Your search keyword '"Josef F. Bille"' showing total 5 results

1. Confocal fluorescence microscopy for minimal-invasive tumor diagnosis

Author

M. H. Götz, M. Zenzinger, Josef F. Bille, and Stefan Fischer

Subjects

Materials science, Microscope, Physics and Astronomy (miscellaneous), medicine.diagnostic_test, business.industry, Confocal, General Engineering, General Physics and Astronomy, Immunofluorescence, Fluorescence, Signal, law.invention, Ultrashort laser, Optics, law, Light sheet fluorescence microscopy, Fluorescence microscope, medicine, business, Biomedical engineering

Abstract

The goal of the project “stereotactic laser-neurosurgery” is the development of a system for careful and minimal-invasive resection of brain tumors with ultrashort laser pulses through a thin probe. A confocal laser-scanning-microscope is integrated in the probe. In this paper, the simulation of its optical properties by a laboratory setup and the expansion by the ability for fluorescence microscopy are reported. For a valuation of the imaging properties, the point-spread-function in three dimensions and the axial depth-transfer-function were measured and thus, among other things, the resolving power and the capacity for depth discrimination were analysed. The microscope will enable intra-operative detection of tumor cells by the method of immunofluorescence. As a first model of the application in the brain, cell cultures, that fluorescein-labelled antibodies were bound to specifically, were used in this work. Due to the fluorescence signal, it was possible to detect and identify clearly the areas that had been marked in this manner, proving the suitability of the setup for minimal-invasive tumor diagnosis.

Published

2000

2. Non-thermal ablation of neural tissue with femtosecond laser pulses

Author

Frieder Loesel, N. Suhm, Josef F. Bille, M. H. Götz, Tibor Juhasz, Christopher Horvath, F. Noack, and Joerg P. Fischer

Subjects

Femtosecond pulse shaping, Materials science, Dye laser, Physics and Astronomy (miscellaneous), business.industry, medicine.medical_treatment, Ti:sapphire laser, General Engineering, General Physics and Astronomy, Laser, Ablation, law.invention, X-ray laser, Optics, law, Ultrafast laser spectroscopy, Femtosecond, medicine, Optoelectronics, business

Abstract

Nonthermal in vitro ablation of bovine neural tis- sue by using laser-induced optical breakdown generated by ultrashort laser pulses, with durations from 100 fs to 35 ps and pulse energies of up to 165mJ, has been investigated. The experiments were performed at wavelengths ranging from 630 to 1053 nm by using a femtosecond Ti:Sapphire laser, a femtosecond dye laser, and a picosecond Nd:YLF laser sys- tem. Tissue ablations have been achieved by focusing the laser beam on the surface of the tissue, to a spot diameter of 5- 20mm, resulting in the generation of a microplasma. Laser pulses from the Ti:Sapphire laser with 140 fs duration showed a two times higher efficiency of ablation than the longer 30 ps pulses from a Nd:YLF laser with an identical pulse energy. At pulse energies of 140mJ, single pass excisions deeper than 200mm were generated by the 140 fs pulses. In addition, the fluence at threshold of the ablation was found to be reduced for shorter pulse durations. For 3p slaser pulses at 630 nm, we measured the fluence at threshold to be about 5: 3J =cm 2 ; for 100 fs pulses from the same laser the experimental thresh- old was at 1: 5J =cm 2 . Histopathological examinations and scanning electron micrographs confirm the high quality of the excisions. No sign of significant thermal damage was ob- served.

