Dehydration mechanism of optical clearing in tissue

Rylander, Christopher G.; Stumpp, Oliver; Milner, Thomas E.; Kemp, Nathaniel Joseph; Mendenhall, John M.; Diller, Kenneth R.; Welch, Ashley J.

doi:10.1117/1.2343208

Cited by 133 publications

(133 citation statements)

References 23 publications

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“…The aqueous solutions of glycerol are immersion liquids widely used as OCAs due to their efficiency, availability, and biocompatibility [1][2][3][4][5][6][7][8]. Unfortunately, in spite of the wide use of glycerol for controlling the tissue optical parameters, there is no unambiguous answer to the question about the optimal concentration of the glycerol solution.…”

Section: Introductionmentioning

confidence: 99%

Ex vivo investigation of glycerol diffusion in skin tissue

Genin

Tuchina

Sadeq

et al. 2016

JBPE

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Abstract. The change of optical parameters of rat skin ex vivo under the action of aqueous 30%, 50%, 60%, 70%, 85%, and 100% glycerol solutions has been experimentally studied. The analysis of kinetics of the change of the studied parameters has allowed the estimate of the diffusion coefficient dependence upon the concentration of glycerol in the skin and the efficiency of optical clearing for each of the glycerol solutions. The results can find application in the development of new methods of noninvasive diagnostics and therapy of skin diseases.

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Section: Introductionmentioning

confidence: 99%

Ex vivo investigation of glycerol diffusion in skin tissue

Genin

Tuchina

Sadeq

et al. 2016

JBPE

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“…Biological tissues can become subject to compression in several ways, including physiologically (pressure exerted on vessel walls during the cardiac cycle (7) and cellular mechanotransduction (8,9)), pathologically (traumatic injuries (10)) clinically (edema monitoring for dialysis patients (11), electrosurgery (12), body water and fat detection (5), and soft-tissue healing techniques (13)), and in basic research (optical clearing in tissues (14) and probe characterization (15)). Even fields that would at first seem to fall far abreast of this specific discussion have added relevance given their synthesis of passive electrical properties with the mechanical properties of materials under examination including certain realms of agricultural research focused on meat quality assessment (16,17) and mineralogical investigations of rocks (18).…”

Section: Introductionmentioning

confidence: 99%

Impedance of tissue-mimicking phantom material under compression

Belmont

Dodde

Shih

2013

Journal of Electrical Bioimpedance

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The bioimpedance of tissues under compression is a field in need of study. While biological tissues can become compressed in a myriad of ways, very few experiments have been conducted to describe the relationship between the passive electrical properties of a material (impedance/admittance) and its underlying mechanical properties (stress and strain) during deformation. Of the investigations that have been conducted, the exodus of fluid from samples under compression has been thought to be the cause of changes in impedance, though until now was not measured directly. Using a soft tissue-mimicking phantom material (tofu) whose passive electrical properties are a function of the conducting fluid held within its porous structure, we have shown that the mechanical behavior of a sample under compression can be measured through bioimpedance techniques.

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“…3 demonstrates that decreasing the tissue temperature resulted in decreasing the µ's and, therefore, increasing the PI and TI which means enhancement of photon density in the dermis. As described in previous studies, such results may be caused by the modification of collagen fiber structure, degradation of cellular components, and change of the refractive index of intercellular fluid [15][16][17][18][19][20].…”

Section: Discussionmentioning

confidence: 96%

“…Rylander et al [18] and Yu et al [19] that skin dehydration is the prominent mechanism of OTC and Yeh et al [20] suggested that the reversible change of both collagen structure and size can affect OTC. In recent in-vivo studies, Ghosn et al monitored and quantified the permeability rate of glucose solutions in in-vivo monkey skin by using OCT [21], and Wen et al reported that the thickness decrease of dermis and regular arrangement of tissue fibers were prominent OTC mechanisms [22].…”

Section: Introductionmentioning

confidence: 99%

Development of an Optical Tissue Clearing Laser Probe System

Yeo¹,

Kang²,

Bae³

et al. 2013

Journal of the Optical Society of Korea

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Although low-level laser therapy (LLLT) has been a valuable therapeutic technology in the clinic, its efficacy may be reduced in deep tissue layers due to strong light scattering which limits the photon density. In order to enhance the photon density in deep tissue layers, this study developed an optical tissue clearing (OTC) laser probe (OTCLP) system which can utilize four different OTC methods: 1) tissue temperature control from 40 to 10℃; 2) laser pulse frequency from 5 to 30 Hz; 3) glycerol injection at a local region; and 4) a combination of the aforementioned three methods. The efficacy of the OTC methods was evaluated and compared by investigating laser beam profiles in ex-vivo porcine skin samples. Results demonstrated that total (peak) intensity at full width at half maximum of laser beam profile when compared to control data was increased: 1) 1.21(1.39)-fold at 10℃; 2) 1.22 (1.49)-fold at a laser pulse frequency of 5 Hz; 3) 1.64 (2.41)-fold with 95% glycerol injection; 4) 1.86 (3.4)-fold with the combination method. In conclusion, the OTCLP system successfully improved the laser photon density in deep tissue layers and may be utilized as a useful tool in LLLT by increasing laser photon density.

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Dehydration mechanism of optical clearing in tissue

Cited by 133 publications

References 23 publications

Ex vivo investigation of glycerol diffusion in skin tissue

Ex vivo investigation of glycerol diffusion in skin tissue

Impedance of tissue-mimicking phantom material under compression

Development of an Optical Tissue Clearing Laser Probe System

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