| 1.
Insights into coverage-affected selective catalytic oxidation of e..
[894]
|
| 2.
Free-breathing simultaneous native myocardial T1, T2 and T1ρ map..
[402]
|
| 3.
Correlation between the structural features and intrinsic activity..
[394]
|
| 4.
Joint Group-Wise Motion Estimation and Segmentation of Cardiac Cin..
[364]
|
| 5.
Cine Cardiac MR Super-resolution using a Fast Diffusion Model with..
[352]
|
| 6.
中国医学物理学科的建设与探索专家共识
[347]
|
| 7.
调整频率编码梯度波形实现磁共振成像降采样和重建方法、系统、终端及介..
[330]
|
| 8.
CARDIAC CINE MRI MOTION CORRECTION USING DIFFUSION MODELS
[328]
|
| 9.
Accelerated 3D free-breathing high-resolution myocardial T-1 rho m..
[316]
|
| 10.
Reversible hydrogen spillover at the atomic interface for efficien..
[307]
|
| 11.
Cardiac MR T1 Mapping with Shortened Acquisition Time and Window v..
[301]
|
| 12.
磁共振中基于投影选择的呼吸与心动信号提取方法、系统、终端及介质
[290]
|
| 13.
Cine Cardiac MRI Motion Correction using Denoising Diffusion Proba..
[277]
|
| 14.
Comprehensive understanding of ethylene epoxidation on copper cata..
[272]
|
| 15.
Comprehensive Study of Oxygen Vacancies on the Catalytic Performan..
[267]
|
| 16.
Grading Clear Cell Renal Cell Carcinoma Grade Using Diffusion Rela..
[266]
|
| 17.
Adjacent Axial Ligand Enables Secondary Coordination Effects in Me..
[264]
|
| 18.
Recurrent Neural Network-based Simultaneous Cardiac T1, T2, and T1..
[259]
|
| 19.
A High-Frequency Re-Optimization Network for MRI Reconstruction wi..
[258]
|
| 20.
Unified Deep Learning For Simultaneous Cardiac Cine MRI Reconstruc..
[257]
|
| 21.
Unravelling the Impact of Metal Dopants and Oxygen Vacancies on Sy..
[251]
|
| 22.
3D B1+corrected simultaneous myocardial T1 and T1Ï mapping with ..
[243]
|
| 23.
Real-time R-peak detection for 5T MRI Gating based on Template Mat..
[243]
|
| 24.
Microkinetic Modeling with Size-Dependent and Adsorbate-Adsorbate ..
[242]
|
| 25.
High Performance Pseudo-Pt@Pt Core-Shell Electrocatalyst for Oxyge..
[242]
|
| 26.
To characterize small renal cell carcinoma using diffusion relaxat..
[231]
|
| 27.
Advanced quantitative indexes in cardiovascular magnetic resonance..
[227]
|
| 28.
Joint Optimization Sampling and Reconstruction of Multi-Contrast M..
[227]
|
| 29.
Accelerated and Accurate Myocardial Multi-Parametric Quantitative ..
[226]
|
| 30.
Accelerated 4D Flow MRI Using Deep Low-Rank Plus Sparse Neural Net..
[226]
|
| 31.
Leveraging Interlayer Interaction in M-N-C Catalysts for Enhanced ..
[224]
|
| 32.
Low-field MRI: A report on the 2022 ISMRM workshop
[223]
|
| 33.
Free-breathing simultaneous myocardial T2 and T1ρ mapping for non..
[213]
|
| 34.
3D B1+ corrected simultaneous myocardial T1 and T1ρ mapping with ..
[213]
|
| 35.
JOINT OPTIMIZATION OF K-SPACE SAMPLING AND RECONSTRUCTION FOR MULT..
[211]
|
| 36.
3D free-breathing simultaneous myocardial T1 and T1ρ mapping with..
[206]
|
| 37.
Patient specific respiratory motion correction for cardiac MRI
[199]
|
| 38.
Recurrent Neural Network-based Simultaneous Cardiac T1, T2, and T1..
[188]
|
| 39.
Frequency Modulated Continuous Wave Radar-based respiratory motion..
[187]
|
| 40.
Cardiac Cine MRI Super-Resolution based on Diffusion Models
[184]
|
| 41.
Optimization of spin-lock preparation pulses for B1 and B0 insensi..
[170]
|
| 42.
Free-Breathing Simultaneous Native Myocardial T1, T2, and T1ρ Map..
[166]
|
| 43.
Deep-learning-based optimization for the k-space acquisition in se..
[152]
|
| 44.
Assessment of Cardiomyopathy at Different CKD Stages using Free-br..
[151]
|
| 45.
High-resolution free-breathing simultaneous myocardial T1, T2 and ..
[143]
|
| 46.
医学扫描的运动校正方法、装置和医学成像系统
[54]
|
| 47.
Secondary Coordination Effects of Adjacent Metal Center in Metal-N..
[43]
|
| 48.
AI-Assisted Compressed Sensing Enables Faster Brain MRI for the El..
[36]
|
| 49.
The curvature structure unlocks an ultra-efficient metal-free carb..
[31]
|
| 50.
Accelerating the identification of the rate controlling steps by c..
[18]
|
| 51.
A unified deep learning model for simultaneous cardiac cine MRI re..
[14]
|
