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Book ChapterDOI

History of lasers in dermatology.

M L Geiges1
University of Zurich1
01 Jan 2011-Current problems in dermatology (Karger Publishers)-Vol. 42, pp 1-6
TL;DR: In the 1950s, based on the theory of stimulating radiant energy published by Albert Einstein in 1916, the collaboration of physicists and electrical engineers, searching for monochromatic radiation to study the spectra of molecules, led to the invention of the first laser in 1960.
Abstract: In the 1950s, based on the theory of stimulating radiant energy published by Albert Einstein in 1916, the collaboration of physicists and electrical engineers, searching for monochromatic radiation to study the spectra of molecules, led to the invention of the first laser in 1960. Ophthalmologists and dermatologists were the first to study the biological effects and therapeutic possibilities of laser beams. The construction of new laser systems emitting energy at different wavelengths or with different durations, as well as the development of new concepts of the biomedical effects, led to its broad use in surgery in the treatment of vascular and pigmented lesions as well as cosmetic applications.
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Citations
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Journal ArticleDOI
Lasers and laser‐like devices: Part one

[...]

Nicholas Stewart, Adrian Lim1, Patricia Lowe2, Greg J. Goodman
Royal North Shore Hospital1, University of Sydney2
01 Aug 2013-Australasian Journal of Dermatology
TL;DR: Non‐laser energy devices utilising intense pulsed light, plasma, radiofrequency, ultrasound and cryolipolysis contribute to the modern laser practitioners' armamentarium and will also be discussed.
Abstract: Lasers have been used in dermatology for nearly 50 years. Through their selective targeting of skin chromophores they have become the preferred treatment for many skin conditions, including vascular malformations, photorejuvenation and acne scars. The technology and design of lasers continue to evolve, allowing greater control of laser parameters and resulting in increased safety and efficacy for patients. Innovations have allowed the range of conditions and the skin types amenable to treatment, in both general and cosmetic dermatology, to expand over the last decade. Integrated skin cooling and laser beam fractionation, for example, have improved safety, patient tolerance and decreased downtime. Furthermore, the availability and affordability of quality devices continues to increase, allowing clinicians not only to access laser therapies more readily but also to develop their personal experience in this field. As a result, most Australian dermatologists now have access to laser therapies, either in their own practice or within referable proximity, and practical knowledge of these technologies is increasingly required and expected by patients. Non-laser energy devices utilising intense pulsed light, plasma, radiofrequency, ultrasound and cryolipolysis contribute to the modern laser practitioners' armamentarium and will also be discussed.

64 citations

Journal ArticleDOI
Lasers and nevus of Ota: a comprehensive review

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Vidhi V. Shah1, Fleta N. Bray1, Adam S. Aldahan1, Stephanie Mlacker1, Keyvan Nouri1 
University of Miami1
01 Jan 2016-Lasers in Medical Science
TL;DR: The purpose of this review article is to summarize the clinical efficacy and side effects associated with QS lasers and the treatment of nevus of Ota lesions.
Abstract: Nevus of Ota is a benign dermal melanocytic nevus that typically affects Asian children and women. The nevus presents as unilateral blue-gray hyperpigmented macules and patches scattered along the first and second divisions of the trigeminal nerve. Individuals with nevus of Ota experience emotional and psychosocial distress related to cosmetic disfigurement and often look for treatment options. Unfortunately, even when treated early, lesions of nevus of Ota are still difficult to treat. The use of lasers for the treatment of nevus of Ota lesions has become helpful in the management of dermal nevi. Currently, Q-switched (QS) lasers have been the most studied and demonstrated positive results for treatment of nevus of Ota. The purpose of this review article is to summarize the clinical efficacy and side effects associated with QS lasers and the treatment of nevus of Ota lesions.

27 citations

Journal ArticleDOI
Non-Ablative Fractional Laser to Facilitate Transdermal Delivery.

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Sindhu S. Ganti1, Ajay K. Banga1
Mercer University1
01 Nov 2016-Journal of Pharmaceutical Sciences
TL;DR: This is a first of its kind study that demonstrates the use of 1410 nm non-ablative fractional laser to enhance transdermal permeation of 2 small molecular weight drugs.

20 citations

Book ChapterDOI
Introduction: the history of lasers in medicine

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H. Jelínková1
Czech Technical University in Prague1
01 Jan 2013
TL;DR: In this paper, the basic principles of the interaction of laser radiation with tissue are explained and the main factors influencing the results of interaction are analyzed, including spectral reflection, refraction, absorption, scattering, and transmission.
Abstract: On the background of the history of laser medicine, the basic principles of the interaction of laser radiation with tissue are explained and the main factors influencing the results of the interaction are analyzed. After description of .laser radiation and tissue main characteristics, the primary factors of laser radiation interaction with tissue, including spectral reflection, refraction, absorption, scattering, and transmission, are defined. Secondary factors, i.e. photochemical or photothermal interaction (non-ablative heating, vaporization), photo-ablation, plasma-induced ablation, and photo-disruption are then mentioned.

