nach oben

Lasers in Medical Science

Erschienen in:

13.09.2018 | Original Article

Temperature and depth evaluation of the in vitro effects of femtosecond laser on oral soft tissue, with or without air-cooling

verfasst von: Wenjun Li, Jianqiao Zheng, Yaopeng Zhang, Fusong Yuan, Peijun Lyu

Erschienen in: Lasers in Medical Science | Ausgabe 4/2019

Einloggen, um Zugang zu erhalten

Abstract

Femtosecond laser is an effective and safe tool in many surgeries, but the studies of its effect on oral soft tissue ablation are insufficient. This study aimed to investigate the effect of soft tissue ablation with a 1030-nm femtosecond laser on temperature and depth. Twenty Sprague–Dawley rat tongue specimens were obtained and flat-mounted. The 1030-nm femtosecond laser was controlled by a computer system, with a set distance of 4.7 mm between the laser aperture and soft tissue surfaces. Ten specimens were ablated for > 1 min with or without air-cooling for temperature measurement, while the other 10 specimens were ablated for depth measurements, using the following parameters: (i) 3 W, 2000 mm/s; (ii) 3 W, 4000 mm/s; (iii) 5 W, 2000 mm/s; (iv) 5 W, 4000 mm/s; (v) 8 W, 2000 mm/s; (vi) 8 W, 4000 mm/s. Temperature changes were measured using a type-K thermocouple. The depth attained using different power and scanning speed settings was measured by a three-dimensional morphology measurement laser microscope. Laser power, scanning speed, and air-cooling effects were determined. Higher energy and lower speed induced higher temperatures (p < 0.05), which were significantly decreased by air-cooling (p < 0.05). The lowest ablation depth was obtained at 3 W and 4000 mm/s (72.63 ± 6.47 μm) (p < 0.05). The greatest incision depth was achieved at 8 W and 2000 mm/s (696.19 ± 35.37 μm), or 4000 mm/s (681.16 ± 55.65 μm) (p < 0.05). The 1030-nm femtosecond laser application demonstrates clinically acceptable ablation efficiency, without marked temperature damage, in a controlled manner.

Schneider D, Goppold K, Kaemmerer PW et al (2018) Use of ultrasonic scalpel and monopolar electrocautery for skin incisions in neck dissection: a prospective randomized trial [J]. Oral Maxillofac Surg 22(2):169–175

Scott JE, Swanson EA, Cooley J et al (2017) Healing of canine skin incisions made with monopolar electrosurgery versus scalpel blade [J]. Vet Surg 46(4):520–529CrossRefPubMed

Hasar ZB, Ozmeric N, Ozdemir B et al (2016) Comparison of radiofrequency and electrocautery with conventional scalpel incisions [J]. J Oral Maxillofac Surg 74(11):2136–2141CrossRefPubMed

Raboud M, Tuleasca C, Maeder P, et al. (2018) Gamma knife radiosurgery for arteriovenous malformations: general principles and preliminary results in a Swiss cohort [J]. Swiss Med Wkly,148(w14602

Pick R M, Pecaro B C. Use of the CO2 laser in soft tissue dental surgery [J]. Lasers Surg Med, 1987, 7(2): 207–213

Romeo U, Palaia G, Del Vecchio A et al (2010) Effects of KTP laser on oral soft tissues. An in vitro study [J]. Lasers Med Sci 25(4):539–543

Angiero F, Parma L, Crippa R et al (2012) Diode laser (808 nm) applied to oral soft tissue lesions: a retrospective study to assess histopathological diagnosis and evaluate physical damage [J]. Lasers Med Sci 27(2):383–388

Romeo U, Libotte F, Palaia G et al (2012) Histological in vitro evaluation of the effects of Er:YAG laser on oral soft tissues [J]. Lasers Med Sci 27(4):749–753

Vescovi P, Corcione L, Meleti M et al (2010) Nd:YAG laser versus traditional scalpel. A preliminary histological analysis of specimens from the human oral mucosa [J]. Lasers Med Sci 25(5):685–691

10.

Gonz lez-mosquera A, Seoane J, Garc A-Caballero L et al (2012) Er,CR:YSGG lasers induce fewer dysplastic-like epithelial artefacts than CO2 lasers: an in vivo experimental study on oral mucosa [J]. Br J Oral Maxillofac Surg 50(6):508–512CrossRef

11.

Natekar M, Raghuveer HP, Rayapati DK et al (2017) A comparative evaluation: Oral leukoplakia surgical management using diode laser, CO2 laser, and cryosurgery [J]. J Clin Exp Dent 9(6):e779–ee84

12.

