Noise Learning of Instruments for High-contrast, High-resolution and Fast Hyperspectral Microscopy and Nanoscopy

Abstract: Raman spectroscopy provides molecular fingerprint information of materials and live-cells in a label-free way, but the intrinsic low Raman scattering efficiency makes it vulnerable to noise. There has to be a trade-off among signal-to-noise ratio (SNR), imaging speed, and spatial and spectral resolutions when Raman spectroscopy is combined with microscopy and especially nanoscopy. Here, we report a noise learning (NL) approach that can fit the intrinsic noise distribution of each instrument by statistically le… Show more

“…Early disease diagnosis SVM [ 142] Low SNR spectra Predict high SNR spectra for nanometer-resolution hyperspectral imaging U-net [ 143] Single-frame Raman imaging with nonchirped femtosecond pulses Predict subcellular organelle maps DenseNet [ 144] GPR-Gaussian process regression; RR-ridge regression; However, the solution of Maxwell's equations at each spatial location and each wavelength would take extensively long solution times and large computational domains, and even cannot reach a convergence in case of some highly complicated structures. Moreover, numerical simulations require a predesign of the structures, in other words, cannot complete inverse tasks.…”

“…This method far surpassed conventional supervised learning algorithms, tackled the trade‐off between imaging resolution and speed, and also showed the potential of improving the imaging speed and minimize the possibility of photobleaching and phototoxicity caused by high incident power and long acquisition time. [ 143 ] Similarly, Horgan et al applied a DL‐enabled Raman spectroscopy for high‐throughput molecular imaging. [ 295 ] Another DenseNet based DL architecture, termed as DeepChem, was proposed in order to further map the different subcellular organelles according to the spectral features, enabling continuous imaging of the same field of view for the study of biological interaction and cooperation.…”

Artificial Intelligence for Surface‐Enhanced Raman Spectroscopy

“…Early disease diagnosis SVM [ 142] Low SNR spectra Predict high SNR spectra for nanometer-resolution hyperspectral imaging U-net [ 143] Single-frame Raman imaging with nonchirped femtosecond pulses Predict subcellular organelle maps DenseNet [ 144] GPR-Gaussian process regression; RR-ridge regression; However, the solution of Maxwell's equations at each spatial location and each wavelength would take extensively long solution times and large computational domains, and even cannot reach a convergence in case of some highly complicated structures. Moreover, numerical simulations require a predesign of the structures, in other words, cannot complete inverse tasks.…”

“…This method far surpassed conventional supervised learning algorithms, tackled the trade‐off between imaging resolution and speed, and also showed the potential of improving the imaging speed and minimize the possibility of photobleaching and phototoxicity caused by high incident power and long acquisition time. [ 143 ] Similarly, Horgan et al applied a DL‐enabled Raman spectroscopy for high‐throughput molecular imaging. [ 295 ] Another DenseNet based DL architecture, termed as DeepChem, was proposed in order to further map the different subcellular organelles according to the spectral features, enabling continuous imaging of the same field of view for the study of biological interaction and cooperation.…”

Artificial Intelligence for Surface‐Enhanced Raman Spectroscopy