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KimiaNet – A Trained Network for Histopathology Image Representation – Kimia Lab
PreOp Surgery Patient Education *** - YouTube
PreOp Surgery Patient Education *** - YouTube
http://bit.ly/PreOpFacebook or http://bit.ly/PreOpTwitter or https://preop.com - Patient Education - 617-244-7591The PreOp Surgery Centers, patient education...
·youtube.com·
PreOp Surgery Patient Education *** - YouTube
ECG-Based Deep Learning and Clinical Risk Factors to Predict Atrial Fibrillation | Circulation
ECG-Based Deep Learning and Clinical Risk Factors to Predict Atrial Fibrillation | Circulation
Background: Artificial intelligence (AI)–enabled analysis of 12-lead ECGs may facilitate efficient estimation of incident atrial fibrillation (AF) risk. However, it remains unclear whether AI provide
·ahajournals.org·
ECG-Based Deep Learning and Clinical Risk Factors to Predict Atrial Fibrillation | Circulation
Home - Pacenet
CancerNet: a unified deep learning network for pan-cancer diagnostics | BMC Bioinformatics | Full Text
CancerNet: a unified deep learning network for pan-cancer diagnostics | BMC Bioinformatics | Full Text
Background Despite remarkable advances in cancer research, cancer remains one of the leading causes of death worldwide. Early detection of cancer and localization of the tissue of its origin are key to effective treatment. Here, we leverage technological advances in machine learning or artificial intelligence to design a novel framework for cancer diagnostics. Our proposed framework detects cancers and their tissues of origin using a unified model of cancers encompassing 33 cancers represented in The Cancer Genome Atlas (TCGA). Our model exploits the learned features of different cancers reflected in the respective dysregulated epigenomes, which arise early in carcinogenesis and differ remarkably between different cancer types or subtypes, thus holding a great promise in early cancer detection. Results Our comprehensive assessment of the proposed model on the 33 different tissues of origin demonstrates its ability to detect and classify cancers to a high accuracy (> 99% overall F-measure). Furthermore, our model distinguishes cancers from pre-cancerous lesions to metastatic tumors and discriminates between hypomethylation changes due to age related epigenetic drift and true cancer. Conclusions Beyond detection of primary cancers, our proposed computational model also robustly detects tissues of origin of secondary cancers, including metastatic cancers, second primary cancers, and cancers of unknown primaries. Our assessment revealed the ability of this model to characterize pre-cancer samples, a significant step forward in early cancer detection. Deployed broadly this model can deliver accurate diagnosis for a greatly expanded target patient population.
·bmcbioinformatics.biomedcentral.com·
CancerNet: a unified deep learning network for pan-cancer diagnostics | BMC Bioinformatics | Full Text
Development and validation of a machine learning method to predict intraoperative red blood cell transfusions in cardiothoracic surgery | Scientific Reports
Development and validation of a machine learning method to predict intraoperative red blood cell transfusions in cardiothoracic surgery | Scientific Reports
Scientific Reports - Development and validation of a machine learning method to predict intraoperative red blood cell transfusions in cardiothoracic surgery
·nature.com·
Development and validation of a machine learning method to predict intraoperative red blood cell transfusions in cardiothoracic surgery | Scientific Reports
KecNet: A Light Neural Network for Arrhythmia Classification Based on Knowledge Reinforcement
Knee Replacement Surgery: All You Need To Know 🏥🔧 #PreOp #SurgeryTips | PreOp® Patient Education - YouTube
Knee Replacement Surgery: All You Need To Know 🏥🔧 #PreOp #SurgeryTips | PreOp® Patient Education - YouTube
https://preop.com/knee-replacement-surgery/Knee Replacement SurgeryKnee replacement surgery, also known as knee arthroplasty, is a procedure that involves re...
