Development of a drug delivery device: using the femtosecond laser to modify cochlear implant electrodes.

Animal experiments suggest that pharmacological intervention could possibly enhance cochlear implant performance. One of the key aspects is therefore a drug delivery device for the human inner ear. The objective of this study was to investigate the possibility of using the femtosecond laser for modifying a cochlear implant electrode for the purpose of drug delivery to the cochlea. Using silicone sheets, the best parameters for creating defined channels at calculated diameters were investigated using a femtosecond laser. The results were transferred to a cochlear implant electrode array (Nucleus Contour). The capability of delivering substances through the drilled openings was tested in vitro. By variation of the output of the laser, spot distance, repetition rate, number of cycles and introducing several focus planes, it was possible to drill holes with nearly vertical walls in the silicone sheets. Transferring these data to the cochlear implant electrode resulted in prototypes for drug delivery with various openings along the array. The use of the femtosecond laser allows rapid modification and adaptation of designs to experimental prototypes of cochlear implant electrodes for the purpose of drug delivery to the inner ear.

[In vitro and in vivo investigations on the treatment of presbyopia using femtosecond lasers]. / In-vitro- und In-vivo-Untersuchungen zur Presbyopiebehandlung mit Femtosekundenlasern.

BACKGROUND: Ultrashort (femtosecond) laser pulses can generate precise cuts in biological tissue without damaging the surface. The application of femtosecond laser technology at the lens was evaluated with respect to a possible treatment of presbyopia. MATERIALS AND METHODS: Femtosecond laser lentotomy was performed on 150 pig lenses in vitro. Cutting geometry and laser settings were optimized to generate smooth cuts with a minimum of produced gas bubbles. Four rabbit lenses were treated afterwards in vivo and were controlled for 3 months post-treatment. The lenses were then extracted and evaluated. RESULTS: With suitable laser settings, light scattering due to residual gas bubbles could be almost completely avoided in pig lenses. A pulse energy of less than 1.2 microJ and a cutting geometry with spot separations of more than 5 microm are important. The rabbit lenses stayed macroscopically clear for 3 months in vivo. Only the cell structures directly adjacent to the laser focus were cut; structures 5-10 microm away appeared to be intact. No cataract formation occurred during this time. CONCLUSION: Femtosecond laser application allows precise and smooth cuts inside pig and rabbit lenses without damage to adjacent tissue.