Microstructural changes in sclera under thermo‐mechanical effect of 1.56 µm laser radiation increasing transscleral humor outflow

Baum, Olga I.; Sobol, Emil N.; Bol'shunov, A V; Федоров, А. А.; Khomchik, O.V.; Omelchenko, Alexander I.; Shcherbakov, E. M.

doi:10.1002/lsm.22202

Cited by 14 publications

(16 citation statements)

References 20 publications

(22 reference statements)

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“…Ten laser spots of 0.6 mm in diameter, instantaneous power of 0.9 W, pulse duration of 200 ms, and pulse repetition rate of 2 Hz were applied on the sclera at a distance of approximately 1-2 mm from the eye limb. As previously reported, this particular laser setting provided the thermo-mechanical effect necessary for efficient formation of pores, which resulted in a substantial increase of hydraulic permeability in the sclera [4]. This unique effect was further employed for a new type of safe and effective intraocular pressure (IOP) normalization technique relying on the enhancement of uveoscleral outflow under nondestructive laser irradiation of the sclera [4].…”

Section: Preparation Of Samplesmentioning

confidence: 82%

“…By imaging tissues impregnated with NP of specific size distribution, one can target for early diagnostics of arthritis and other cartilage-related diseases which otherwise cannot be manifested today using MRI and other conventional imaging methods. It was recently established that laser-induced formation of pores in the sclera may serve as a basis for new approaches toward IOP normalization in glaucoma [4], however, no monitoring approach currently exists that can deliver an efficient feedback necessary for determining settings for optimal pore formation in IOP normalization procedures. The hybrid OA and US microscopy was able to visualize laser-induced formation of pores in the eye sclera, which can be potentially used to dynamically adjust the laser irradiation settings in order to prevent undesirable modification of the sclera structure.…”

Section: Discussionmentioning

confidence: 99%

“…Yet, safety and efficacy of laser modification technologies rely on efficient feedback control systems to accurately monitor the changes in tissue structure. To this end, laser-induced structural alterations have been mainly studied ex-vivo using conventional microscopic techniques applied to thin specimen, including histological methods [3], atomic force microscopy and electron microscopy [4,5]. Various non-destructive techniques, including light scattering measurements [5,6], optical coherence tomography (OCT) [7], and ultrasound imaging [8,9], have been also applied to study laser-treated tissues.…”

Section: Introductionmentioning

confidence: 99%

“…In the context of laser treatments, ultrasoundbased imaging might further become a promising candidate for monitoring of laserinduced formation of submicron size pores in cartilage matrix, which has been recently established as one of the factors promoting regeneration of cartilaginous tissues [3]. Similarly, formation of gaseous pores in laser-treated sclera allows substantially increasing its water permeability, serving as a basis for new types of glaucoma therapies [4]. By means of a optoacoustic imaging approach, which uses intense short-duration laser pulses to induce ultrasonic responses in deep tissues layers [10], a real-time feedback capability during laser treatments was recently showcased, yet only reported for monitoring of destructive laser ablation procedures [11].…”

Section: Introductionmentioning

confidence: 99%

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Hybrid optoacoustic and ultrasound biomicroscopy monitors’ laser-induced tissue modifications and magnetite nanoparticle impregnation

Estrada¹,

Sobol²,

Baum³

et al. 2014

Laser Phys. Lett.

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Tissue modification under laser radiation is emerging as one of the advanced applications of lasers in medicine, with treatments ranging from reshaping and regeneration of cartilage to normalization of the intraocular pressure. Laser-induced structural alterations can be studied using conventional microscopic techniques applied to thin specimen. Yet, development of noninvasive imaging methods for deep tissue monitoring of structural alterations under laser radiation is of great importance, especially for attaining efficient feedback during the procedures. We developed a fast scanning biomicroscopy system that can simultaneously deliver both optoacoustic and pulse-echo ultrasound contrast from intact tissues and show that both modalities allow manifesting the laser-induced changes in cartilage and sclera. Furthermore, images of the sclera samples reveal a crater developing around the center of the laser-irradiated spot as well as certain degree of thickening within the treated zone, presumably due to pore formation. Finally, we were able to observe selective impregnation of magnetite nanoparticles into the cartilage, thus demonstrating a possible contrast enhancement approach for studying specific treatment effects. Overall, the new imaging approach holds promise for development of noninvasive feedback control systems that could guarantee efficacy and safety of laser-based medical procedures.

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Section: Preparation Of Samplesmentioning

confidence: 82%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Hybrid optoacoustic and ultrasound biomicroscopy monitors’ laser-induced tissue modifications and magnetite nanoparticle impregnation

Estrada¹,

Sobol²,

Baum³

et al. 2014

Laser Phys. Lett.

