We noticed you’re blocking ads

Thanks for visiting CRSTG | Europe Edition. Our advertisers are important supporters of this site, and content cannot be accessed if ad-blocking software is activated.

In order to avoid adverse performance issues with this site, please white list https://crstodayeurope.com in your ad blocker then refresh this page.

Need help? Click here for instructions.

Cataract Surgery | Jan 2011

BONUS FEATURE: The Promise of Precise LRIs With the Femtosecond Laser

Femtosecond LRIs have the potential to increase the accuracy and predictability of astigmatism correction at the time of cataract surgery or refractive lens exchange.

An astigmatically neutral postoperative result is a major goal of modern small-incision phacoemulsification and refractive lens surgery. Techniques and techologies including carefully planned incision locations, intraoperative limbal relaxing incisions (LRIs),1-89-11 LRIs are widely performed for low dioptric corrections.12 They preserve the optical qualities of the cornea, do not cause significant patient discomfort, and are sufficiently effective for correcting lower levels of astigmatism. The limbal location of these incisions results in a consistent 1:1 coupling ratio13 that causes little change in spherical equivalent and eliminates the need to change implant power. Gills1 and Osher14 were early advocates of these incisions.

Successfully placed LRIs reduce cylinder without an overcorrection or axis shift. Determining the exact location of the cylinder, however, is often challenging. Keratometry, refraction, and corneal topography may not correlate. Of these, corneal topography has been the most helpful and is most often used to guide the surgical plan and to evaluate the postoperative result. In addition to diagnostic methodology, incision construction technique has also varied among surgeons.15 Peripheral corneal pachymetry, incision depth, and optical zone size (distance from the visual axis or corneal apex to the incisions) appear to play important roles in effectiveness. Variability in results is likely multifactorial, but a consistent technique is the minimum requirement for beginning to understand the variation in response.

BENEFITS OF AUTOMATION
Recently, femtosecond laser keratotomy has been introduced as a more precise way to achieve incisional correction of astigmatism, including high degrees of astigmatism in postkeratoplasty eyes.16-18 Abbey et al demonstrated correction of about 2.50 to 3.00 D of naturally occurring refractive astigmatism with femtosecond laser astigmatic keratotomy.19

Common sense suggests that automating the incisional technology and thus eliminating the variability in performance that is an attribute of manual incision construction will lead to greater reproducibility in results.

The potential for femtosecond LRIs to place the photodisruptive cutting effect at the right orientation and to make cuts of the correct length and depth to create the desired refractive effect should lead to greater consistency of outcomes. The laser’s ability to make sub-Bowman’s incisions may have benefits in limiting the effect of healing, which can be responsible for regression of the effect. Sub- Bowman’s incisions may also improve patient comfort postoperatively. Overall, laser-mediated LRIs should make outcomes more predictable and reliable for all surgeons.

UNDERSTANDING THE INCISION EFFECT
To develop LRIs with femtosecond technology, it is necessary to model the cornea so that changes induced by the incisions can be predicted and the most effective treatment algorithm selected. The model should be able to predict the published outcomes of current surgical methods so that laser treatments can be compared. Changes in topography should be predictable and confirmed on animal and human cadaver eye models. Finally, clinical testing should confirm the outcomes predicted from the model.

Nichamin and coworkers developed a corneal model to study the effects of LRIs (Figure 1). The model includes five layers with different material properties: Bowman’s membrane (one layer), stroma (three layers), and Descemet’s membrane (one layer). These reflect the mechanical properties of the cornea at different depths. An incision profile created for use with the corneal model was well defined in terms of arc length, depth and profile, and optic zone diameter. To assess the stress distribution of the incisions, a nominal IOP must be selected. Outcomes will vary depending on the IOP selected (Figure 2).

In using this model to study the effects of LRIs, we assessed the effects of age, stiffness, and various incision lengths and optic zones. Figure 3 shows the results in simulated 25- and 75-year-old corneas. The change in refractive cylinder increases with the arc length of the incision and is greater in the younger cornea than the older one.

The regression of corneal power after incisional surgery has been studied for radial keratotomy; there is a tendency for greater regression with younger age. Initial surgery must therefore overcompensate the intended correction to allow for regression; the amount of compensation will be smaller for older patients. At 3 months, the model predicts 39% regression for a 90° arc length at age 25 but only 25% regression at age 45. For shorter arc lengths the difference is greater: 65% for a 30° arc in a 25-year-old and 42% in a 45-year-old. When the finite element analysis model data prediction is compared with the Nichamin nomogram for with-the-rule astigmatism, there is close correlation for both younger and older corneas.20

CORNEAL RESPONSE
The use of the femtosecond laser to create LRIs introduces the possibility to create intrastromal incisions, which may mitigate the effects of healing on regression. In our corneal model, as expected, the change in refractive power is reduced compared with surface incisions, but the results can be enhanced by using multiple incisional arcs and differing incision heights (ie, how much of the intrastromal tissue is ablated).20

Ex-vivo work has demonstrated the feasibility of these procedures on animal eyes, in which corneal power can be verified using instruments such as the Keratron Scout (Optikon 2000 Industrie, Rome). Finite element analysis modeling has confirmed the corneal response to LRIs. Younger corneas showed a greater response to incisional surgery but also regressed more postoperatively.20

The model and early ex-vivo studies suggest that femtosecond LRIs produce results equivalent to those of manual LRIs. The effect of sub-Bowman’s incisions have been demonstrated in animals.

