Kelvin E. Donne scite author profile

Penetration depth of ultraviolet, visible light and infrared radiation in biological tissue has not previously been adequately measured. Risk assessment of typical intense pulsed light and laser intensities, spectral characteristics and the subsequent chemical, physiological and psychological effects of such outputs on vital organs as consequence of inappropriate output use are examined. This technical note focuses on wavelength, illumination geometry and skin tone and their effect on the energy density (fluence) distribution within tissue. Monte Carlo modelling is one of the most widely used stochastic methods for the modelling of light transport in turbid biological media such as human skin. Using custom Monte Carlo simulation software of a multi-layered skin model, fluence distributions are produced for various non-ionising radiation combinations. Fluence distributions were analysed using Matlab mathematical software. Penetration depth increases with increasing wavelength with a maximum penetration depth of 5378 μm calculated. The calculations show that a 10-mm beam width produces a fluence level at target depths of 1–3 mm equal to 73–88% (depending on depth) of the fluence level at the same depths produced by an infinitely wide beam of equal incident fluence. Meaning little additional penetration is achieved with larger spot sizes. Fluence distribution within tissue and thus the treatment efficacy depends upon the illumination geometry and wavelength. To optimise therapeutic techniques, light-tissue interactions must be thoroughly understood and can be greatly supported by the use of mathematical modelling techniques.

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Real-time full matrix capture for ultrasonic non-destructive testing with acceleration of post-processing through graphic hardware

Sutcliffe

Weston²,

Dutton³

et al. 2012

NDT & E International

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Full matrix capture with time-efficient auto-focusing of unknown geometry through dual-layered media

Sutcliffe¹,

Weston²,

Charlton³

et al. 2013

insight

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Mathematical modeling of the optimum pulse structure for safe and effective photo epilation using broadband pulsed light

Ash

Donne

Daniel

et al. 2012

J Applied Clin Med Phys

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The objective of this work is the investigation of intense pulsed light (IPL) photoepilation using Monte Carlo simulation to model the effect of the output dosimetry with millisecond exposure used by typical commercial IPL systems. The temporal pulse shape is an important parameter, which may affect the biological tissue response in terms of efficacy and adverse reactions. This study investigates the effect that IPL pulse structures, namely free discharge, square pulse, close, and spaced pulse stacking, has on hair removal. The relationship between radiant exposure distribution during the IPL pulse and chromophore heating is explored and modeled for hair follicles and the epidermis using a custom Monte Carlo computer simulation. Consistent square pulse and close pulse stacking delivery of radiant exposure across the IPL pulse is shown to generate the most efficient specific heating of the target chromophore, whilst sparing the epidermis, compared to free discharge and pulse stacking pulse delivery. Free discharge systems produced the highest epidermal temperature in the model. This study presents modeled thermal data of a hair follicle in situ, indicating that square pulse IPL technology may be the most efficient and the safest method for photoepilation. The investigation also suggests that the square pulse system design is the most efficient, as energy is not wasted during pulse exposure or lost through interpulse delay times of stacked pulses.PACS number: 87.10.Rt

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Virtual source aperture imaging for non-destructive testing

Sutcliffe¹,

Weston²,

Charlton³

et al. 2012

insight

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Kelvin E. Donne

Effect of wavelength and beam width on penetration in light-tissue interaction using computational methods

Real-time full matrix capture for ultrasonic non-destructive testing with acceleration of post-processing through graphic hardware

Full matrix capture with time-efficient auto-focusing of unknown geometry through dual-layered media

Mathematical modeling of the optimum pulse structure for safe and effective photo epilation using broadband pulsed light

Virtual source aperture imaging for non-destructive testing

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