nach oben

Lasers in Medical Science

Erschienen in:

01.07.2019 | Original Article

Continuous cooling system in conjunction with laser surgery for ear reshaping

verfasst von: Yen-Chang Hsiao, Kuen Ting, Yun-Liang Su, Cheng-Jen Chang

Erschienen in: Lasers in Medical Science | Ausgabe 2/2020

Einloggen, um Zugang zu erhalten

Abstract

When the cartilage on the prominent ears is reshaped, the arising stress returns the tissue to its initial configuration. Laser irradiation of areas of maximal stress leads to stress relaxation and results in a stable configuration. Sixty auricles were harvested from 30 New Zealand white rabbits and cut into a rectangle measuring 50 mm by 25 mm with an average thickness of approximately 1.3 mm. Bilateral skin was included for ex vivo studies. Continuous cryogen spray cooling (CSC) with laser energy was delivered to the exposed cartilage for reshaping. In clinical applications, from January 2006 to December 2016, a total of 50 patients with 100 bat ears who underwent CO₂ laser reshaping (otoplasty) were assessed. A continuous cooling system (4 °C) in conjunction with a CO₂ laser was applied to make a retroauricular-approached incision and reshape the ear cartilage. The well cartilage bending correlated with the different parameters demonstrated in the continuous CSC protected group. All 100 (100%) of the subjects experienced early complications (≤ 1 month) related to laser exposure with swelling, while 5 (5%) experienced ecchymosis, 2 (2%) minimal hematoma, 2 (2%) scarring, 1 (1%) minor infection, 1 (1%) under correction, 1 (1%) overcorrection, and 1 (1%) relapse. These problems were corrected and/or had resolved after 3 months. All patients achieved good to excellent results in our final outcome assessment (> 6 months). Laser reshaping has a potential use in certain surgical procedures involving the cartilage. The appropriate conditions for laser ear reshaping clearly depend on the laser wavelength used, energy controlling, and tissue optical properties.

Chang CJ, Sally Cheng MH, Lynn LC, Wong BJF, Ting K (2008) Minimizing superficial thermal injury using bilateral cryogen spray cooling during laser reshaping of composite cartilage grafts. Lasers Surg Med 40:477–482CrossRef

Sobol E, Sviridov A, Omel'chenko A, Bagratashvili V, Kitai M, Harding SE, Jones N, Jumel K, Mertig M, Pompe W, Ovchinnikov Y, Shekhter A, Svistushkin V (2000) Laser reshaping of cartilage. Biotechnol Genet Eng Rev 17:553–578CrossRef

Stark H (1991) Otoplasty using the CO₂ laser. Laryngorhinootologie 70:652CrossRef

Wong BJ, Milner TE, Harrington A, Ro J, Dao X, Sobol EN, Nelson JS (1999) Feedback controlled laser mediated cartilage reshaping. Arch Facial Plast Surg 1:282–287CrossRef

Wang Z, Pankratov MM, Perrault DF, Pankratov MM, Shapshay SM (1995) Laser-assisted cartilage reshaping: in vitro and in vivo animal studies. Proc SPIE 2395:296–302CrossRef

Velegrakis GA, Papadakis CE, Nikolidakis AA, Prokopakis EP, Volitakis ME, Naoumidi I, Helidonis ES (2000) In vitro ear cartilage shaping with carbon dioxide laser: an experimental study. Ann Otol Rhinol Laryngol 109:1162–1166CrossRef

Helidonis E, Volitakis M, Naumidi I, Velegrakis G, Bizakis J, Christodoulou P (1994) The histology of laser thermo-chondro-plasty. Am J Otolaryngol 15:423–428CrossRef

Chang CJ, Tsang KL, Chiu LL, Wong BJF (2004) Reduction of superficial thermal injury using cryogen spray cooling in conjunction with Nd: YAG laser for cartilage reshaping of composite cartilage flaps: preliminary investigation. Formos J Surg 37:8–15

Gilchrest BA, Rosen S, Noe JM (1982) Chilling port wine stains improves the response to argon laser therapy. Plast Reconstr Surg 69:278–283CrossRef

10.

Dréno B, Patrice T, Litoux P, Barrière H (1985) The benefit of chilling in argon laser treatment of port wine stains. Plast Reconstr Surg 75:42–45CrossRef

11.

Chess C, Chess Q (1993) Cool laser optics treatment of large telangiectasia of the lower extremities. J Dermatol Surg Oncol 19:74–80CrossRef

12.

Chang CJ, Ma SF, Tzeng YF, Wei FC (2002) Dynamic cooling for laser photocoagulation: in vivo & ex vivo studies. J Med Biol Eng 22:25–32

13.

Chang CJ, Yu DY, Chen HC, Chang SY, Hsiao YC, Ting K, Lin WS, Cheng SF, Chen KT, Hou KH (2015) Real-time photothermal imaging and response in pulsed dye laser treatment for port wine stain patients. Biom J 38:342–349

14.

Nelson JS, Milner TE, Anvari B, Tanenbaum BS, Kimel S, Svaasand LO, Jacques SL (1995) Dynamic epidermal cooling during pulsed laser treatment of port wine stain-a new methodology with preliminary clinical evaluation. Arch Dermatol 131:695–700CrossRef

15.

Chang CJ, Nelson JS (1999) Cryogen spray cooling and higher fluence pulsed dye laser treatment improve port wine stain clearance while minimizing epidermal damage. J Dermatol Surg 25:767–772CrossRef

16.

