Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

At a glance: The STEP trials

A round-up of the STEP phase 3 clinical trials evaluating semaglutide for weight loss in people with overweight or obesity.
ADVANCED SEARCH
Log in
Top
Lasers in Medical Science
Published in: Lasers in Medical Science 2/2022

01-03-2022 | Laser | Original Article

Evaluation of a 3.8-µm laser-induced skin injury and their repair with in vivo OCT imaging and noninvasive monitoring

Authors: Yingwei Fan, Qiong Ma, Junchen Wang, Wanyue Wang, Hongxiang Kang

Published in: Lasers in Medical Science | Issue 2/2022

Login to get access

Abstract

To explore a 3.8-µm laser-induced damage and wound healing effect, we propose using optical coherence tomography (OCT) and a noninvasive monitoring-based in vivo evaluation method to quantitatively and qualitatively analyze the time-dependent biological effect of a 3.8-µm laser. The optical attenuation coefficient (OAC) is computed using a Fourier-domain algorithm. Three-dimensional (3-D) visualization of OCT images has been implemented to visualize the burnt spots. Furthermore, the burnt spots from the 3-D volumetric data was segmented and visualized, and the quantitative parameters of the burnt spots, such as the mean OACs, areas, and volumes, were computed. Then, OCT images and histological sections were analyzed to compare the structural changes. Within a certain radiation range, there is a linear relationship between radiation dose and temperature. Dermoscopic images, OCT images, and histological sections showed that, within a certain dose range, as the radiation doses increased, the cutaneous damage became more serious. One hour after laser radiation, the mean OACs increased and then decreased; the areas of burnt spots always increased and were 0.95 ± 0.07, 1.01 ± 0.06, 1.025 ± 0.07, 0.99 ± 0.07, 0.98 ± 0.07, 1.00 ± 0.07, 0.96 ± 0.05, and 0.98 ± 0.06 mm−1, respectively; the areas were 2.10 ± 0.63, 3.75 ± 1.85, 5.95 ± 1.62, 8.35 ± 0.88, 9.44 ± 1.28, 10.29 ± 0.49, 12.27 ± 0.96, and 13.127 ± 1.90 mm2; and the volumes were 1.54 ± 0.41, 2.86 ± 0.09, 3.73 ± 0.49, 4.14 ± 0.80, 7.21 ± 0.52, 6.77 ± 0.45, 8.36 ± 0.25, and 10.65 ± 0.51 mm3; and 21 days after laser radiation, the volumes were 0.67 ± 0.18, 1.64 ± 0.08, 1.87 ± 0.12, 2.57 ± 0.34, 3.43 ± 0.26, 3.64 ± 0.04, 3.84 ± 0.15, and 4.16 ± 0.53 mm3, respectively. We investigated the time-dependent biological effect of 3.8-µm laser-induced cutaneous damage and wound healing using the quantitative parameters of OCT imaging and noninvasive monitoring. The real-time temperature reflects the photothermal effect during laser radiation of mouse skin. OCT images of burnt spots were segmented to compute the mean OACs, burnt area, and quantitative volumes. This study has the potential for in vivo noninvasive and quantitative clinical evaluation in the future.
Literature
1.
Yun SH, Kwok SJJ (2017) Light in diagnosis, therapy and surgery. Nature Biomedical Engineering 1:1–39CrossRef
2.
Gianfaldoni S, Tchernev G, Wollina U et al (2017) An overview of laser in dermatology: the past, the present and the future. Open Access Macedonian J Med Sci 5:4
3.
Trivedi MK, Yang FC, Cho BK (2017) A review of laser and light therapy in melasma. Int J Womens Dermatol 3(1):11–20CrossRef
4.
Anderson R, Parrish J (1983) Selective photothermolysis: precise microsurgery by selective absorption of pulsed radiation. Science 220(4596):524–527CrossRef
5.
Fan YW, Sun Y, Chang W, Zhang XR, Tang J, Zhang LW, Liao HE (2018) Bioluminescence imaging and two-photon microscopy guided laser ablation of GBM decreases tumor burden. Theranostics 8(15):4072–4085CrossRef
6.
Tsai SR, Hamblin MR (2017) Biological effects and medical applications of infrared radiation. J Photochem Photobiol B 170:197–207CrossRef