·youtube.com·
Knee Replacement Surgery: All You Need To Know 🏥🔧 #PreOp #SurgeryTips | PreOp® Patient Education - YouTube
Prediction of Cardiovascular Parameters With Supervised Machine Learning From Singapore “I” Vessel Assessment and OCT-Angiography: A Pilot Study | TVST | ARVO Journals
PreOp® Centers of Excellence Surgery Patient education - YouTube
PreOp® Centers of Excellence Surgery Patient education - YouTube
PreOp® Centers of Excellence Surgery Patient educationhttps://preop.com - http://Store.PreOp.comThese certified medical animations, certified medical scripts...
·youtube.com·
PreOp® Centers of Excellence Surgery Patient education - YouTube
CardioNet: a manually curated database for artificial intelligence-based research on cardiovascular diseases | BMC Medical Informatics and Decision Making | Full Text
CardioNet: a manually curated database for artificial intelligence-based research on cardiovascular diseases | BMC Medical Informatics and Decision Making | Full Text
Background Cardiovascular diseases (CVDs) are difficult to diagnose early and have risk factors that are easy to overlook. Early prediction and personalization of treatment through the use of artificial intelligence (AI) may help clinicians and patients manage CVDs more effectively. However, to apply AI approaches to CVDs data, it is necessary to establish and curate a specialized database based on electronic health records (EHRs) and include pre-processed unstructured data. Methods To build a suitable database (CardioNet) for CVDs that can utilize AI technology, contributing to the overall care of patients with CVDs. First, we collected the anonymized records of 748,474 patients who had visited the Asan Medical Center (AMC) or Ulsan University Hospital (UUH) because of CVDs. Second, we set clinically plausible criteria to remove errors and duplication. Third, we integrated unstructured data such as readings of medical examinations with structured data sourced from EHRs to create the CardioNet. We subsequently performed natural language processing to structuralize the significant variables associated with CVDs because most results of the principal CVD-related medical examinations are free-text readings. Additionally, to ensure interoperability for convergent multi-center research, we standardized the data using several codes that correspond to the common data model. Finally, we created the descriptive table (i.e., dictionary of the CardioNet) to simplify access and utilization of data for clinicians and engineers and continuously validated the data to ensure reliability. Results CardioNet is a comprehensive database that can serve as a training set for AI models and assist in all aspects of clinical management of CVDs. It comprises information extracted from EHRs and results of readings of CVD-related digital tests. It consists of 27 tables, a code-master table, and a descriptive table. Conclusions CardioNet database specialized in CVDs was established, with continuing data collection. We are actively supporting multi-center research, which may require further data processing, depending on the subject of the study. CardioNet will serve as the fundamental database for future CVD-related research projects.
·bmcmedinformdecismak.biomedcentral.com·
CardioNet: a manually curated database for artificial intelligence-based research on cardiovascular diseases | BMC Medical Informatics and Decision Making | Full Text
CardioNet: a manually curated database for artificial intelligence-based research on cardiovascular diseases | BMC Medical Informatics and Decision Making | Full Text
CardioNet: a manually curated database for artificial intelligence-based research on cardiovascular diseases | BMC Medical Informatics and Decision Making | Full Text
Background Cardiovascular diseases (CVDs) are difficult to diagnose early and have risk factors that are easy to overlook. Early prediction and personalization of treatment through the use of artificial intelligence (AI) may help clinicians and patients manage CVDs more effectively. However, to apply AI approaches to CVDs data, it is necessary to establish and curate a specialized database based on electronic health records (EHRs) and include pre-processed unstructured data. Methods To build a suitable database (CardioNet) for CVDs that can utilize AI technology, contributing to the overall care of patients with CVDs. First, we collected the anonymized records of 748,474 patients who had visited the Asan Medical Center (AMC) or Ulsan University Hospital (UUH) because of CVDs. Second, we set clinically plausible criteria to remove errors and duplication. Third, we integrated unstructured data such as readings of medical examinations with structured data sourced from EHRs to create the CardioNet. We subsequently performed natural language processing to structuralize the significant variables associated with CVDs because most results of the principal CVD-related medical examinations are free-text readings. Additionally, to ensure interoperability for convergent multi-center research, we standardized the data using several codes that correspond to the common data model. Finally, we created the descriptive table (i.e., dictionary of the CardioNet) to simplify access and utilization of data for clinicians and engineers and continuously validated the data to ensure reliability. Results CardioNet is a comprehensive database that can serve as a training set for AI models and assist in all aspects of clinical management of CVDs. It comprises information extracted from EHRs and results of readings of CVD-related digital tests. It consists of 27 tables, a code-master table, and a descriptive table. Conclusions CardioNet database specialized in CVDs was established, with continuing data collection. We are actively supporting multi-center research, which may require further data processing, depending on the subject of the study. CardioNet will serve as the fundamental database for future CVD-related research projects.