14 citations

Journal ArticleDOI
History of dermatology: the study of skin diseases over the centuries.

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Iago Gonçalves Ferreira1, Magda Blessmann Weber1, Renan Rangel Bonamigo2
Universidade Federal de Ciências da Saúde de Porto Alegre1, Universidade Federal do Rio Grande do Sul2
01 May 2021-Anais Brasileiros De Dermatologia
TL;DR: In this article, the authors provide a historical synthesis for the medical community to recognize and understand the origins that supported one of the most relevant specialties in the current medical scenario, the field of dermatology.
Abstract: The study of skin, the science of dermatology, has undergone significant transformations throughout the centuries. From the first descriptions of skin diseases in Egyptian papyri and in Hippocratic writings to the first treatises on dermatology, important individuals and discoveries have marked the specialty. In the 18th and 19th centuries, the specialty consolidated itself as a field of medical study based on the first classifications of dermatoses, diagnostic methods, and drug treatments. In the 20th century, the scientific and technological revolution transformed dermatological practice, incorporating new therapeutic resources, as well as surgical and aesthetic procedures. In the face of such a vigorous process, it is important to provide a historical synthesis for the medical community to recognize and understand the origins that supported one of the most relevant specialties in the current medical scenario.

9 citations

References
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Journal ArticleDOI
Maser Action in Ruby

[...]

George Makhov, Chihiro Kikuchi, John Lambe, Robert W. Terhune
15 Feb 1958-Physical Review

69 citations

Journal ArticleDOI
Use of the alexandrite laser (755 nm, 100 nsec) for tattoo pigment removal in an animal model

[...]

Richard E. Fitzpatrick, Mitchel P. Goldman, Javier Ruiz-Esparza
01 May 1993-Journal of The American Academy of Dermatology
TL;DR: The alexandrite laser shows promise as a treatment modality for tattoo removal without scarring and was found to be very effective in removal of professional and amateur black tattoo pigment and minimally effective in Removal of red pigment.
Abstract: Background: All previous treatment modalities for the removal of tattoos, with the possible exception of the Q-switched ruby and YAG lasers, result in scarring. Objective: The purpose of this study was to investigate the use of a new laser that may remove tattoo pigment without leaving a scar. Methods: A Yucatan micropig was tattooed by a professional tattoo artist with black, blue, green, and red pigments. These tattoos were then treated with single overlapping pulses with the alexandrite laser (wavelength 755 nm, pulse 100 nsec) and evaluated clinically and histologically. Comparison treatment with an argon laser (wavelength 488 nm, 514 nm, continuous-wave) and flashlamp-pumped dye laser (wavelength 585 nm, pulse 450 μsec) was performed as well for removal of red tattoo pigment. Results: The alexandrite laser was found to be very effective in removal of professional and amateur black tattoo pigment, moderately effective in removal of blue and green pigment, and minimally effective in removal of red pigment. No scarring was seen clinically or histologically. Conclusion: The alexandrite laser shows promise as a treatment modality for tattoo removal without scarring.

51 citations

Journal ArticleDOI
Production of Coherent Radiation by Atoms and Molecules.

[...]

Charles H. Townes1
Massachusetts Institute of Technology1
20 Aug 1965-Science
TL;DR: These two regimes, radio electronics and optics, have now come much closer together in the field known as quantum electronics, and have lent each other interesting insights and powerful techniques.
Abstract: From the time when man first saw the sunlight until very recently, the light which he has used has come dominantly from spontaneous emission, like the random emission of incandescent sources. So have most other types of electromagnetic radiation-infrared, ultraviolet, or gamma rays. The maximum radiation intensities, or specifically the power radiated per unit area per unit solid angle per unit frequency bandwidth, have been controlled by Planck's black-body law for radiation from hot objects. This sets an upper limit on radiation intensity-a limit which increases with increasing temperature, but we have had available temperatures of only a few tens of thousands or possibly a few millions of degrees. Radio waves have been different. And, perhaps without our realizing it, even much of our thinking about radio waves has been different, in spite of Maxwell's demonstration before their discovery that the equations governing radio waves are identical with those for light. The black-body law made radio waves so weak that emission from hot objects could not, for a long time, have been even detected. Hence their discovery by Hertz and the great use of radio waves depended on the availability of quite different types of sources-oscilla-tors and amplifiers for which the idea of temperature and black-body radiation even seems rather out of place. For example, if we express the radiation intensity of a modern electronic oscillator in terms of temperature, it will typically be in the range 10 10 to 10 30 degrees Kelvin. These two regimes, radio electronics and optics, have now come much closer together in the field known as quantum electronics, and have lent each other interesting insights and powerful techniques. The development of radar stimulated many important applications of electronics to scientific problems, and what occupied me in particular during the late 1940's was microwave spectroscopy, the study of interactions between microwaves and molecules. From this research, considerable information could be obtained about molecular, atomic, and nuclear structure. For its success, coherent microwave oscillators were crucial in allowing a powerful

36 citations

Journal ArticleDOI
Theory of the Pulsation of Fluorescent Light From Ruby

[...]

