Ex vivo investigations of laser auricular cartilage reshaping with carbon dioxide spray cooling in a rabbit model

Laser cartilage reshaping (LCR) with cryogen spray cooling is a promising modality for producing cartilage shape change while reducing cutaneous thermal injury. However, LCR in thicker tissues, such as auricular cartilage, requires higher laser power, thus increasing cooling requirements. To elimina...

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Bibliographic Details
Published in:Lasers in medical science 2013-11, Vol.28 (6), p.1475-1482
Main Authors: Wu, Edward C., Sun, Victor, Manuel, Cyrus T., Protsenko, Dmitriy E., Jia, Wangcun, Nelson, J. Stuart, Wong, Brian J. F.
Format: Article
Language:English
Subjects:
Animals
Carbon Dioxide
Cartilage
Cryotherapy - methods
Dentistry
Ear Cartilage - injuries
Ear Cartilage - surgery
Laser surgery
Lasers
Lasers, Semiconductor - adverse effects
Lasers, Semiconductor - therapeutic use
Medicine
Medicine & Public Health
Models, Animal
Optical Devices
Optics
Original Article
Photonics
Plastic surgery
Quantum Optics
Rabbits
Skin - injuries
Skin Temperature
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Summary:Laser cartilage reshaping (LCR) with cryogen spray cooling is a promising modality for producing cartilage shape change while reducing cutaneous thermal injury. However, LCR in thicker tissues, such as auricular cartilage, requires higher laser power, thus increasing cooling requirements. To eliminate the risks of freeze injury characteristic of high cryogen spray pulse rates, a carbon dioxide (CO 2 ) spray, which evaporates rapidly from the skin, has been proposed as the cooling medium. This study aims to identify parameter sets which produce clinically significant reshaping while producing minimal skin thermal injury in LCR with CO 2 spray cooling in ex vivo rabbit auricular cartilage. Excised whole rabbit ears were mechanically deformed around a cylindrical jig and irradiated with a 1.45-μm wavelength diode laser (fluence 12–14 J/cm 2 per pulse, four to six pulse cycles per irradiation site, five to six irradiation sites per row for four rows on each sample) with concomitant application of CO 2 spray (pulse duration 33–85 ms) to the skin surface. Bend angle measurements were performed before and after irradiation, and the change quantified. Surface temperature distributions were measured during irradiation/cooling. Maximum skin surface temperature ranged between 49.0 to 97.6 °C following four heating/cooling cycles. Significant reshaping was achieved with all laser dosimetry values with a 50–70 °C difference noted between controls (no cooling) and irradiated ears. Increasing cooling pulse duration yielded progressively improved gross skin protection during irradiation. CO 2 spray cooling may potentially serve as an alternative to traditional cryogen spray cooling in LCR and may be the preferred cooling medium for thicker tissues. Future studies evaluating preclinical efficacy in an in vivo rabbit model are in progress.
ISSN:0268-8921
1435-604X
DOI:10.1007/s10103-012-1250-9