Abstract
In femtosecond laser ophthalmic surgery tissue dissection is achieved by photodisruption based on laser induced optical breakdown. In order to minimize collateral damage to the eye laser surgery systems should be optimized towards the lowest possible energy threshold for photodisruption. However, optical aberrations of the eye and the laser system distort the irradiance distribution from an ideal profile which causes a rise in breakdown threshold energy even if great care is taken to minimize the aberrations of the system during design and alignment. In this study we used a water chamber with an achromatic focusing lens and a scattering sample as eye model and determined breakdown threshold in single pulse plasma transmission loss measurements. Due to aberrations, the precise lower limit for breakdown threshold irradiance in water is still unknown. Here we show that the threshold energy can be substantially reduced when using adaptive optics to improve the irradiance distribution by spatial beam shaping. We found that for initial aberrations with a root-mean-square wave front error of only one third of the wavelength the threshold energy can still be reduced by a factor of three if the aberrations are corrected to the diffraction limit by adaptive optics. The transmitted pulse energy is reduced by 17% at twice the threshold. Furthermore, the gas bubble motions after breakdown for pulse trains at 5 kilohertz repetition rate show a more transverse direction in the corrected case compared to the more spherical distribution without correction. Our results demonstrate how both applied and transmitted pulse energy could be reduced during ophthalmic surgery when correcting for aberrations. As a consequence, the risk of retinal damage by transmitted energy and the extent of collateral damage to the focal volume could be minimized accordingly when using adaptive optics in fs-laser surgery.
Highlights
Femtosecond laser induced optical breakdown (LIOB) is applied in ophthalmic surgery mainly for tissue incisions [1]
Plasma formation during optical breakdown is based on nonlinear absorption which relies on the irradiance distribution in the focal volume
Our results confirm that the threshold energy for femtosecond laser induced optical breakdown and the transmitted energy are reduced when using adaptive optics to correct for wave front aberrations
Summary
Femtosecond laser induced optical breakdown (LIOB) is applied in ophthalmic surgery mainly for tissue incisions [1]. The typically desired precise Gaussian profile for irradiance distribution is often impossible to realize as aberrations distort the wave front [2]. These aberrations can originate from numerous sources beginning at the laser system, to the optical pulse delivery system including focusing optics and contact glass plates, to the treated eye itself. Theses aberrations originate mainly from the light passage through distorting ocular media, especially the cornea and the crystalline lens, but can be introduced depending on the application. An oblique passage of the laser beam through the ocular media during microsurgery in the ocular periphery can contribute to the overall aberrations [4]
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