Published

1998

3. Time resolved imaging of the surface ablation of soft tissue with IR picosecond laser pulses

Author

Joerg P. Fischer, Josef F. Bille, and Tibor Juhasz

Subjects

Shock wave, Chemistry, medicine.medical_treatment, Physics::Medical Physics, Analytical chemistry, General Chemistry, Plasma, Laser, Ablation, law.invention, Shock (mechanics), Amplitude, Impact crater, Physics::Plasma Physics, law, medicine, General Materials Science, Irradiation, Atomic physics

Abstract

Time resolved video photographs have been taken in order to investigate plasma induced surface ablation of soft tissue by infrared picosecond laser pulses with energies of about 1 mJ. The emission and propagation of shock waves in the irradiated tissue as well as in the surrounding air environment was studied. The pressure amplitudes of the shock transients were determined from the measured shock velocities. A decay of the pressure amplitude below 100 MPa was observed within a distance of about 200 \(\mu\)m from the center of laser induced optical breakdown. The dynamics of the ablation crater and the ejection of the ablation fragments was studied on a larger timescale. The maximum expansion of the ablation crater was measured to be about 200 \(\mu\)m at temporal delays of 4–5 \(\mu \)s referring to the laser pulse. Furthermore, generation and propagation of a surface deformation wave was observed. Thus, we present a detailed and consistent description of all phenomena occuring during plasma induced surface ablation of soft tissue.

Published

1997

4. Ablation of neural tissue by short-pulsed lasers ? a technical report

Author

Volker Sturm, Frieder Loesel, M. H. Götz, Wolfgang Schlegel, Joerg P. Fischer, Roland Schröder, N. Suhm, and Josef F. Bille

Subjects

Pathology, medicine.medical_specialty, Brain model, business.industry, medicine.medical_treatment, Neurosurgery, Planning target volume, Brain, Ablation, Laser, law.invention, law, Picosecond, Femtosecond, Animals, Medicine, Cattle, Surgery, Thermal damage, Laser Therapy, Neurology (clinical), Irradiation, business, Biomedical engineering

Abstract

The basis for most laser applications in neurosurgery is the conversion of laser light into heat when the incident laser beam is absorbed by the tissue. Irradiation of neural tissue with laser light therefore leads to its thermal damage. However, due to the diffusion of heat energy into the surrounding tissue, often there is thermal damage to neural tissue outside the area of the target volume. These are the characteristics of thermal laser/tissue interaction. In this paper we discuss how we used three different short-pulsed lasers to achieve non-thermal ablation of neural tissue. Three different short-pulsed lasers were used to generate ultrashort laser pulses in the picosecond to femtosecond range. The interaction of such laser pulses with tissue was predicted to be nonthermal. The short-pulsed lasers were used for the ablation of neural tissue using an in vitro calf brain model. The histopathological examination of the lesions revealed that the neural tissue had been removed very precisely without any sign of thermal damage to the surrounding tissue.

Published

1996

5. Plasma-mediated ablation of brain tissue with picosecond laser pulses

Author

E. Kerker, Markolf H. Niemz, J. Dams, Frieder Loesel, C. Messer, Joerg P. Fischer, N. Suhm, Josef F. Bille, and M. H. Götz

Subjects

Materials science, Physics and Astronomy (miscellaneous), business.industry, Pulse (signal processing), General Engineering, General Physics and Astronomy, Pulse duration, chemistry.chemical_element, Laser, Neodymium, law.invention, X-ray laser, Microsecond, Optics, chemistry, law, Solid-state laser, Picosecond, business

Abstract

Plasma-mediated ablations of brain tissue have been performed using picosecond laser pulses obtained from a Nd:YLF oscillator/regenerative amplifier system. The laser pulses had a pulse duration of 35 ps at a wavelength of 1.053 µm. The pulse energy varied from 90 µJ to 550 µJ at a repetition rate of 400 Hz. The energy density at the ablation threshold was measured to be 20 J/cm2. Comparisons have been made to 19 ps laser pulses at 1.68 µm and 2.92 µm from an OPG/OPA system and to microsecond pulse trains at 2.94 µm from a free running Er:YAG laser. Light microscopy and scanning electron microscopy were performed to judge the depth and the quality of the ablated cavities. No thermal damage was induced by either of the picosecond laser systems. The Er:YAG laser, on the other hand, showed 20 µm wide lateral damage zones due to the longer pulse durations and the higher pulse energies.

Published

1994