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show abstract

“…Laser treatment of tissues is a rapidly developing field of biophotonics and medical physics in general. Biologically, nondestructive laser‐induced modification of several types of collagenous tissues, such as cartilaginous tissue , sclera and cornea, is a perspective branch of this field. For example, the laser‐induced temperature and thermal‐stress fields allow for changing the cartilaginous sample shape, which can be used for manufacturing allo‐ and autoimplants.…”

Section: Introductionmentioning

confidence: 99%

Interplay of temperature, thermal‐stresses and strains in laser‐assisted modification of collagenous tissues: Speckle‐contrast and OCT‐based studies

Baum

Zaitsev

Yuzhakov

et al. 2019

Journal of Biophotonics

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Moderate heating of collagenous tissues such as cartilage and cornea by infrared laser irradiation can produce biologically nondestructive structural rearrangements and relaxation of internal stresses resulting in the tissue reshaping. The reshaping results and eventual changes in optical and biological properties of the tissue strongly depend on the laser‐irradiation regime. Here, a speckle‐contrast technique based on monochromatic illumination of the tissue in combination with strain mapping by means of optical coherence elastography (OCE) is applied to reveal the interplay between the temperature and thermal stress fields producing tissue modifications. The speckle‐based technique ensured en face visualization of cross correlation and contrast of speckle images, with evolving proportions between contributions of temperature increase and thermal‐stresses determined by temperature gradients. The speckle‐technique findings are corroborated by quantitative OCE‐based depth‐resolved imaging of irradiation‐induced strain‐evolution. The revealed relationships can be used for real‐time control of the reshaping procedures (e.g., for laser shaping of cartilaginous implants in otolaryngology and maxillofacial surgery) and optimization of the laser‐irradiation regimes to ensure the desired reshaping using lower and biologically safer temperatures. The figure of waterfall OCE‐image demonstrates how the strain‐rate maximum arising in the heating‐beam center gradually splits and drifts towards the zones of maximal thermal stresses located at the temperature‐profile slopes.

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Revealing structural modifications in thermomechanical reshaping of collagenous tissues using optical coherence elastography

Zaitsev

Matveyev

Matveev

et al. 2018

Journal of Biophotonics

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Moderate heating of such collagenous tissues as cornea and cartilages by infra‐red laser (IR laser) irradiation is an emerging technology for nondestructive modification of the tissue shape and microstructure for a variety of applications in ophthalmology, otolaryngology and so on. Postirradiation high‐resolution microscopic examination indicates the appearance of microscopic either spheroidal or crack‐like narrow pores depending on the tissue type and irradiation regime. Such examinations usually require special tissue preparation (eg, staining, drying that affect microstructure themselves) and are mostly suitable for studying individual pores, whereas evaluation of their averaged parameters, especially in situ, is challenging. Here, we demonstrate the ability of optical coherence tomography (OCT) to visualize areas of pore initiation and evaluate their averaged properties by combining visualization of residual irradiation‐induced tissue dilatation and evaluation of the accompanying Young‐modulus reduction by OCT‐based compressional elastography. We show that the averaged OCT‐based data obtained in situ fairly well agree with the microscopic examination results. The results obtained develop the basis for effective and safe applications of novel nondestructive laser technologies of tissue modification in clinical practice. PICTURE: Elastographic OCT‐based images of an excised rabbit eye cornea subjected to thermomechanical laser‐assisted reshaping. Central panel shows resultant cumulative dilatation in cornea after moderate (~45‐50°C) pulse‐periodic heating by an IR laser together with distribution of the inverse Young modulus 1/E before (left) and after (right) IR irradiation. Significant modulus decrease in the center of irradiated region is caused by initiated micropores. Their parameters can be extracted by analyzing the elastographic images.

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Microstructural changes in sclera under thermo‐mechanical effect of 1.56 µm laser radiation increasing transscleral humor outflow

Cited by 14 publications

References 20 publications

Hybrid optoacoustic and ultrasound biomicroscopy monitors’ laser-induced tissue modifications and magnetite nanoparticle impregnation

Hybrid optoacoustic and ultrasound biomicroscopy monitors’ laser-induced tissue modifications and magnetite nanoparticle impregnation

Interplay of temperature, thermal‐stresses and strains in laser‐assisted modification of collagenous tissues: Speckle‐contrast and OCT‐based studies

Revealing structural modifications in thermomechanical reshaping of collagenous tissues using optical coherence elastography

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