Tuchmann A, Fischer P L, Bauer P, et al. [Scalpel and CO2 laser in the animal experiment. A comparative study of inoculation tumors of the mouse] [J]. Langenbecks Arch Chir, 1986, 368(2): 125–136

13.

Friesen LR, Cobb CM, Rapley JW et al (1999) Laser irradiation of bone: II. Healing response following treatment by CO2 and Nd:YAG lasers [J]. J Periodontol 70(1):75–83CrossRefPubMed

14.

Romanos G E. Diode laser soft-tissue surgery: advancements aimed at consistent cutting, improved clinical outcomes [J]. Compend Contin Educ Dent, 2013, 34(10): 752–757; quiz 8

15.

Beer FK, Rpert W, Passow H et al (2012) Reduction of collateral thermal impact of diode laser irradiation on soft tissue due to modified application parameters [J]. Lasers Med Sci 27(5):917–921CrossRefPubMed

16.

Braun A, Kettner M, Berthold M et al (2018) Efficiency of soft tissue incision with a novel 445-nm semiconductor laser [J]. Lasers Med Sci 33(1):27–33

17.

He M, Jin H, He H et al (2018) Femtosecond laser-assisted small incision endokeratophakia using a xenogeneic lenticule in rhesus monkeys [J]. Cornea 37(3):354–361CrossRefPubMed

18.

Agca A, Cankaya KI, Yilmaz I et al (2015) Fellow eye comparison of nerve fiber regeneration after SMILE and femtosecond laser-assisted LASIK: a confocal microscopy study [J]. J Refract Surg 31(9):594–598

19.

Mencucci R, Matteoli S, Corvi A et al (2015) Investigating the ocular temperature rise during femtosecond laser lens fragmentation: an in vitro study [J]. Graefe’s archive for clinical and experimental ophthalmology = Albrecht von Graefes Archiv fur klinische und experimentelle Ophthalmologie 253(12):2203–2210

20.

Mortensen LJ, Alt C, Turcotte R et al (2015) Femtosecond laser bone ablation with a high repetition rate fiber laser source [J]. Biomed Opt Express 6(1):32–42CrossRefPubMed

21.

Rajitha Gunaratne G, Khan R, Fick D et al (2017) A review of the physiological and histological effects of laser osteotomy [J]. J Med Eng Technol 41(1):1–12CrossRefPubMed

22.

Chen H, Li H, Sun Y, et al(2016) Femtosecond laser for cavity preparation in enamel and dentin: ablation efficiency related factors [J]. Scientific reports, 6(20950

23.

Sun Y C, Vorobyev A, Liu J, et al. [Femtosecond pulsed laser ablation of dental hard tissues with numerical control: a roughness and morphology study] [J]. Zhonghua Kou Qiang Yi Xue Za Zhi, 2012, 47(8): 486–489

24.

Stover T, Paasche G, Lenarz T et al (2007) Development of a drug delivery device: using the femtosecond laser to modify cochlear implant electrodes [J]. Cochlear Implants Int 8(1):38–52

25.

Delgado-ruiz RA, Markovic A, Calvo-guirado JL et al (2014) Implant stability and marginal bone level of microgrooved zirconia dental implants: a 3-month experimental study on dogs [J]. Vojnosanit Pregl 71(5):451–461CrossRefPubMed

26.

Gokhan Demir A, Previtali B (2014) Comparative study of CW, nanosecond- and femtosecond-pulsed laser microcutting of AZ31 magnesium alloy stents [J]. Biointerphases 9(2):029004CrossRefPubMed

27.

Uchugonova A, Breunig HG, Batista A et al (2015) Optical reprogramming of human somatic cells using ultrashort Bessel-shaped near-infrared femtosecond laser pulses [J]. J Biomed Opt:20(11)

28.

Kuetemeyer K, Lucas-hahn A, Petersen B et al (2011) Femtosecond laser-induced fusion of nonadherent cells and two-cell porcine embryos [J]. J Biomed Opt:16(8)

29.

Konig K, Riemann I, Fritzsche W (2001) Nanodissection of human chromosomes with near-infrared femtosecond laser pulses [J]. Opt Lett 26(11):819–821

30.

Shi F, He H, Wang YT et al (2015) Mitochondrial swelling and restorable fragmentation stimulated by femtosecond laser [J]. Biomed Opt Express 6(11):4539–4545

31.

Xue Z.(2007) In vivo experiment of femtosecond laser treatment in skin pigment abnormalities [D]; Shanghai Jiaotong University

32.

