使用各种光声成像系统对人类牙齿进行成像。

human teeth imaging with various photoacoustic imaging systems.

作者信息

Periyasamy Vijitha, Gisi Katherine, Pramanik Manojit

机构信息

Department of Electrical and Computer Engineering, Iowa State University, Ames, Iowa 50011, USA.

出版信息

Biomed Opt Express. 2024 Aug 23;15(9):5479-5490. doi: 10.1364/BOE.531436. eCollection 2024 Sep 1.

DOI:10.1364/BOE.531436

PMID:39296410

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11407247/

Abstract

Dental caries cause pain and if not diagnosed, it may lead to the loss of teeth in extreme cases. Dental X-ray imaging is the gold standard for caries detection; however, it cannot detect hidden caries. In addition, the ionizing nature of X-ray radiation is another concern. Hence, other alternate imaging modalities like photoacoustic (PA) imaging are being explored for dental imaging. Here, we demonstrate the feasibility of acoustic resolution photoacoustic microscopy (ARPAM) to image a tooth with metal filling, circular photoacoustic computed tomography (cPACT) to acquire images of teeth with caries and pigmentation, and linear array-based photoacoustic imaging (lPACT) of teeth with caries and pigmentation. The cavity measured with lPACT imaging is compared with the X-ray computed tomography image. The metal filling and its boundaries are clearly seen in the ARPAM image. cPACT images at 1064 nm were a better representative of the tooth surface compared to the images acquired at 532 nm. It was possible to detect the cavities present in the dentine when lPACT imaging was used. The PA signal from the pigmented caries on the lateral surface (occlusion view) of the tooth was high when imaged using the lPACT system.

摘要

龋齿会引起疼痛，如果不进行诊断，在极端情况下可能会导致牙齿脱落。牙科X射线成像是龋齿检测的金标准；然而，它无法检测出隐匿性龋齿。此外，X射线辐射的电离特性是另一个问题。因此，正在探索其他替代成像方式，如光声（PA）成像用于牙科成像。在此，我们展示了声学分辨率光声显微镜（ARPAM）对有金属填充物的牙齿进行成像的可行性，圆形光声计算机断层扫描（cPACT）用于获取有龋齿和色素沉着的牙齿图像，以及基于线性阵列的光声成像（lPACT）用于有龋齿和色素沉着的牙齿成像。将用lPACT成像测量的龋洞与X射线计算机断层扫描图像进行比较。在ARPAM图像中可以清楚地看到金属填充物及其边界。与在532nm处采集的图像相比，1064nm处的cPACT图像能更好地代表牙齿表面。使用lPACT成像时，可以检测到牙本质中存在的龋洞。当使用lPACT系统成像时，牙齿侧面（咬合面视图）色素沉着龋齿的光声信号很高。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4ba2/11407247/f32d7b3782f0/boe-15-9-5479-g001.jpg

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使用各种光声成像系统对人类牙齿进行成像。

human teeth imaging with various photoacoustic imaging systems.

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