Table 1.
Summary of some studies showing the application of AI for initial neuroimaging in AIS [Acute Ischemic Stroke] between 2000 and 2023.
| Year | Authors | Research Question | Outcomes Measures/Conclusions |
|---|---|---|---|
| 2023 [12] | Field N. et al. | Does supplying an LVO detection algorithm notification to the thrombectomy team’s cell phone improve ischemic stroke workflow? | Transfer time and Mechanical Thrombectomy [MT] Initiation time decreased. |
| 2023 [13] | Zhaou X. et al. | Does CTA derived from CT Perfusion [CTA-DF-CTP] give better image quality and diagnostic accuracy than traditional CTA in AIS? | CTA derived from CTA-DF-CTP had diagnostic accuracy comparable to traditional CTA and CTA-DF-CTP. |
| 2023 [14] | Xiang et al. | Is it feasible to apply computed tomography perfusion [CTP] imaging-guided mechanical thrombectomy in acute ischemic stroke patients with LVO beyond the therapeutic time window? | NIHSS of MT group-CTP guided [at 6 h, 24 h, 7 days, and 30 days] was significantly better [p < 0.05]; however, infarct core volume approximation was too high or too low for this group. |
| 2023 [15] | Du B. et al. | In patients with ICAS [Intracranial Atherosclerotic Stenosis] in the anterior circulation, is AI based on CBF [Cerebral Blood Flow] or sCoV [Spatial Coefficient of Variation] better for predicting vascular cognitive impairment? | Cognitive impairment seems better predicted by AI analysis of sCoV than CBF. |
| 2023 [16] | Farsani S. et al. | Can AG-DCNN [Attention Gated Deep Convoluted Neural Network] predict infarct volume and size? | AG-DCNN, using only admission DWI, predicted infarct volumes at 3–7 days after stroke onset with accuracy like models using DWI and PWI. |
| 2022 [17] | Kossen T. et al. | How can modern machine learning methods such as generative adversarial networks [GANs] automate perfusion map generation from [DSC-MR] Dynamic Susceptibility Contrasted MR in AIS on an expert level without manual validation? | DSC-MR using machine learning can speed up patient stratification by perfusion mapping in AIS. |
| 2022 [18] | Long Le et al. | Can an advanced deep learning-based method accurately and rapidly assess collateral perfusion in AIS by automatically generating a multiphase collateral imaging map from dynamic susceptibility contrast-enhanced MR perfusion [DSC-MRP] images? | DSC-Enhanced MR Perfusion improved accuracy and sped the assessment of the collateral perfusion. |
| 2021 [19] | Neeves G et al. | Can a machine-learning [ML] algorithm grade digital subtraction angiograms [DSA] by the mTICI scale? | ML of complete cerebral DSA predicted mTICI scores following EVT of MCA occlusions. |
| 2020 [20] | Grosser M. et al. | In AIS patients, how do predictions of machine learning models based on local [regional] tissue susceptibility to ischemia compare with those of machine learning models based on global brain imaging? | Compared to single global machine learning models, locally trained machine learning models can lead to better prediction of lesion outcomes in AIS patients. |
| 2019 [21] | Satish R. et al. | Can Convolutional Neural Network analysis of Multisequence MRI in AIS predict the ischemic core and penumbra? | CNN analysis experimentally confirmed local changes. |
| 2019 [22] | Reid M. et al. | For detecting early severe ischemia, how does NCCT compare with multiphase computed tomography angiography [mCTA] regional leptomeningeal score [mCTA-rLMC] and an mCTA venous [mCTA-venous] perfusion lesion? | An assessment blinded to clinical information in patients undergoing endovascular therapy [EVT] showed that mCTA-venous more accurately detected early ischemia and predicted clinical outcomes than NCCT and the mCTA-rLMC score. |
| 2018 [23] | Nielsen A. et al. | In AIS, can Deep Learning improve Tissue Outcome and Treatment Effect predictions? | Deep Learning improves predictions of final neurological outcome and lesion volume. |
| 2018 [24] | Chung-Ho. et al. | Can imaging features and advanced machine learning use the TSS [Time Since Stroke] classification to characterize the Acute Ischemic Stroke Onset Time? | Demonstrates the potential benefit of using advanced machine learning methods in TSS classification. |
| 2017 [25] | Yu. Y. et al. | Can machine learning models trained on perfusion-weighted magnetic resonance imaging [PWI] and diffusion-weighted MRI scans predict HT [hemorrhagic transformation] occurrence and location in AIS? | HT prediction was a machine-learning problem. Specifically, the model learned to extract imaging markers of HT directly from source PWI images. |
| 2016 [26] | Tian X. et al. | Can clinically acceptable PCT [dynamic cerebral Perfusion Computed Tomography] images be created from low-dose CT images restored with a coupled dictionary learning [CDL] method in chronic and AIS patients? | CDL increased kinetic enhanced details and improved diagnostic hemodynamic parameter maps |
| 2013 [27] | Fang R. et al. | Will the robust sparse perfusion deconvolution method [SPD] accurately estimate cerebral blood flow [CBF] in CTP performed at a low radiation dose? | SPD was superior to existing methods for CBF and helped differentiate normal and ischemic brain tissue. |
| 2010 [28] | Mendrick A. et al. | Can the diagnostic yield of CTP in cerebrovascular diseases be expanded by combining arterial and venous segmentation and vessel-enhanced volume? | This artery and vein segmentation method was accurate for arteries and veins with normal perfusion. Combining the artery and vein segmentation with the vessel-enhanced volume produced an arteriogram and venogram, extending the diagnostic yield of CTP scans and making a CTA scan unnecessary. |
| 2007 [29]. | Meyer-Baese A. et al. | Do five unsupervised clustering techniques help analyze dynamic susceptibility contrast MRI time series? | Clustering is a valuable tool for analyzing and visualizing brain regional perfusion properties. |