Optodynamic energy-conversion efficiency during an Er:YAG-laser-pulse delivery into a liquid through different fiber-tip geometries

Gregorčič, Peter; Jezeršek, Matija; Možina, Janez

doi:10.1117/1.jbo.17.7.075006

Cited by 60 publications

(65 citation statements)

References 51 publications

(70 reference statements)

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“…After the initial collapse of the bubble (700 µs), additional oscillations can occur Figure 2 shows the laser-induced vapor bubble oscillation in 50 µs time intervals. In unconstrained space, laser-induced vapor bubbles have been shown to grow in a roughly spherical shape [7,8]. The prolate spheroidal shape of the growing bubble is likely caused by the constraints of the root canal as the water displaced by the growing bubble is forced out of the canal alongside its walls.…”

Section: Water Vorticity Measuring Setupmentioning

confidence: 99%

“…Matija.jezersek@fs.uni-lj.si 1 Faculty of Mechanical Engineering, University of Ljubljana, Aškerčeva 6, 1000 Ljubljana, Slovenia light penetration depth) leads to explosive boiling that generates vapor bubbles [6,7], causing mixing of liquid also at distant regions of the complex root canal anatomy. This is an important advantage over ultrasonic needle irrigation, where a significant effect occurs only in the close proximity of the instrument [8].…”

Section: B Matija Jezeršekmentioning

confidence: 99%

“…For this purpose, an experimental setup was developed based on two measuring principles. Shadow photography with short, 10 ns, white-light illumination flashes, and frequencydoubled Nd:YAG laser illumination is used to visualize the cavitation bubble dynamics [7] inside the root canal. Simulated debris particles within the transparent model of the root canal are used to examine liquid vorticity.…”

Section: B Matija Jezeršekmentioning

confidence: 99%

See 2 more Smart Citations

Optodynamic Phenomena During Laser-Activated Irrigation Within Root Canals

2016

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Laser-activated irrigation is a powerful endodontic treatment for smear layer, bacteria, and debris removal from the root canal. In this study, we use shadow photography and the laser-beam-transmission probe to examine the dynamics of laserinduced vapor bubbles inside a root canal model and compare ultrasonic needle irrigation to the laser method. Results confirm important phenomenological differences in the two endodontic methods with the laser method resulting in much deeper irrigation. Observations of simulated debris particles show liquid vorticity effects which in our opinion represents the major cleaning mechanism.

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Section: Water Vorticity Measuring Setupmentioning

confidence: 99%

Section: B Matija Jezeršekmentioning

confidence: 99%

Section: B Matija Jezeršekmentioning

confidence: 99%

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Optodynamic Phenomena During Laser-Activated Irrigation Within Root Canals

2016

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“…The shape of the tip determines how the light emerging from the fiber is distributed on a tissue sample and also determines the light collection efficiency for viewing the irradiated tissue sample or examining scattered or fluorescing light emitted from the sample. [84][85][86][87][88][89][90][91][92][93][94][95][96] When deciding on the geometry of an optical fiber tip, parameters that need to be evaluated include the sizes of the illumination and light-collection areas, the collection angle (related to the fiber NA), and the fiber diameter. Another important factor to keep in mind is that biological tissue has a multilayered characteristic from both compositional and functional viewpoints.…”

Section: Optical Fiber Biomedical Probesmentioning

confidence: 99%

Review of diverse optical fibers used in biomedical research and clinical practice

et al. 2014

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Abstract. Optical fiber technology has significantly bolstered the growth of photonics applications in basic life sciences research and in biomedical diagnosis, therapy, monitoring, and surgery. The unique operational characteristics of diverse fibers have been exploited to realize advanced biomedical functions in areas such as illumination, imaging, minimally invasive surgery, tissue ablation, biological sensing, and tissue diagnosis. This review paper provides the necessary background to understand how optical fibers function, to describe the various categories of available fibers, and to illustrate how specific fibers are used for selected biomedical photonics applications. Research articles and vendor data sheets were consulted to describe the operational characteristics of conventional and specialty multimode and single-mode solid-core fibers, double-clad fibers, hard-clad silica fibers, conventional hollow-core fibers, photonic crystal fibers, polymer optical fibers, side-emitting and side-firing fibers, middle-infrared fibers, and optical fiber bundles. Representative applications from the recent literature illustrate how various fibers can be utilized in a wide range of biomedical disciplines. In addition to helping researchers refine current experimental setups, the material in this review paper will help conceptualize and develop emerging optical fiber-based diagnostic and analysis tools.

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“…Due to the very high absorption coefficient (l a = 1.247 9 10 6 m -1 ) [4] of Er:YAG, light in water more than 70 % of all the pulse's light is absorbed within an only 1-lm-thick water layer. Thus, the water is locally and instantly heated over its boiling point, and a vapor bubble develops at the fiber tip's end [5][6][7][8].…”

Section: Introductionmentioning

confidence: 99%

Synchronized delivery of Er:YAG-laser pulses into water studied by a laser beam transmission probe for enhanced endodontic treatment

et al. 2016

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We examine the effects of the synchronized delivery of multiple Er:YAG-laser pulses during vaporbubble oscillations into water. For this purpose, we used a laser beam transmission probe that enables monitoring of the bubble's dynamics from a single shot. To overcome the main drawbacks of this technique, we propose and develop an appropriate and robust calibration by simultaneous employment of shadow photography. By using the developed experimental method, we show that the resonance effect is obtained when the second laser pulse is delivered at the end or slightly after the first bubble's collapse. In this case, the resonance effect increases the mechanical energy of the secondary bubble's oscillations and prolongs their duration. The presented laser method for synchronized delivery of Er:YAG-laser pulses during bubble oscillations has great potential for further improvement of laser endodontic treatment, especially upon their safety and efficiency.

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Optodynamic energy-conversion efficiency during an Er:YAG-laser-pulse delivery into a liquid through different fiber-tip geometries

Cited by 60 publications

References 51 publications

Optodynamic Phenomena During Laser-Activated Irrigation Within Root Canals

Optodynamic Phenomena During Laser-Activated Irrigation Within Root Canals

Review of diverse optical fibers used in biomedical research and clinical practice

Synchronized delivery of Er:YAG-laser pulses into water studied by a laser beam transmission probe for enhanced endodontic treatment

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