Fabrication of a thin-layer solid optical tissue phantom by a spin-coating method: pilot study

Solid optical tissue phantoms (OTPs) have been widely used for many purposes. This study introduces a spin-coating method (SCM) to fabricate a thin-layer solid OTP (TSOTP) with epidermal thickness. TSOTPs are fabricated by controlling the spin speed (250 to 2500 rpm), absorber concentration (0.2% to...

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Veröffentlicht in:	Journal of biomedical optics 2013-02, Vol.18 (2), p.025006-025006
Hauptverfasser:	Bae, Yunjin, Son, Taeyoon, Park, Jihoon, Jung, Byungjo
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Sprache:	eng
Schlagworte:	Absorption coefficient Correlation Epidermis - anatomy & histology Feasibility Humans Multilayers Optical Imaging Optical Phenomena Phantoms, Imaging Pilots
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container_title	Journal of biomedical optics
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creator	Bae, Yunjin Son, Taeyoon Park, Jihoon Jung, Byungjo
description	Solid optical tissue phantoms (OTPs) have been widely used for many purposes. This study introduces a spin-coating method (SCM) to fabricate a thin-layer solid OTP (TSOTP) with epidermal thickness. TSOTPs are fabricated by controlling the spin speed (250 to 2500 rpm), absorber concentration (0.2% to 1.0%), and the number of layers. The results show that the thicknesses of the TSOTPs are homogeneous in the region of interest. The one-layer TSOTP achieves maximum and minimum thicknesses of 65±0.28 μm (250 rpm) and 5.1±0.17 μm (2500 rpm), respectively, decreasing exponentially as a function of the spin speed. The thicknesses of the multilayer TSOTPs increases as a function of the number of layers and are correlated strongly with the spin speed (R2≥0.95). The concentration of the OTP mixture does not directly affect the thickness of the TSOTP; however, the absorption coefficients exponentially increase as a function of absorber concentration (R2≥0.98). These results suggest that the SCM can be used to fabricate homogeneous TSOTPs with various thicknesses by controlling the spin speed and number of layers. Finally, a double-layer OTP that combines epidermal TSOTP and dermal OTP is manufactured as a preliminary study to investigate the practical feasibility of TSOTPs.
doi_str_mv	10.1117/1.JBO.18.2.025006
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Biomed. Opt</addtitle><description>Solid optical tissue phantoms (OTPs) have been widely used for many purposes. This study introduces a spin-coating method (SCM) to fabricate a thin-layer solid OTP (TSOTP) with epidermal thickness. TSOTPs are fabricated by controlling the spin speed (250 to 2500 rpm), absorber concentration (0.2% to 1.0%), and the number of layers. The results show that the thicknesses of the TSOTPs are homogeneous in the region of interest. The one-layer TSOTP achieves maximum and minimum thicknesses of 65±0.28 μm (250 rpm) and 5.1±0.17 μm (2500 rpm), respectively, decreasing exponentially as a function of the spin speed. The thicknesses of the multilayer TSOTPs increases as a function of the number of layers and are correlated strongly with the spin speed (R2≥0.95). The concentration of the OTP mixture does not directly affect the thickness of the TSOTP; however, the absorption coefficients exponentially increase as a function of absorber concentration (R2≥0.98). 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Biomed. Opt</addtitle><date>2013-02-01</date><risdate>2013</risdate><volume>18</volume><issue>2</issue><spage>025006</spage><epage>025006</epage><pages>025006-025006</pages><issn>1083-3668</issn><eissn>1560-2281</eissn><abstract>Solid optical tissue phantoms (OTPs) have been widely used for many purposes. This study introduces a spin-coating method (SCM) to fabricate a thin-layer solid OTP (TSOTP) with epidermal thickness. TSOTPs are fabricated by controlling the spin speed (250 to 2500 rpm), absorber concentration (0.2% to 1.0%), and the number of layers. The results show that the thicknesses of the TSOTPs are homogeneous in the region of interest. The one-layer TSOTP achieves maximum and minimum thicknesses of 65±0.28 μm (250 rpm) and 5.1±0.17 μm (2500 rpm), respectively, decreasing exponentially as a function of the spin speed. The thicknesses of the multilayer TSOTPs increases as a function of the number of layers and are correlated strongly with the spin speed (R2≥0.95). 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subjects	Absorption coefficient Correlation Epidermis - anatomy & histology Feasibility Humans Multilayers Optical Imaging Optical Phenomena Phantoms, Imaging Pilots
title	Fabrication of a thin-layer solid optical tissue phantom by a spin-coating method: pilot study
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