Improving fluorescence lifetime imaging microscopy phasor accuracy using convolutional neural networks

IF 2.8 Q2 MATHEMATICAL & COMPUTATIONAL BIOLOGY
Varun Mannam, Jacob P. Brandt, Cody J. Smith, Xiaotong Yuan, S. Howard
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引用次数: 0

Abstract

Introduction: Although a powerful biological imaging technique, fluorescence lifetime imaging microscopy (FLIM) faces challenges such as a slow acquisition rate, a low signal-to-noise ratio (SNR), and high cost and complexity. To address the fundamental problem of low SNR in FLIM images, we demonstrate how to use pre-trained convolutional neural networks (CNNs) to reduce noise in FLIM measurements.Methods: Our approach uses pre-learned models that have been previously validated on large datasets with different distributions than the training datasets, such as sample structures, noise distributions, and microscopy modalities in fluorescence microscopy, to eliminate the need to train a neural network from scratch or to acquire a large training dataset to denoise FLIM data. In addition, we are using the pre-trained networks in the inference stage, where the computation time is in milliseconds and accuracy is better than traditional denoising methods. To separate different fluorophores in lifetime images, the denoised images are then run through an unsupervised machine learning technique named “K-means clustering”.Results and Discussion: The results of the experiments carried out on in vivo mouse kidney tissue, Bovine pulmonary artery endothelial (BPAE) fixed cells that have been fluorescently labeled, and mouse kidney fixed samples that have been fluorescently labeled show that our demonstrated method can effectively remove noise from FLIM images and improve segmentation accuracy. Additionally, the performance of our method on out-of-distribution highly scattering in vivo plant samples shows that it can also improve SNR in challenging imaging conditions. Our proposed method provides a fast and accurate way to segment fluorescence lifetime images captured using any FLIM system. It is especially effective for separating fluorophores in noisy FLIM images, which is common in in vivo imaging where averaging is not applicable. Our approach significantly improves the identification of vital biologically relevant structures in biomedical imaging applications.
利用卷积神经网络提高荧光寿命成像显微镜相位精度
引言:荧光寿命成像显微镜(FLIM)虽然是一种强大的生物成像技术,但却面临着采集速度慢、信噪比(SNR)低、成本高且复杂等挑战。为了解决荧光寿命成像图像信噪比低这一根本问题,我们展示了如何使用预训练的卷积神经网络(CNN)来降低荧光寿命成像测量中的噪声:我们的方法使用预先学习的模型,这些模型之前已在大型数据集上进行过验证,这些数据集的分布与训练数据集不同,例如荧光显微镜中的样本结构、噪声分布和显微镜模式,因此无需从头开始训练神经网络,也无需获取大型训练数据集来对 FLIM 数据进行去噪处理。此外,我们还在推理阶段使用预先训练好的网络,其计算时间仅为毫秒级,准确性却优于传统的去噪方法。为了分离生命周期图像中的不同荧光团,去噪后的图像将通过一种名为 "K-means 聚类 "的无监督机器学习技术进行处理:在活体小鼠肾脏组织、已荧光标记的牛肺动脉内皮(BPAE)固定细胞和已荧光标记的小鼠肾脏固定样本上进行的实验结果表明,我们展示的方法能有效去除 FLIM 图像中的噪声,并提高分割精度。此外,我们的方法在分布外高散射活体植物样本上的表现表明,它还能在具有挑战性的成像条件下提高信噪比。我们提出的方法提供了一种快速、准确的方法来分割使用任何 FLIM 系统捕获的荧光寿命图像。这种方法对分离嘈杂 FLIM 图像中的荧光团特别有效,而这种情况在不适用平均法的活体成像中很常见。我们的方法大大提高了生物医学成像应用中重要生物相关结构的识别能力。
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CiteScore
2.60
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0.00%
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