光声的等效噪声灵敏度。
Noise-equivalent sensitivity of photoacoustics.
出版信息
J Biomed Opt. 2013 Sep;18(9):097003. doi: 10.1117/1.JBO.18.9.097003.
Abstract
The fundamental limitations of photoacoustic microscopy for detecting optically absorbing molecules are investigated both theoretically and experimentally. We experimentally demonstrate noise-equivalent detection sensitivities of 160,000 methylene blue molecules (270 zeptomol or 2.7×10-19 mol) and 86,000 oxygenated hemoglobin molecules (140 zeptomol) using narrowband continuous-wave photoacoustics. The ultimate sensitivity of photoacoustics is fundamentally limited by thermal noise, which can present in the acoustic detection system as well as in the medium itself. Under the optimized conditions described herein and using commercially available detectors, photoacoustic microscopy can detect as few as 100s of oxygenated hemoglobin molecules. Realizable improvements to the detector may enable single molecule detection of select molecules.
摘要
本文从理论和实验两方面研究了光声显微镜探测光吸收分子的基本局限性。我们使用窄带连续波光声技术,实验演示了 160000 个亚甲基蓝分子(270 zeptomol 或 2.7×10-19 mol)和 86000 个氧合血红蛋白分子(140zeptomol)的等效噪声检测灵敏度。光声的极限灵敏度受到热噪声的根本限制,热噪声既可以出现在声学检测系统中,也可以出现在介质本身中。在本文所述的优化条件下,使用市售探测器,光声显微镜可以检测到少至 100 个氧合血红蛋白分子。对探测器的切实改进可能实现对特定分子的单分子检测。
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