Ultrafast-laser-radiation transfer in heterogeneous tissues with the discrete-ordinates method

Guo, Zhixiong; Kim, Kyunghan

doi:10.1364/ao.42.002897

Cited by 60 publications

(37 citation statements)

References 25 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Other studies have shown that the diffusion approximation fails to predict the transmittance at early times for all optical thicknesses and also at long times for optically thin slabs [6]. In addition, Guo et al [7] showed that the diffusion approximation fails for both collimated radiation and strong anisotropically scattering media.…”

Section: Current State Of Knowledgementioning

confidence: 99%

Maximum time-resolved hemispherical reflectance of absorbing and isotropically scattering media

Smith

Katika

Pilon

2007

Journal of Quantitative Spectroscopy and Radiative Transfer

View full text Add to dashboard Cite

This paper presents a parametric study of the time-resolved hemispherical reflectance of a plane-parallel slab of homogeneous, cold, absorbing, and isotropically scattering medium exposed to a collimated Gaussian pulse. The front surface of the slab is transparent while the back surface is assumed to be cold and black. The onedimensional time-dependent radiation transfer equation is solved using the modified method of characteristics. The parameters explored include (1) the optical thickness, (2) the single scattering albedo of the medium, and (3) the incident pulse width. The study pays particular attention to the maximum transient hemispherical reflectance and identifies optically thin and thick regimes. It shows that the maximum reflectance is independent of the optical thickness in the optically thick regime. In the optically thin regime, however, the maximum hemispherical reflectance depends on all three parameters explored. The transition between the optically thick and thin regimes occurs when the optical thickness is approximately equal to the dimensionless pulse width. Finally, correlations relating the maximum of the hemispherical reflectance as a function of the optical thickness, the single scattering albedo of the materials and the incident pulse width have been developed. These correlations could be used to retrieve radiation characteristics or serve as initial guesses for more complex inversion schemes accounting for anisotropic scattering.

show abstract

Section: Current State Of Knowledgementioning

confidence: 99%

Maximum time-resolved hemispherical reflectance of absorbing and isotropically scattering media

Smith

Katika

Pilon

2007

Journal of Quantitative Spectroscopy and Radiative Transfer

View full text Add to dashboard Cite

show abstract

“…In the case of optically thick slabs, the diffusion approximation fails for short times. This issue has also been discussed by Guo and Kim [20] in the transport of ultra-fast laser pulses in biological tissues. In addition, it is difficult to describe collimated sources using the diffusion approximation without carefully choosing the source terms [21].…”

Section: Current State Of Knowledgementioning

confidence: 87%

Numerical feasibility analysis of an epidermal glucose sensor based on time-resolved fluorescence

Katika

Pilon

2006

Optical Interactions With Tissue and Cells XVII

View full text Add to dashboard Cite

This paper presents numerical simulations predicting the time-resolved reflectance and autofluorescence of human skin exposed to a pulse of collimated light at 337 nm and pulse width of 1 ns. Moreover, the feasibility of using an embedded time-resolved fluorescence sensor for monitoring glucose concentration is also studied. Skin is modeled as a multilayer medium with each layer having its own optical properties and fluorophore absorption coefficients, lifetimes and quantum yields. The intensity distributions of excitation and fluorescent light in skin are then determined by solving the transient radiative transfer equation using the modified method of characteristics. In both cases, the fluorophore lifetimes are recovered from the simulated fluorescence decays and compared with the actual lifetimes used in the simulations. It was found that the fluorescence lifetime of the fluorophore contributing the least to the fluorescence signal could not be recovered while the other lifetimes could be recovered within 2.5% of input values. Such simulations could be valuable in interpreting data from time-resolved fluorescence experiments on healthy and diseased tissue as well as in designing and testing the feasibility of various optical sensors for biomedical diagnostics.

show abstract

“…To limit thermal damage, external irradiation should be performed with a continuous-wave laser with cooling intervals (i.e., intermittent irradiation) [86] or with ultrafast irradiation with a pulsed laser (e.g., picosecond laser pulses) [109]. The combination of irradiation-and cooling intervals facilitates heat distribution to the solder-tissue interface and prevents excessive heat buildup in the underlying tissue.…”

Section: Status Quo Of Sslavw and Possible Solutions 341 Improvemementioning

confidence: 99%

“…In contrast to continuous-wave lasers that distribute heat to the deeper layer via conduction, the pulsed laser enables sufficient heat generation at the solder-tissue interface without over-coagulating the solder superficial layer. The pulsed laser produced stable welds with minimal thermal damage [109].…”

Section: Status Quo Of Sslavw and Possible Solutions 341 Improvemementioning

confidence: 99%

Laser-assisted vessel welding: state of the art and future outlook

Pabittei

Boon

Heger

et al. 2015

JCTRes

View full text Add to dashboard Cite

Laser-assisted vascular welding (LAVW) is an experimental technique being developed as an alternative to suture anastomosis. In comparison to mechanical anastomosis, LAVW is less traumatic, non-immunogenic, provides immediate water tight sealant, and possibly a faster and easier procedure for minimally invasive surgery. This review focuses on technical advances to improve welding strength and to reduce thermal damage in LAVW. In terms of welding strength, LAVW has evolved from the photothermally-induced microvascular anastomosis, requiring stay sutures to support welding strength, to sutureless anastomoses of medium-sized vessels, withstanding physiological and supraphysiological pressure. Further improvements in anastomotic strength could be achieved by the use of chromophore-containing albumin solder and the employment of (biocompatible) polymeric scaffolds. The anastomotic strength and the stability of welds achieved with such a modality, referred to as scaffold-and solder-enhanced LAVW (ssLAVW), are dependent on the intermolecular bonding of solder molecules (cohesive bonding) and the bonding between solder and tissue collagen (adhesive bonding). Presently, the challenges of ssLAVW include (1) obtaining an optimal balance between cohesive and adhesive bonding and (2) minimizing thermal damage. The modulation of thermodynamics during welding, the application of semi-solid solder, and the use of a scaffold that supports both cohesive and adhesive strength are essential to improve welding strength and to limit thermal damage.

show abstract

Ultrafast-laser-radiation transfer in heterogeneous tissues with the discrete-ordinates method

Cited by 60 publications

References 25 publications

Maximum time-resolved hemispherical reflectance of absorbing and isotropically scattering media

Maximum time-resolved hemispherical reflectance of absorbing and isotropically scattering media

Numerical feasibility analysis of an epidermal glucose sensor based on time-resolved fluorescence

Laser-assisted vessel welding: state of the art and future outlook

Contact Info

Product

Resources

About