通过电子倍增电荷耦合器件(EMCCD)增益控制系统和基于脂质体的造影剂提高超声可切换荧光的灵敏度和成像深度。
Improving sensitivity and imaging depth of ultrasound-switchable fluorescence via an EMCCD-gain-controlled system and a liposome-based contrast agent.
作者信息
Yao Tingfeng, Liu Yang, Ren Liqin, Yuan Baohong
机构信息
Ultrasound and Optical Imaging Laboratory, Department of Bioengineering, The University of Texas at Arlington, Arlington, TX, USA.
Joint Biomedical Engineering Program, The University of Texas at Arlington and The University of Texas Southwestern Medical Center, Dallas, TX, USA.
出版信息
Quant Imaging Med Surg. 2021 Mar;11(3):957-968. doi: 10.21037/qims-20-796.
BACKGROUND
The ultrasound-switchable fluorescence (USF) technique was recently developed to achieve high-resolution fluorescence imaging in centimeters-deep tissue. This study introduced strategies to significantly improve imaging sensitivity and depth using an electron multiplying charge-coupled device (EMCCD) camera-based USF imaging system and a newly developed USF contrast agent of indocyanine green (ICG)-encapsulated liposomes. For a quantitative study, a phantom of a sub-millimeter silicone tube embedded in centimeter-thick chicken breast tissue was adopted in this study as a model.
METHODS
The synthesized ICG-liposome was characterized and compared with the previously reported ICG-nanogel. The exposure of the EMCCD camera was controlled via the MATLAB (The MathWorks, Inc. USA), instead of an external hardware trigger. The stability of the electron multiplying (EM) gain of the EMCCD camera was compared between two trigger modes: the MATLAB trigger mode and the external hardware trigger mode. The signal-to-noise ratio (SNR) of the USF imaging with different EM gain in various thick tissue was studied.
RESULTS
The hydrodynamic size of the ICG-liposome was ~181 nm. The ICG-liposome had a sharper temperature switching curve and a better USF performance than the previously reported ICG-nanogel. The EM gain was more stable in MATLAB trigger mode than the external hardware trigger mode. Although, as usual, the SNR decreased quickly with the increase of the tissue thickness, the proposed strategies improved the SNR and the imaging depth significantly by adopting the novel contrast agent and controlling the EM gain.
CONCLUSIONS
We successfully imaged the sub-millimeter silicone tube with an inner diameter of 0.76 mm and an outer diameter of 1.65 mm in 5.5 cm-thick chicken breast tissue using 808 nm excitation light with a low intensity of 28.35 mW/cm, the improved EMCCD camera-based USF imaging system and the novel ICG-liposomes.
背景
超声可切换荧光(USF)技术最近被开发用于在厘米深的组织中实现高分辨率荧光成像。本研究引入了一些策略,使用基于电子倍增电荷耦合器件(EMCCD)相机的USF成像系统和新开发的包裹吲哚菁绿(ICG)的脂质体USF造影剂,显著提高成像灵敏度和深度。为了进行定量研究,本研究采用了嵌入厘米厚鸡胸组织中的亚毫米硅胶管模型。
方法
对合成的ICG脂质体进行表征,并与先前报道的ICG纳米凝胶进行比较。通过MATLAB(美国MathWorks公司)控制EMCCD相机的曝光,而不是外部硬件触发。比较了两种触发模式下EMCCD相机电子倍增(EM)增益的稳定性:MATLAB触发模式和外部硬件触发模式。研究了在不同厚度组织中不同EM增益下USF成像的信噪比(SNR)。
结果
ICG脂质体的流体动力学尺寸约为181nm。与先前报道的ICG纳米凝胶相比,ICG脂质体具有更陡峭的温度切换曲线和更好的USF性能。MATLAB触发模式下的EM增益比外部硬件触发模式更稳定。尽管通常情况下,SNR会随着组织厚度的增加而迅速下降,但通过采用新型造影剂和控制EM增益所提出的策略显著提高了SNR和成像深度。
结论
我们使用强度为28.35mW/cm的低强度808nm激发光、改进的基于EMCCD相机的USF成像系统和新型ICG脂质体,成功地在5.5cm厚的鸡胸组织中对内径为0.76mm、外径为1.65mm的亚毫米硅胶管进行了成像。
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