Santos MOD, Latrive A, De Castro PAA et al (2017) Multimodal evaluation of ultra-short laser pulses treatment for skin burn injuries [J]. Biomed Opt Express 8(3):1575–1588CrossRefPubMedPubMedCentral

33.

Su E, Sun H, Juhasz T, et al.(2014) Preclinical investigations of articular cartilage ablation with femtosecond and pulsed infrared lasers as an alternative to microfracture surgery [J]. J Biomed Opt, 19(9)

34.

Choi M, Yun SH (2013) In vivo femtosecond endosurgery: an intestinal epithelial regeneration-after-injury model [J]. Opt Express 21(25):30842–30848

35.

Hoy CL, Everett WN, Yildirim M et al (2012) Towards endoscopic ultrafast laser microsurgery of vocal folds [J]. J Biomed Opt 17(3):038002CrossRefPubMed

36.

Liang JH, Kang J, Pan YL et al (2011) Ex vivo evaluation of femtosecond pulse laser incision of urinary tract tissue in a liquid environment: implications for endoscopic treatment of benign ureteral strictures [J]. Lasers Surg Med 43(6):516–521CrossRefPubMed

37.

Moshonov J, Stabholz A, Leopold Y et al (1993) Lasers in dentistry. Part B--Interaction with biological tissues and the effect on the soft tissues of the oral cavity, the hard tissues of the tooth and the dental pulp. Refuat Hapeh Vehashinayim 18(3–4):21–28 107-8

38.

Azevedo AS, Monteiro LS, Ferreira F et al (2016) In vitro histological evaluation of the surgical margins made by different laser wavelengths in tongue tissues [J]. J Clin Exp Dent 8(4):e388–ee96PubMedPubMedCentral

39.

Pinheiro AL, Browne RM, Frame JW et al (1993) Assessment of thermal damage in precooled CO2 laser wounds using biological markers [J]. Br J Oral Maxillofac Surg 31(4):239–243CrossRefPubMed

40.

Ikezaki M, Higashimoto N, Matsumura K et al (2016) Hsc70 facilitates TGF-beta-induced activation of Smad2/3 in fibroblastic NRK-49F cells [J]. Biochem Biophys Res Commun 477(3):448–453

41.

Capon A, Mordon S (2003) Can thermal lasers promote skin wound healing? [J]. Am J Clin Dermatol 4(1):1–12

42.

Augustin JA, Pflug IJ (1967) Recovery patterns of spores of putrefactive anaerobe 3679 in various subculture media after heat treatment [J]. Appl Microbiol 15(2):266–276PubMedPubMedCentral

43.

Eriksson RA, Albrektsson T, Magnusson B (1984) Assessment of bone viability after heat trauma. A histological, histochemical and vital microscopic study in the rabbit [J]. Scand J Plast Reconstr Surg 18(3):261–268CrossRefPubMed

44.

HAmbleton J, Shakespeare PG (1991) Thermal damage to skin collagen [J]. Burns 17(3):209–212

45.

Sasaki KM, Aoki A, Ichinose S et al (2002) Scanning electron microscopy and Fourier transformed infrared spectroscopy analysis of bone removal using Er:YAG and CO2 lasers [J]. J Periodontol 73(6):643–652CrossRefPubMed

Titel: Temperature and depth evaluation of the in vitro effects of femtosecond laser on oral soft tissue, with or without air-cooling
verfasst von: Wenjun Li
Jianqiao Zheng
Yaopeng Zhang
Fusong Yuan
Peijun Lyu
Publikationsdatum: 13.09.2018
Verlag: Springer London
Erschienen in: Lasers in Medical Science / Ausgabe 4/2019
Print ISSN: 0268-8921
Elektronische ISSN: 1435-604X
DOI: https://doi.org/10.1007/s10103-018-2634-2

Springer Medizin

Abstract

Bitte loggen Sie sich ein, um Zugang zu diesem Inhalt zu erhalten

Weitere Artikel der Ausgabe 4/2019

Quantitative evaluation of skin shrinkage associated with non-invasive skin tightening: a simple method for reproducible linear measurement using microtattoos

Effect of blue LED on the healing process of third-degree skin burns: clinical and histological evaluation

Correction to: Comparative study using fractional carbon dioxide laser versus glycolic acid peel in treatment of pseudo-acanthosis nigricans

Melanocyte activation and skin barrier disruption induced in melasma patients after 1064 nm Nd:YAG laser treatment

Raman spectroscopy applications in rheumatology

Multi-wavelength laser treatments of spider nevi