7.
Cercadillo-Ibarguren I, España-Tost A, Arnabat-Domínguez J, Valmaseda-Castellón E, Berini-Aytés L, Gay-Escoda C (2010) Histologic evaluation of thermal damage produced on soft tissues by CO2, Er, Cr:YSGG and diode lasers. Med Oral Patol Oral Cir Bucal 15(6):e912-8CrossRef
8.
Li D, Farshidi D, Wang G, He Y, Kelly K, Wu W, Chen B, Ying Z (2014) A comparison of microvascular responses to visible and near-infrared lasers. Lasers Surg Med 46:479–487CrossRef
9.
Zhang YM, Ruan J, Xiao R, Zhang Q, Huang YS (2013) A comparison of microvascular responses to visible and near-infrared lasers. Cell Biochem Biophys 67(3):1005–1014CrossRef
10.
Tanaka Y, Matsuo K, Yuzuriha S (2011) Objective assessment of skin rejuvenation using near-infrared 1064-nm neodymium: YAG laser in Asians. Clin Cosmet Investig Dermatol 4:123–130CrossRef
11.
Ahluwalia J, Avram MM, Ortiz AE (2019) Outcomes of long-pulsed 1064 nm Nd:YAG laser treatment of basal cell carcinoma: a retrospective review. Lasers Surg Med 51:34–39CrossRef
12.
Morse K, Kimizuka Y, Chan MPK et al (2017) Near-infrared 1064 nm laser modulates migratory dendritic cells to augment the immune response to intradermal influenza vaccine. J Immunol 199(4):1319–1332CrossRef
13.
Tanzi EL, Alster TS (2004) Comparison of a 1450-nm diode laser and a 1320-nm Nd: YAG laser in the treatment of atrophic facial scars. Dermatol Surg 30(2):152–157PubMed
14.
Fan YW, Ma Q, Liang J, Lu YX, Ni B, Luo ZK, Cui YF, Kang HX (2019) Quantitative and qualitative evaluation of recovery process of a 1 064 nm laser on laser-induced skin injury: in vivo experimental research. Laser Physics Letters 16:115604CrossRef
15.
Vincelette RL, Noojin GD, Harbert CA, Schuster KJ, Shingledecker AD, Stolarski DJ, Kumru SS, Oliver JW (2014) Porcine skin damage thresholds for 0.6 to 9.5 cm beam diameters from 1070-nm continuous-wave infrared laser radiation. J Biomed Opt 19(3):035007CrossRef
16.
Chen B, O’Dell DC, Thomsen SL et al (2005) Porcine skin ED50 damage thresholds for 2,000 nm laser irradiation. Lasers Surg Med 37(5):373–381CrossRef
17.
Yang JC, Dong XX, Mu ZM et al (2015) Temporal and spatial temperature distributions on glabrous skin irradiated by a 1,940 nm continuous-wave laser stimulator. Biomed Opt Express 6(4):1451–1463CrossRef
18.
19.
Ida T, Iwazaki H, Kawaguchi Y, Kawauchi S, Ohkura T, Iwaya K, Tsuda H, Saitoh D, Sato S, Iwai T (2016) Burn depth assessments by photoacoustic imaging and laser Doppler imaging. Wound Rep and Reg 24:349–355CrossRef
20.
Xu D, Yang S, Wang Y, Gu Y, Xing D (2016) Noninvasive and high-resolving photoacoustic dermoscopy of human skin. Biomed Opt Express 7:2095–2102CrossRef
21.
Sang X, Li D, Chen B (2021) Improving imaging depth by dynamic laser speckle imaging and topical optical clearing for in vivo blood flow monitoring. Lasers Med Sci 36:387–399CrossRef
22.
Heeman W, Steenbergen W, van Dam GM, Boerma EC (2019) Clinical applications of laser speckle contrast imaging: a review. Journal of Biomedical Optics 24(8):080901CrossRef
23.
Millet C, Roustit M, Blaise S, Cracowski JL (2011) Comparison between laser speckle contrast imaging and laser Doppler imaging to assess skin blood flow in humans. Microvasc Res 82(2):147–151CrossRef
24.
Thatcher JE, Squiers JJ, Kanick SC et al (2016) Imaging techniques for clinical burn assessment with a focus on multispectral imaging. Adv Wound Care (New Rochelle) 5(8):360–378CrossRef
25.
Huang D, Swanson EA, Lin CP, Schuman JS, Stinson WG, Chang W et al (1991) Optical coherence tomography. Science (New York, N.Y.) 254(5035):1178–1181
26.
Ahn Y, Lee CY, Baek S, Kim T, Kim P et al (2016) Quantitative monitoring of laser-treated engineered skin using optical coherence tomography. Biomed Opt Express 7:1030–1041CrossRef
