACS corneal outcomes have also been formerly associated with fewer internal aberrations.2 Recently, incisions created by FLACS were shown to be predictable and minimally impact higher order aberrations in the eye.9,20 When compared with manual clear corneal incisions (CCIs), FLACS CCIs had reduced endothelial cell loss and edema, as well as better endothelium orientation and wound sealing in the corneal epithelium and endothelium.20 In addition, FLACS CCIs produce more predictable surgically induced astigmatism results when compared with manual CCIs and this was attributed to the laser allowing a more accurate and repeatable incision construction.20 The LenSx® Laser allows all incisions to be customized, including location, length, depth, and size.6

In one study, laser incisions appear to increase cell death relative to manual incisions but this has not been associated with a significant increase in inflammation.21 Another important consideration is that the laser suite is generally not sterile, which means that caution should be observed when moving patients after incisions have been created, to reduce the risk for infection and/or endophthalmitis.4,22

Clinical Results of Challenging Cases
FLACS can be applied in surgically challenging cases.4 Recent studies have demonstrated how certain complications can be mitigated and how incorporating FLACS in challenging cases may be useful.

FLACS shows promising results in patients with small pupils and intraoperative floppy iris syndrome (IFIS).4 Iris damage from manual manipulation during standard cataract surgery may be decreased when using FLACS.4 In a recent case report of a patient with small pupils and IFIS, standard cataract surgery was performed on one eye and FLACS with an iris expander was performed on the other eye.4 The laser-treated eye had no complications but the fellow eye had posterior capsule rupture during phacoemulsification.4 FLACS may be beneficial in eyes with IFIS because the capsulotomy and lens fragmentation are completed before making any incision, reducing the amount of time, phacoemulsification energy, and manipulation required to perform the cataract surgery once the eye is opened.4

FLACS was successfully performed in a patient with nanopthalmos,23 and in a patient with a shallow anterior chamber.18 In small eyes and/or eyes with a restricted surgical space, FLACS may provide better surgical results than conventional cataract surgery.4,23 Laser technology affords a more stable anterior chamber, reduces manual manipulation, and limits the disruption to surrounding tissue compared with standard cataract surgery.4,23 In addition, FLACS offers capsulotomy precision that can be maintained in the confined space.23 Complications in small eyes are expected to be low using FLACS due to decreased phacoemulsification time and power, with an associated reduction in endothelial cell loss likely.4,23

Previous studies show that FLACS may be successfully performed in postpenetrating keratoplasty cases.2 Recently, it has also been shown that mild corneal scarring, such as with radial keratometry scars, may be overcome by increasing laser energy.4 FLACS was also successfully performed in eyes after postrefractive surgery and postpenetrating keratoplasty.4 In these cases, the corneas may be very flat or steep with an increased risk for suction breaks or increased IOP; however, no such problems were reported.4 Instead, the postoperative spherical equivalent in the postrefractive eyes were comparable to untouched corneas, probably due to improved IOL position.4 FLACS was also noted to reduce phacoemulsification time and manual manipulation.4 This is advantageous in eyes with conditions such as Fuchs’ endothelial dystrophy, where FLACS may lower the likelihood that later corneal surgery will be required.4 Intraocular pressure (IOP) is known to increase when docking the patient interface.11 However, the average IOP rise observed with the SoftFit™ Patient Interface is <17 mmHg, which is considered a nominal risk.11,12 An examination of post-trabeculectomy eyes 6 months after FLACS showed that the bleb, IOP, visual fields, and OCT retinal nerve fiber layer findings were stable.4 In all reported cases, the docking with the LenSx® Laser SoftFit™ Patient Interface was uneventful without intrableb hemorrhage.4 Furthermore, a patient suffering from phacomorphic glaucoma underwent uneventful FLACS using the LenSx® femtosecond Laser system.18 FLACS may also decrease zonular stress in pseudoexfoliation syndromes by improving capsular strength and reducing lens rotation.4

Previous studies have suggested improved visual results with FLACS relative to standard cataract surgery in patients undergoing combined vitrectomy and cataract surgery.2 A recent study also found that phacovitrectomy cases were completed successfully without complications with better postoperative visual acuity compared with preoperative values.4

Conclusion
Recent research presented here builds on earlier results, looking at ways to further improve the safety, applicability, and accuracy of FLACS. Expectations for standard surgery have been established; new articles addressed more challenging cases.

There have been a number of recent changes to the LenSx® Laser, with results from these changes now available in the literature. The SoftFit™ Patient Interface was reported to reduce complications and improve capsulotomy results. The efficiency of the LenSx® Laser system has been improved through the introduction of a variety of new fragmentation patterns. Continued clinical evaluation of the FLACS procedure and the LenSx® Laser system will drive the continuous improvement of both.

Article Information:
Disclosure

Sarah Makari, OD, and Richard Potvin, MASc, OD, are employees of Science in Vision, Akron, NY, US, which is a consultant to Alcon Laboratories, Inc.