·bmcmedinformdecismak.biomedcentral.com·
CardioNet: a manually curated database for artificial intelligence-based research on cardiovascular diseases | BMC Medical Informatics and Decision Making | Full Text
A Comparative Study of Machine Learning Models with TabNet Classifier for Heart Disease Prediction - YouTube
Diagnostics | Free Full-Text | Jointly Optimized Deep Neural Networks to Synthesize Monoenergetic Images from Single-Energy CT Angiography for Improving Classification of Pulmonary Embolism
Diagnostics | Free Full-Text | Jointly Optimized Deep Neural Networks to Synthesize Monoenergetic Images from Single-Energy CT Angiography for Improving Classification of Pulmonary Embolism
Detector-based spectral CT offers the possibility of obtaining spectral information from which discrete acquisitions at different energy levels can be derived, yielding so-called virtual monoenergetic images (VMI). In this study, we aimed to develop a jointly optimized deep-learning framework based on dual-energy CT pulmonary angiography (DE-CTPA) data to generate synthetic monoenergetic images (SMI) for improving automatic pulmonary embolism (PE) detection in single-energy CTPA scans. For this purpose, we used two datasets: our institutional DE-CTPA dataset D1, comprising polyenergetic arterial series and the corresponding VMI at low-energy levels (40 keV) with 7892 image pairs, and a 10% subset of the 2020 RSNA Pulmonary Embolism CT Dataset D2, which consisted of 161,253 polyenergetic images with dichotomous slice-wise annotations (PE/no PE). We trained a fully convolutional encoder-decoder on D1 to generate SMI from single-energy CTPA scans of D2, which were then fed into a ResNet50 network for training of the downstream PE classification task. The quantitative results on the reconstruction ability of our framework revealed high-quality visual SMI predictions with reconstruction results of 0.984 ± 0.002 (structural similarity) and 41.706 ± 0.547 dB (peak signal-to-noise ratio). PE classification resulted in an AUC of 0.84 for our model, which achieved improved performance compared to other naïve approaches with AUCs up to 0.81. Our study stresses the role of using joint optimization strategies for deep-learning algorithms to improve automatic PE detection. The proposed pipeline may prove to be beneficial for computer-aided detection systems and could help rescue CTPA studies with suboptimal opacification of the pulmonary arteries from single-energy CT scanners.
·mdpi.com·
Diagnostics | Free Full-Text | Jointly Optimized Deep Neural Networks to Synthesize Monoenergetic Images from Single-Energy CT Angiography for Improving Classification of Pulmonary Embolism
Diagnostics | Free Full-Text | Jointly Optimized Deep Neural Networks to Synthesize Monoenergetic Images from Single-Energy CT Angiography for Improving Classification of Pulmonary Embolism
Diagnostics | Free Full-Text | Jointly Optimized Deep Neural Networks to Synthesize Monoenergetic Images from Single-Energy CT Angiography for Improving Classification of Pulmonary Embolism
Detector-based spectral CT offers the possibility of obtaining spectral information from which discrete acquisitions at different energy levels can be derived, yielding so-called virtual monoenergetic images (VMI). In this study, we aimed to develop a jointly optimized deep-learning framework based on dual-energy CT pulmonary angiography (DE-CTPA) data to generate synthetic monoenergetic images (SMI) for improving automatic pulmonary embolism (PE) detection in single-energy CTPA scans. For this purpose, we used two datasets: our institutional DE-CTPA dataset D1, comprising polyenergetic arterial series and the corresponding VMI at low-energy levels (40 keV) with 7892 image pairs, and a 10% subset of the 2020 RSNA Pulmonary Embolism CT Dataset D2, which consisted of 161,253 polyenergetic images with dichotomous slice-wise annotations (PE/no PE). We trained a fully convolutional encoder-decoder on D1 to generate SMI from single-energy CTPA scans of D2, which were then fed into a ResNet50 network for training of the downstream PE classification task. The quantitative results on the reconstruction ability of our framework revealed high-quality visual SMI predictions with reconstruction results of 0.984 ± 0.002 (structural similarity) and 41.706 ± 0.547 dB (peak signal-to-noise ratio). PE classification resulted in an AUC of 0.84 for our model, which achieved improved performance compared to other naïve approaches with AUCs up to 0.81. Our study stresses the role of using joint optimization strategies for deep-learning algorithms to improve automatic PE detection. The proposed pipeline may prove to be beneficial for computer-aided detection systems and could help rescue CTPA studies with suboptimal opacification of the pulmonary arteries from single-energy CT scanners.
