Bae Heejin, Kim Seung-Seob, Lee Seungsoo, Song Hyuna, Lee Songhyun, Koh Dalkwon, Kim Jae Gwan, Jung Dae Chul
Department of Radiology, Research Institute of Radiological Science, Yonsei University College of Medicine, Seoul, Korea.
Department of Biomicrosystem Engineering, Korea University College of Health Science, Seoul, Korea.
Ultrasonography. 2019 Apr;38(2):143-148. doi: 10.14366/usg.18030. Epub 2018 Jul 14.
This study aimed to develop a multi-channel near-infrared spectroscopy (NIRS) and ultrasonography (USG) fusion imaging system for imaging prostate cancer and to verify its diagnostic capability by applying the hybrid imaging system to a prostate cancer phantom.
A multi-channel NIRS system using the near-infrared 785-nm wavelength with 12 channels and four detectors was developed. After arranging the optical fibers around a USG transducer, we performed NIRS imaging and grayscale USG imaging simultaneously. Fusion imaging was obtained by processing incoming signals and the spatial reconstruction of NIRS, which corresponded with grayscale USG acquired at the same time. The NIRS-USG hybrid system was applied to a silicone-based optical phantom of the prostate gland containing prostate cancer to verify its diagnostic capability qualitatively.
The NIRS-USG hybrid imaging system for prostate cancer imaging simultaneously provided anatomical and optical information with 2-dimensional registration. The hybrid imaging system showed more NIR attenuation over the prostate cancer model than over the model of normal prostate tissue. Its diagnostic capability to discriminate a focal area mimicking the optical properties of prostate cancer from the surrounding background mimicking the optical properties of normal prostate tissue was verified by applying the hybrid system to a silicone-based optical phantom of prostate cancer.
This study successfully demonstrated that the NIRS-USG hybrid system may serve as a new imaging method for improving the diagnostic accuracy of prostate cancer, with potential utility for future clinical applications.
本研究旨在开发一种用于前列腺癌成像的多通道近红外光谱(NIRS)与超声(USG)融合成像系统,并通过将该混合成像系统应用于前列腺癌模型来验证其诊断能力。
开发了一种使用785 nm近红外波长、具有12个通道和四个探测器的多通道NIRS系统。在超声换能器周围布置光纤后,我们同时进行了NIRS成像和灰阶超声成像。通过处理输入信号和对NIRS进行空间重建获得融合成像,该重建与同时获取的灰阶超声相对应。将NIRS-USG混合系统应用于含有前列腺癌的硅基前列腺光学模型,以定性验证其诊断能力。
用于前列腺癌成像的NIRS-USG混合成像系统通过二维配准同时提供了解剖学和光学信息。混合成像系统显示,与正常前列腺组织模型相比,前列腺癌模型上的近红外衰减更多。通过将混合系统应用于硅基前列腺癌光学模型,验证了其从模拟正常前列腺组织光学特性的周围背景中区分模拟前列腺癌光学特性的局灶区域的诊断能力。
本研究成功证明,NIRS-USG混合系统可作为一种提高前列腺癌诊断准确性的新成像方法,具有未来临床应用的潜在价值。