Correspondence

Richard Potvin, MASc, OD, 6197 Dye Road, Akron, NY 14001, US. E: rick@scienceinvision.com

Support

Alcon sponsored the publication of this promotional piece and is responsible for its content along with Sarah Makari, OD, and Richard Potvin,
MASc, OD. Science in Vision received funding from Alcon to support the preparation of this manuscript. Neither author has any financial interest in any products mentioned.
The content has been independently peer reviewed and verified by the US Ophthalmic Review publication process.

Access

This article is published under the Creative Commons Attribution Noncommercial License, which permits any noncommercial use, distribution, adaptation, and reproduction provided the original author(s) and source are given appropriate credit.

Received

2014-09-08T00:00:00

References

  1. B erdahl JP, Jensen MP, The business of refractive laser assisted cataract surgery (ReLACS), Curr Opin Ophthalmol, 2014;25:62–70.
  2. Potvin R, Makari S, Cataract surgery and the LenSx® femtosecond laser system, US Ophthalmic Review, 2013;6:89–93.
  3. Mackool RJ, Mackool RJ JR, Evolving technology: the LenSx® Laser, Cataract and Refractive Surgery Today [Insert], April 4–6, 2014.
  4. Martin AI, Hodge C, Lawless M, et al., Femtosecond laser cataract surgery: challenging cases, Curr Opin Ophthalmol, 2014;25:71–80.
  5. Alio JL, Soria F, Abdou AA, Femtosecond laser assisted cataract surgery followed by coaxial phacoemulsification or microincisional cataract surgery: differences and advantages, Curr Opin Ophthalmol, 2014;25:81–8.
  6. Chapman J, Incision precision with the LenSx® Laser, Cataract and Refractive Surgery Today [Insert], 2014;6–8.
  7. Sarayba M, The LenSx® Laser: Built for continual innovation, Cataract and Refractive Surgery Today [Insert], April 4–6, 2014.
  8. Kohnen T, Klaproth OK, Ostovic M, et al., Morphological changes in the edge structures following femtosecond laser capsulotomy with varied patient interfaces and different energy settings, Graefes Arch Clin Exp Ophthalmol, 2014;252:293–8.
  9. Mayer WJ, Klaproth OK, Ostovic M, et al., Femtosecond laserassisted lens surgery depending on interface design and laser pulse energy: Results of the first 200 cases, Ophthalmologe, 2014;111:1172–7.
  10. Abell RG, Howie AR, Vote BJ, Lateral canthotomy for femtosecond laser-assisted cataract surgery in infants, J Cataract Refract Surg, 2014;40:167–8.
  11. Yeoh R, Practical differences between 3 femtosecond phaco laser platforms, J Cataract Refract Surg, 2014;40:510.
  12. Donaldson KE, Braga-Mele R, Cabot F, et al.; ASCRS Refractive Cataract Surgery Subcommittee, Femtosecond laser-assisted cataract surgery, J Cataract Refract Surg, 2013;39:1753–63.
  13. Nagy ZZ, Takacs AI, Filkorn T, et al., Complications of femtosecond laser-assisted cataract surgery, J Cataract Refract Surg, 2014;40:20–8.
  14. Abell RG, Davies PE, Phelan D, et al., Anterior capsulotomy integrity after femtosecond laser-assisted cataract surgery, Ophthalmology, 2014;121:17–24.
  15. Nagy Z, Takacs A, Filkorn T, Sarayba M, Initial clinical evaluation of an intraocular femtosecond laser in cataract surgery, J Refract Surg, 2009;25:1053–60.
  16. Takács AI, Kovács I, Miháltz K, et al., Central corneal volume and endothelial cell count following femtosecond laser-assisted refractive cataract surgery compared to conventional phacoemulsification, J Refract Surg, 2012;28:387–91.
  17. Mayer WJ, Klaproth OK, Hengerer FH, Kohnen T, Impact of crystalline lens opacification on effective phacoemulsification time in femtosecond laser-assisted cataract surgery, Am J Ophthalmol, 2014;157:426–32.
  18. Kránitz K, Takács AI, Gyenes A, et al., Femtosecond laserassisted cataract surgery in management of phacomorphic glaucoma, J Refract Surg, 2013;29:645–8.
  19. Alió JL, Abdou AA, Soria F, et al., Femtosecond laser cataract incision morphology and corneal higher-order aberration analysis, J Refract Surg, 2013;29:590–5.
  20. Mastropasqua L, Toto L, Mastropasqua A, et al., Femtosecond laser versus manual clear corneal incision in cataract surgery, J Refract Surg, 2014;30:27–33.
  21. Mayer WJ, Klaproth OK, Hengerer FH, et al., In vitro immunohistochemical and morphological observations of penetrating corneal incisions created by a femtosecond laser used for assisted intraocular lens surgery, J Cataract Refract Surg, 2014;40:632–8.
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