Intraocular photodisruption with picosecond and nanosecond laser pulses: tissue effects in cornea, lens, and retina.

PURPOSE Nd:YAG laser photodisruption with nanosecond (ns) pulses in the millijoule range is an established tool for intraocular surgery. This study investigates tissue effects in cornea, lens, and retina to assess whether picosecond (ps) pulses with energies in the microjoule range can increase the surgical precision, reduce collateral damage, and allow applications requiring more localized tissue effects than can be achieved with ns pulses. METHODS Both ps and ns Nd:YAG laser effects on Descemet's membrane, in the corneal stroma, in the lens, and at the retina were investigated in vitro in bovine and sheep eyes and in cataractous human lens nuclei. For each tissue, the optical breakdown threshold was determined. The morphology of the tissue effects and the damage range of the laser pulses were examined by light and scanning electron microscopy. The cavitation bubble dynamics during the formation of corneal intrastromal laser effects were documented by time-resolved photography. RESULTS The optical breakdown threshold for ps pulses in clear cornea, lens, and vitreous is, on average, 12 times lower than that for ns pulses. In cataractous lens nuclei, it is lower by a factor of 7. Using ps pulses, Descemet's membrane could be dissected with fewer disruptive side effects than with ns pulses, whereby the damage range decreased by a factor of 3. The range for retinal damage was only 0.5 mm when 200 microJ ps pulses were focused into the vitreous. Picosecond pulses could be used for corneal intrastromal tissue evaporation without damaging the corneal epithelium or endothelium, when the pulses were applied in the anterior part of the stroma. The range for endothelial damage was 150 microns at 80 microJ pulse energy. Intrastromal corneal refractive surgery is compromised by the laser-induced cavitation effects. Tissue displacement during bubble expansion is more pronounced than tissue evaporation, and irregular bubble formation creates difficulties in producing predictable refractive changes. CONCLUSIONS The use of ps pulses improves the precision of intraocular Nd:YAG laser surgery and diminishes unwanted disruptive side effects, thereby widening the field of potential applications. Promising fields for further studies are intrastromal corneal refractive surgery, cataract fragmentation, membrane cutting, and vitreolysis close to the retina.

[1]  C. Puliafito,et al.  Neodymium-YAG laser surgery on experimental vitreous membranes. , 1984, Archives of ophthalmology.

[2]  Josef F. Bille,et al.  Principles of operation and first clinical results using the picosecond IR laser , 1992, Photonics West - Lasers and Applications in Science and Engineering.

[3]  Reginald Birngruber,et al.  Intraocular Nd:YAG laser surgery: laser-tissue interaction, damage range, and reduction of collateral effects , 1990 .

[4]  F. Fankhauser,et al.  Clinical studies on high and low power laser radiation upon some structures of the anterior and posterior segments of the eye , 1982, International Ophthalmology.

[5]  C. A. Sacchi,et al.  Experimental Investigation of Optical Breakdown Thresholds in Ocular Media under Single Pulse Irradiation with Different Pulse Durations , 1986 .

[6]  A Vogel,et al.  Cavitation bubble dynamics and acoustic transient generation in ocular surgery with pulsed neodymium: YAG lasers. , 1986, Ophthalmology.

[7]  I. Kreissig,et al.  Indications for Q-Switched and Mode-Locked Nd: Yag Lasers in Vitreoretinal Pathology , 1991, European journal of ophthalmology.

[8]  R Birngruber,et al.  Mechanisms of intraocular photodisruption with picosecond and nanosecond laser pulses , 1994, Lasers in surgery and medicine.

[9]  R Birngruber,et al.  Picosecond optical breakdown: Tissue effects and reduction of collateral damage , 1989, Lasers in surgery and medicine.

[10]  J. Emery,et al.  Extracapsular cataract surgery , 1983 .

[11]  Peter A. Barnes,et al.  LASER INDUCED UNDERWATER SPARKS , 1968 .

[12]  D E Gaasterland,et al.  Threshold for retinal damage associated with the use of high-power neodymium-YAG lasers in the vitreous. , 1983, American journal of ophthalmology.

[13]  F. Fankhauser,et al.  Vitreolysis with the Q-switched laser. , 1985, Archives of ophthalmology.

[14]  E W Norton,et al.  Accommodation of an endocapsular silicone lens (Phaco-Ersatz) in the nonhuman primate. , 1987, Ophthalmology.

[15]  James G. Fujimoto,et al.  Time-resolved measurements of picosecond optical breakdown , 1989 .

[16]  D J Cinotti,et al.  The Nd:YAG laser in ophthalmology. , 1985, New Jersey medicine : the journal of the Medical Society of New Jersey.

[17]  C. Puliafito,et al.  Neodymium yttrium aluminum garnet laser surgery on experimental vitreous membranes , 1984 .

[18]  S. Logani,et al.  Nd:YAG laser photodisruption of the lens nucleus before phacoemulsification. , 1987, American journal of ophthalmology.

[19]  Werner Lauterborn,et al.  Optical and acoustic investigations of the dynamics of laser-produced cavitation bubbles near a solid boundary , 1989, Journal of Fluid Mechanics.

[20]  G. Brown,et al.  Treatment of diabetic traction retinal detachment with the pulsed neodymium-YAG laser. , 1985, American journal of ophthalmology.

[21]  D Aron-Rosa,et al.  Use of the neodymium-YAG laser to open the posterior capsule after lens implant surgery: a preliminary report. , 1980, Journal - American Intra-Ocular Implant Society.

[22]  J KESSLER,et al.  EXPERIMENTS IN REFILLING THE LENS. , 1964, Archives of ophthalmology.

[23]  John Taboada Micron-sized laser-supported plasma effect applied to microsurgery , 1992, Photonics West - Lasers and Applications in Science and Engineering.