·mdpi.com·
Diagnostics | Free Full-Text | Jointly Optimized Deep Neural Networks to Synthesize Monoenergetic Images from Single-Energy CT Angiography for Improving Classification of Pulmonary Embolism
Pre-Op Videos • Northwest ENT and Allergy Center
Accuracy of computed tomography-based three-dimensional preoperative planning for total wrist arthroplasty - Tomoki Matsuo, Takuji Iwamoto, Taku Suzuki, 2023
Accuracy of computed tomography-based three-dimensional preoperative planning for total wrist arthroplasty - Tomoki Matsuo, Takuji Iwamoto, Taku Suzuki, 2023
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·journals.sagepub.com·
Accuracy of computed tomography-based three-dimensional preoperative planning for total wrist arthroplasty - Tomoki Matsuo, Takuji Iwamoto, Taku Suzuki, 2023
Comparison of the components of RCRI: CAIS vs original (4): The... | Download Table
Comparison of the components of RCRI: CAIS vs original (4): The... | Download Table
Download Table | Comparison of the components of RCRI: CAIS vs original (4): The occurrence of major cardiac complications (MCCs) postoperatively  from publication: The Revised Cardiac Risk Index in the new millennium: A single-centre prospective cohort re-evaluation of the original variables in 9,519 consecutive elective surgical patients | Cardiac complications following non-cardiac surgery are major causes of morbidity and mortality. The Revised Cardiac Risk Index (RCRI) has become a standard for predicting post-surgical cardiac complications. This study re-examined the original six risk factors to confirm... | Cohort, Auditing and Analytical Ultracentrifugation (AUC) | ResearchGate, the professional network for scientists.
·researchgate.net·
Comparison of the components of RCRI: CAIS vs original (4): The... | Download Table
A foundational vision transformer improves diagnostic performance for electrocardiograms | npj Digital Medicine
A foundational vision transformer improves diagnostic performance for electrocardiograms | npj Digital Medicine
npj Digital Medicine - A foundational vision transformer improves diagnostic performance for electrocardiograms
·nature.com·
A foundational vision transformer improves diagnostic performance for electrocardiograms | npj Digital Medicine
Cardiac Arrhythmia Recognition Using Transfer Learning with a Pre-trained DenseNet | IEEE Conference Publication | IEEE Xplore
Prediction of mortality after surgery with the help of AI (The Lancet Digital Health) - E-med.co.il | Israel's medical news channel
Prediction of mortality after surgery with the help of AI (The Lancet Digital Health) - E-med.co.il | Israel's medical news channel
מחקר חדש שפורסם ב-The Lancet Digital Health הראה שאלגוריתם למידה עמוקה יכול לזהות מטופלים בסיכון גבוה למות לאחר ניתוח או פרוצדורות, טוב יותר מאשר מחשבון סיכונים קונבנציונלי
·www-e--med-co-il.translate.goog·
Prediction of mortality after surgery with the help of AI (The Lancet Digital Health) - E-med.co.il | Israel's medical news channel
Researchers Show That a Machine Learning Model Can Improve Mortality Risk Prediction for Cardiac Surgery Patients | Mount Sinai - New York