Geronemus R, Lou W, Quintana A, Kauvar A (2000) High fluence modified pulsed dye laser photocoagulation with dynamic cooling for port wine stains in infancy. Arch Dermatol 136:942–943CrossRef

17.

Chang CJ, Kelly KM, van Gemert MJC, Nelson JS (2002) Comparing the effectiveness of 585-nm versus 595-nm wavelength pulsed dye laser treatment of port-wine stains in conjunction with cryogen spray cooling during. Lasers Surg Med 31:352–358CrossRef

18.

Chang CJ, Anvari B, Nelson JS (1998) Cryogen spray cooling for spatially selective photocoagulation of hemangiomas-a new methodology with preliminary clinical reports. Plast Reconstr Surg 102:459–463CrossRef

19.

Chang CJ, Kelly KM, Nelson JS (2001) Cryogen spray cooling and pulsed dye laser treatment of cutaneous hemangiomas. Ann Plast Surg 46:577–583CrossRef

20.

Huang PS, Chang CJ (2001) Cryogen spray cooling in conjunction with pulse dye laser treatment of port wine stains of the head and neck. Chang Gung Med J 24:469–475PubMed

21.

Manzer LE (1990) The CFCs-ozone issue: progress on the development of alternative to CFCs. Science 249:31–36CrossRef

22.

Magaribuchi T, Ito Y, Kuriyama H (1973) Effects of rapid cooling on the mechanical and electrical activities of smooth muscles of guinea pig stomach and taenia coli. J Gen Physiol 61:323–341CrossRef

23.

Sun YS, Weng CI, Chen TC, Li WC (1996) Estimation of surface absorptivity and surface temperature in laser surface hardening process. Jpn J Appl Phys 35:3658–3664CrossRef

24.

Ting K, Chen KT, Cheng SF, Lin WS, Chang CJ (2008) Prediction of skin temperature distribution in cosmetic laser surgery. Jpn J Appl Phys 47:361–367CrossRef

25.

Liu J (2001) Uncertainty analysis for temperature prediction of biological bodies subject to randomly spatial heating. J Biomech 34:1637–1642CrossRef

26.

Alexander RR, Griffiths JM (1993) Basic biochemical methods, 2nd ed. Wiley-Liss, Inc., New York, p 181

27.

Kaminski W (1990) Hyperbolic heat conduction equation for materials with a non-homogeneous inner structure. J Heat Transf 112:555–560CrossRef

28.

Diller KR, Hayes LJ (1991) Analysis of tissue injury by burning: comparison of in situ and skin flap models. Int J Heat Mass Transf 34:1393–1406CrossRef

29.

Lecarpentier GL, Motamedi M, Mcmath LP, Rastegar S, Welch AJ (1993) Continuous wave laser ablation of tissue: analysis of thermal and mechanical events. IEEE Trans Biomed Eng 40:188–200CrossRef

30.

Moritz AR, Henriques FC (1947) Studies of thermal injury II. Relative importance of time and surface temperature in the causation of cutaneous burns. Am J Pathol 23:695–720PubMedPubMedCentral

31.

Stoll AM, Greene LC (1959) Relationship between pain and tissue damage due to thermal radiation. J Appl Physiol 14:373–382CrossRef

32.

Torvi DA, Dale JD (1994) A finite element model of skin subjected to a flash fire. J Biomech Eng 116:250–255CrossRef

33.

Mitra K, Kumar S, Vedavarz A, Moallemi MK (1995) Experimental evidence of hyperbolic heat conduction in processes meat. ASME J Heat Transfer 117:568–573CrossRef

34.

Liu J, Ren Z, Wang C (1995) Interpretation of living tissue’s temperature oscillations by thermal wave theory. Chin Sci Bull 40:1493

35.

Lu WQ, Liu J, Zeng Y (1998) Simulation of the thermal wave propagation in biological tissues by the dual reciprocity boundary element method. Eng Anal Bound Elem 22:167–174CrossRef

36.

Nabil TM, Mona AA, Asma FE (2003) Effects of microwave heating on the thermal states of biological tissues. Afr J Biotechnol 2:453–459CrossRef

37.

Cattaneo C (1958) A form of heat conduction equation which eliminates the paradox of instantaneous propagation. Compte Rendus 247:431–433

Titel: Continuous cooling system in conjunction with laser surgery for ear reshaping
verfasst von: Yen-Chang Hsiao
Kuen Ting
Yun-Liang Su
Cheng-Jen Chang
Publikationsdatum: 01.07.2019
Verlag: Springer London
Erschienen in: Lasers in Medical Science / Ausgabe 2/2020
Print ISSN: 0268-8921
Elektronische ISSN: 1435-604X
DOI: https://doi.org/10.1007/s10103-019-02831-3

Springer Medizin

Abstract

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

Weitere Artikel der Ausgabe 2/2020

Comparative effects of photobiomodulation therapy at wavelengths of 660 and 808 nm on regeneration of inferior alveolar nerve in rats following crush injury

Detecting creatine excreted in the urine of swimming athletes by means of Raman spectroscopy

Modulatory effect of photobiomodulation on stem cell epigenetic memory: a highlight on differentiation capacity

Comparison of efficacy and safety of a novel 755-nm diode laser with conventional 755-nm alexandrite laser in reduction of axillary hairs

Comment on “Clinical study on the efficacy of LED phototherapy for pain control in an orthodontic procedure”

The effect of the debulking by excimer laser coronary angioplasty on long-term outcome compared with drug-coating balloon: insights from optical frequency domain imaging analysis