The optical microscopy image plays an important role in scientific research through the direct visualization of the nanoworld,where the imaging mechanism is described as the convolution of the point spread function(PS...The optical microscopy image plays an important role in scientific research through the direct visualization of the nanoworld,where the imaging mechanism is described as the convolution of the point spread function(PSF)and emitters.Based on a priori knowledge of the PSF or equivalent PSF,it is possible to achieve more precise exploration of the nanoworld.However,it is an outstanding challenge to directly extract the PSF from microscopy images.Here,with the help of self-supervised learning,we propose a physics-informed masked autoencoder(PiMAE)that enables a learnable estimation of the PSF and emitters directly from the raw microscopy images.We demonstrate our method in synthetic data and real-world experiments with significant accuracy and noise robustness.PiMAE outperforms DeepSTORM and the Richardson–Lucy algorithm in synthetic data tasks with an average improvement of 19.6%and 50.7%(35 tasks),respectively,as measured by the normalized root mean square error(NRMSE)metric.This is achieved without prior knowledge of the PSF,in contrast to the supervised approach used by DeepSTORM and the known PSF assumption in the Richardson–Lucy algorithm.Our method,PiMAE,provides a feasible scheme for achieving the hidden imaging mechanism in optical microscopy and has the potential to learn hidden mechanisms in many more systems.展开更多
Dear Editor,We present here a case of an infertile man with azoospermia, from whom an insertion mutation (g. 1283_1284insAGTTTGCTG) near the beginning of the CAG repeat in the exon 1 of androgen receptor (AR) gene...Dear Editor,We present here a case of an infertile man with azoospermia, from whom an insertion mutation (g. 1283_1284insAGTTTGCTG) near the beginning of the CAG repeat in the exon 1 of androgen receptor (AR) gene is demonstrated.展开更多
基金Innovation Program for Quantum Science and Technology(2021ZD0303200)CAS Project for Young Scientists in Basic Research(YSBR-049)+2 种基金National Natural Science Foundation of China(62225506)Anhui Provincial Key Research and Development Plan(2022b13020006)USTC Center for Micro and Nanoscale Research and Fabrication。
文摘The optical microscopy image plays an important role in scientific research through the direct visualization of the nanoworld,where the imaging mechanism is described as the convolution of the point spread function(PSF)and emitters.Based on a priori knowledge of the PSF or equivalent PSF,it is possible to achieve more precise exploration of the nanoworld.However,it is an outstanding challenge to directly extract the PSF from microscopy images.Here,with the help of self-supervised learning,we propose a physics-informed masked autoencoder(PiMAE)that enables a learnable estimation of the PSF and emitters directly from the raw microscopy images.We demonstrate our method in synthetic data and real-world experiments with significant accuracy and noise robustness.PiMAE outperforms DeepSTORM and the Richardson–Lucy algorithm in synthetic data tasks with an average improvement of 19.6%and 50.7%(35 tasks),respectively,as measured by the normalized root mean square error(NRMSE)metric.This is achieved without prior knowledge of the PSF,in contrast to the supervised approach used by DeepSTORM and the known PSF assumption in the Richardson–Lucy algorithm.Our method,PiMAE,provides a feasible scheme for achieving the hidden imaging mechanism in optical microscopy and has the potential to learn hidden mechanisms in many more systems.
文摘Dear Editor,We present here a case of an infertile man with azoospermia, from whom an insertion mutation (g. 1283_1284insAGTTTGCTG) near the beginning of the CAG repeat in the exon 1 of androgen receptor (AR) gene is demonstrated.