INTRAOPERATIVE ABERROMETRY
Modeling and automation may reduce variation in technique, but they do not take into account variation in response. A recent advance in astigmatism management may prove complementary to the femtosecond laser in this regard. ORange (WaveTec Vision, Aliso Viejo, California) is an intraoperative aberrometer based on Talbot Moiré interferometry that provides wavefrontguided refraction during cataract and refractive lens exchange surgery (Figure 4). The device analyzes sphere, cylinder, and axis and enables surgeons to make decisions regarding the need to reduce residual and/or induced astigmatism while performing the procedure. Intraoperative aberrometry is used to measure the effectiveness of incision construction and allow enhancement of the incisions if indicated.

A retrospective study has shown that wavefront-guided LRIs at the time of surgery have a positive effect on the rate of postoperative laser enhancement.21 In a group of 37 eyes of patients who were not measured with the device, six eyes (16%) went on to LASIK enhancement. In a group of 30 eyes of patients who were measured with the device, one eye (3%) went on to LASIK enhancement. Eight of the 30 eyes (27%) had received intraoperative LRIs during the primary procedure based on aberrometry findings. The groups had similar pre- and postoperative characteristics.

CONCLUSION
The drive toward greater accuracy and predictability in the outcomes of our incisional surgery for astigmatism represents a tremendous benefit for our patients because they will be able to achieve their desired results with a single procedure. Ultimately, our abilities to titrate and enhance precise LRIs may prove superior to outcomes achieved with toric IOLs for most degrees of astigmatic correction.

Mark Packer, MD, FACS, CPI, is a Clinical Associate Professor at the Casey Eye Institute, Department of Ophthalmology, Oregon Health & Science University, and is in private practice at Drs. Fine, Hoffman & Packer, LLC, Eugene, Oregon. He states that he is a consultant to LensAR, Inc., and to WaveTec Vision Systems, Inc. Dr. Packer may be reached at tel: +1 541 6872110; e-mail: mpacker@finemd.com.

  1. Gills JP.Treating astigmatism at the time of cataract surgery.Curr Opin Ophthalmol.2002;13(1):2-6.
  2. Kohnen T,Koch DD.Methods to control astigmatism at the time of cataract surgery.Curr Opin Ophthalmol.1996;7:75-80.
  3. Nichamin LD. Astigmatism management at the time of cataract surgery.In:Krachmer JH,Mannis MJ,Holland EJ,eds. Cornea.2nd edition. St.Louis:Mosby;2004:7-11.
  4. Nichamin LD.Astigmatism control.Ophthalmol Clin N Am.2006;19(4):485-493.
  5. Amesbury EC,Miller KM.Correction of astigmatism at the time of cataract surgery.Curr Opin Ophthalmol. 2009;20(1):19-24.
  6. Müller-Jensen K,Fischer P,Siepe U.Limbal relaxing incisions to correct astigmatism in clear corneal cataract surgery.J Refract Surg.1999;15(5):586-589.
  7. Budak D,Friedman NJ,Koch DD.Limbal relaxing incisions with cataract surgery. J Cataract Refract Surg.1998;24:503- 508.
  8. Kaufmann C,Peter J,Ooi K,et al.Limbal relaxing incisions versus on-axis incisions to reduce corneal astigmatism at the time of cataract surgery.J Cataract Refract Surg.2005;31(12):2261-2265.
  9. Horn JD.Status of toric intraocular lenses.Curr Opin Ophthalmol.2007;18(1):58-61.
  10. Mendicute J,Irigoyen C,Aramberri J,et al.Foldable toric intraocular lens for astigmatism correction in cataract patients.J Cataract Refract Surg.2008;34(4):601-607.
  11. Bauer NJ,de Vries NE,Webers CA,et al.Astigmatism management in cataract surgery with the AcrySof toric intraocular lens.J Cataract Refract Surg.2008;34(9):1483-1488.
  12. Duffey RJ,Leaming D.US trends in refractive surgery:2003 ISRS/AAO survey.J Refract Surg.2005;21(1):87-91.
  13. Faktorovich EG,Maloney RK,Price FW Jr.Effect of astigmatic keratotomy on spherical equivalent:results of the Astigmatism Reduction Clinical Trial.Am J Ophthalmol.1999;127(3):260-269.
  14. Osher RH.Paired transverse relaxing keratotomy:a combined technique for reducing astigmatism.J Cataract Refract Surg.1989;15(1):32-37.
  15. Goldberg L.Improving LRI results:two doctors discuss their techniques.Ophthalmology Management.December 2007.http://www.ophmanagement.com/article.aspx?article=101165. Accessed December 2,2010.
  16. Yoo S.Femtosecond laser astigmatic keratotomy.Refractive Eyecare.April 2010. http://www.refractiveeyecare.com/articles/femtosecond-laser-astigmatic-keratotomy-241.html.Accessed December 2,2010.
  17. Kymionis GD,Yoo SH,Ide T,et al.Femtosecond-assisted astigmatic keratotomy for post-keratoplasty irregular astigmatism. J Cataract Refract Surg.2009;35(1):11-13.
  18. Kumar NL,Kaiserman I,Shehadeh-Mashor R,Sansanayudh W,Ritenour R,Rootman DS.IntraLase-enabled astigmatic keratotomy for post-keratoplasty astigmatism:on-axis vector analysis.Ophthalmology.2010;117(6):1228-1235.
  19. Abbey A,Ide T,Kymionis GD,et al.Femtosecond laser-assisted astigmatic keratotomy in naturally occurring high astigmatism.Br J Ophthalmol. 2009;93(12):1566-1569.
  20. Nichamin LD,Teuma EV.The use of femtosecond lasers to create corneal incisions.Paper presented at:the American Society of Cataract & Refractive Surgery Annual Symposium;April 9-14,2010;Boston.
  21. Packer M.Effect of intraoperative aberrometry on the rate of postoperative enhancement:retrospective study.J Cataract Refract Surg. 2010;36(5):747-755.

Jan 2011