27.
Luo ST, Fan YW, Chang W, Liao HE, Kang HX, Huo L (2019) Classification of human stomach cancer using morphological feature analysis from optical coherence tomography images. Laser Physics Letters 16(9):095602CrossRef
28.
Tsai MT, Yang CH, Shen SC, Lee YJ, Chang FY, Feng CS (2013) Monitoring of wound healing process of human skin after fractional laser treatments with optical coherence tomography. Biomed Opt Express 4(11):2362–2375CrossRef
29.
Deegan AJ, Wang W, Men S et al (2018) Optical coherence tomography angiography monitors human cutaneous wound healing over time. Quant Imaging Med Surg 8(2):135–150CrossRef
30.
Chang S, Bowden AK (2019) Review of methods and applications of attenuation coefficient measurements with optical coherence tomography. J Biomed Opt 24(9):090901CrossRef
31.
Gong P, McLaughlin RA, Liew YM, Munro PRT, Wood FM, Sampson DD (2013) Assessment of human burn scars with optical coherence tomography by imaging the attenuation coefficient of tissue after vascular masking. J Biomed Opt 19(2):021111CrossRef
32.
Fan YW, Ma LF, Jiang WP, Luo ST, Zhang XR, Liao HE (2018) Optimized optical coherence tomography imaging with Hough transform-based fixed-pattern noise reduction. IEEE Access 6:32087–32096CrossRef
33.
Fan YW, Hu CQ, Kang HX, Liao HE (2020) Background noise reduction of OCT images based on region filling. The 11th Asian Pacific Conference on Medical and Biological Engineering. (APCMBE 2020) May 25–27, 2020. Okayama Convention Center, Japan
34.
Yuan W, Kut C, Liang W, Li X (2017) Robust and fast characterization of OCT-based optical attenuation using a novel frequency-domain algorithm for brain cancer detection. Sci Rep 7:44909CrossRef
35.
Yu X et al (2018) Evaluating micro-optical coherence tomography as a feasible imaging tool for pancreatic disease diagnosis. IEEE J Sel Top Quantum Electron 25(1):1–8CrossRef
36.
Ahluwalia J, Avram MM, Ortiz AE (2019) Outcomes of long-pulsed 1064 nm Nd:YAG laser treatment of basal cell carcinoma: a retrospective review. Lasers Surg Med 51(1):34–39CrossRef
37.
Kepp T, Droigk C, Casper M, Evers M, Hüttmann G, Salma N, Manstein D, Heinrich MP, Handels H (2019) Segmentation of mouse skin layers in optical coherence tomography image data using deep convolutional neural networks. Biomed Opt Express 10:3484–3496CrossRef
Metadata
Title
Evaluation of a 3.8-µm laser-induced skin injury and their repair with in vivo OCT imaging and noninvasive monitoring
Authors
Yingwei Fan
Qiong Ma
Junchen Wang
Wanyue Wang
Hongxiang Kang
Publication date
01-03-2022
Publisher
Springer London
Keyword
Laser
Published in
Lasers in Medical Science / Issue 2/2022
Print ISSN: 0268-8921
Electronic ISSN: 1435-604X
DOI
https://doi.org/10.1007/s10103-021-03388-w

Other articles of this Issue 2/2022

Lasers in Medical Science 2/2022 Go to the issue

Original Article

The effect of cisplatin-low-level laser therapy on cell viability and death of LNCaP prostate cancer cell line

Original Article

Total mouth photodynamic therapy mediated by red LED and porphyrin in individuals with AIDS

Brief Report

CO2 laser in the management of eccrine hidrocystomas: a retrospective study

Review Article

Clinical effectiveness of adjunctive diode laser on scaling and root planing in the treatment of periodontitis: is there an optimal combination of usage mode and application regimen? A systematic review and meta-analysis

Original Article

The application of SFDI and LSI system to evaluate the blood perfusion in skin flap mouse model

Original Article

Improvement of apical papilla cell attachment after erbium, chromium-doped yttrium, scandium, gallium, and garnet laser application: a study in an ex vivo immature tooth model