Robert W. Hellwarth1
HRL Laboratories1
01 Jan 1961-Physical Review Letters

33 citations

Journal ArticleDOI
Amplification of microwave radiation by substances not in thermal equilibrium

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J. Weber1
University of Maryland, College Park1
01 Jun 1953-Transactions of The Ire Professional Group on Electron Devices
TL;DR: In this paper, it was shown that it is possible to obtain coherent microwave radiation from crystals and gases, provided that a certain non-equilibrium energy distribution is first produced, and the amount of amplification which can be produced by such methods is very small under ordinary circumstances and does not appear to be able to compete with other methods.
Abstract: This paper briefly discusses the possibility of obtaining coherent microwave radiation from crystals and gases. It will be shown that it is possible to obtain coherent microwave radiation by such methods, provided that a certain non equilibrium energy distribution is first produced. Methods are discussed for producing such a distribution. The amount of amplification which can be produced by such methods is very small Tinder ordinary circumstances and does not appear to be able to compete with other methods. The method may have certain special applications.

33 citations

Related Papers (5)
Fractional Photothermolysis: A New Concept for Cutaneous Remodeling Using Microscopic Patterns of Thermal Injury

[...]

01 Jun 2004-Lasers in Surgery and Medicine
Dieter Manstein, G. Scott Herron, R. Kehl Sink, Heather Tanner, R. Rox Anderson 
Selective photothermolysis: precise microsurgery by selective absorption of pulsed radiation

[...]

29 Apr 1983-Science
R. Rox Anderson, John A. Parrish
Basics in Dermatological Laser Applications

[...]

18 Aug 2011
I. Bogdan Allemann, David J. Goldberg
Surgical solid-state lasers and their clinical applications

[...]

01 Jan 2013
D.G. Kochiev, A.M. Prokhorov, A.V. Lukashev, I.A.S Hcherbakov, S.K. Vartapetov 
Recent advances in laser dermatology.

[...]

12 Jul 2009-Journal of Cosmetic and Laser Therapy
Anjali Butani, Jacob Dudelzak, David J. Goldberg
Frequently Asked Questions (14)
Q1. What contributions have the authors mentioned in the paper "History of lasers in dermatology" ?

Geiges et al. this paper presented a history of the use of laser technology in dermatology. 

In 1996, the erbium (Er):YAG laser with a very short wavelength of 2,940 nm allowed a more superficial vaporization of tissue and was used together with CO2 lasers for skin resurfacing. 

The first attempt to minimize this nonspecific tissue injury involved making the continuous- wave lasers discontinuous or quasi- continuous by using a mechanical shutter to interrupt the beam of light. 

The ruby laser was ineffective when used as an optical scalpel for cutting or coagulation, and when using high- energy pulses the effect became unpredictable because of cavitations (vapor bubbles). 

He expected the laser to bring substantial benefits to the treatment of skin cancer: ‘Because of the accessibility and color, laser surgery can be used extensively in the field of skin cancer. 

The medical specialists who were already treating diseases with sunlight and technical light sources were also the first to carry out biomedical research with lasers. 

In dermatology, the treatment of skin diseases with light has a long tradition – e.g. lupus vulgaris with the Finsen lamp in 1899, wound healing and rickets with artificial UV light sources afterHistory of Lasers in Dermatology 31901, and psoriasis with the combination of light and tar in 1925. 

In 1960, he presented the first functional optical ruby maser excited by a xenon flash lamp to produce a bright pulse of 693.7 nm, deep red light of about a 1- ms duration and a power output of about a billion watt per pulse [14]. 

Although the essential ideas for constructing a laser were known around 1930, it was not before the early 1950s that physicists and electrical engineers began to collaborate with the research on monochromatic radiation of constant amplitude at very small wavelengths studying the microwave and radio frequency spectra of molecules. 

In 1961, Fred J. McClung and Robert W. Hellwarth introduced the quality- switching (Q- switching) technique to shorten the pulse length to nanoseconds with the use of an electro- optical shutter that permitted the storage and subsequent release of a peak power up to gigawatts of energy [15, 16]. 

The ammonia beam maser itself was not particularly useful as its operation was limited to the resonant frequency of the ammonia molecule and could only be used at barely detectable power levels [1]. 

In the 1980s, the pulsed ruby laser was commercialized in Japan for the treatment of tattoos and pigmented lesions, while being abandoned in Europe and the USA where tattoo removal was performed by CO2 laser vaporization [27]. 

One year after Maiman had presented the first ruby laser, ophthalmologists using xenon lamps for retinal photocoagulation published on ocular lesions experimentally produced in a rabbit by an optical maser [17]. 

Theodore Maiman was enthusiastic about the first laser he constructed, but regarded it as ‘a solution looking for a problem’ [1].