The project will develop an innovative, real-time clinical decision support (DSS) platform. The platform will utilize Big Data analytic methods, novel algorithms, and software tools to integrate and analyze disparate sources of continuous and non-continuous patient data.
The DSS platform will be able to understand and predict potential complications and recovery trends for patients following cardiac surgery, other open vascular operations in the chest and abdomen, and other trauma surgeries involving the cardiovascular system.
This project has two aims. First, the construction of AngioAid, a fully automated computer-based platform to assist with the interpretation of coronary angiogram videos. Secondly, the creation of a curated dataset of coronary angiogram videos, made publicly available via Amazon Web Services, that will spur development of new algorithms to advance the field of angiogram interpretation.
The proposed system will accurately predict or detect the onset of severe cardiac events (e.g., hemodynamic instability) prior to complications experienced by the driver in order to ensure driver safety.
The project aim is to establish a prognostic predictive model using non-convex kernel models to distinguish between benign and malignant tumor patients. This model will provide adjuvant information to stratify osteosarcoma patients and subsequently to guide clinical decision.
We have developed wound segmentation and deep neural network models that can accurately predict infection and wound healing. The image segmentation methods provide an accurate “hands-free” measurement of wound surface area. Our objective here is to refine our algorithms and test the suitability of image analysis as a biomarker for healing or infection. We will do this by performing image analyses of DFU treated by total contact cast (TCC) and by comparing the image features to those not treated by TCC. Our working hypothesis is there will be unique features from image analysis that can accurately predict infection or healing beyond surface area changes over time, known clinical predictors (Brownrigg, Hinchliffe et al. 2016) or candidate biomarkers.
The project is a collaboration between CareProgress and the University of Michigan. The project aims to:
- Develop computational algorithms to analyze the clinical and self-reported data collected by CareProgress to assess the recovery and effectiveness of treatment and health resource consumption.
- Improving the accuracy and reliability of the predictions on the recovery and health resource consumption by using the physiological data collected by wearable sensors, including through the creation of patient risk sco
Architecture design, test and validate image/video processing and machine learning method to detect and understand human’s affective state by analyzing face images captured by an in-vehicle camera. Specifically, it includes:
- Real-time face detection/localization and automatic annotation.
- Dynamic face localization through a sequence of images recorded over time. Spatial-temporal feature extraction to understanding facial expression and motion
- Multi-model fusion to reason and understand human’s behavior and state, especially for the driver drowsiness application.
In this project, the project team at U-M hereafter, in collaboration with DENSO, will create computational methods, in particular deep learning algorithms, to understand and predict human behavior and affective state (distracted/focused, drowsy/active, etc.). The team will implement the above-mentioned algorithms in MATLAB and Python framework.
This project continues the development of the Piezo Ring. The ring portably measures the vascular tone and reactivity of small blood vessels in the finger, which gauge a patient’s physiology and hypotension. Using computational methods, the ring predicts hypotension ranging from 9-108 minutes in advance. This is useful for hemodialysis patients who greatly benefit from constant blood pressure monitoring, as well as in combat and critical care situations.
The Piezo Ring is easily portable, provides continuous hemodynamic monitoring, and predicts hypotension up to 108 minutes in advance. The Piezo Ring also provides more relevant data to physicians, making it a better indicator of patient physiology than current devices such as pulse oximeters.
Among other image modalities used for TBI assessment, a number of recent studies reported that hand-held optic nerve ultrasound (ONUS) may help identify elevated intracranial pressure (ICP). In the largest study of ICP prediction using ONUS to date, we found that optic nerve sheath diameter can accurately predict ICP > 25 mmHg in a mixed population of patients in a neurosurgical ICU. Our preliminary work has demonstrated the feasibility of fully automated algorithms to measure optic nerve sheath diameter. In this project we will further develop these algorithms to predict ICP from measuring the optic nerve sheath diameter.
Trauma is the leading cause of death among Americans under 44. The mortality rate for patients with pelvic injuries is increased by the risk of further complications, especially severe hemorrhage. However, even a single trauma patient generates large volumes of information, including vital signs, injury severity scores, demographic details, lab reports, and in particular, complex medical images such as CT scans and X-rays—all of which impact diagnosis and treatment, as well as costs. A computer-assisted decision support system (DSS) capable of rapidly analyzing large volumes of patient information to generate accurate treatment recommendations and outcome predictions has the potential to improve both patient care/survival and resource utilization. The proposed Decision Support System (DSS) technology is envisioned to significantly improve pelvic/abdominal trauma decision-making using facilitated and prompt analysis of complex and heterogeneous patient medical data.
The current project will extend the algorithms of our DDS technology to:
- Integrate our algorithms and methods for analysis of data for pelvic/abdominal injuries with those of TBI such that the resulting DDS software can be used in polytrauma cases.
- Further develop the planned software implementation of our technology as a user-friendly software tool to be used in the clinical setting.
This project aims to create novel computational methodologies that synthesize and integrate longitudinal electronic health data streams for real-time and continuous health status monitoring and early detection of disease. We will utilize these technologies to address the problem of monitoring patients with lung disease to detect the presence of the acute respiratory distress syndrome (ARDS) at early stages. The project combines the capabilities of two emerging fields of machine learning, privileged learning and learning from uncertain data, both highly relevant to healthcare applications. While the current project focuses on improving diagnosis of ARDS, the proposed learning methods will generalize across healthcare settings, allowing for better characterization of patient health status in both in-hospital and in-home settings via portable electronic monitoring devices.
Hypertension is the number one cause of racial disparities in mortality in the U.S. Understanding the mechanisms by which race is linked with the cardiovascular system is key for potentially reducing race disparities in hypertension and hypertension related mortality. The present study is guided by existing theories of racial health disparities, which suggest that racial health disparities are due to variations in long-term exposure to stress that are moderated by social relations and age.
This project has three aims:
- Test links between long-term stress exposure and short-term stress reactivity among Eurpoean American (EA) and AA adults.
- Examine age differences in long-term stress exposure and short-term reactivity by race.
- Determine how long-term social relationships moderate individual differences in stress exposure and reactivity.
While sleep disruption and disorders are common in individuals with spinal cord injury (SCI), little is known about how these disturbances impact symptoms (fatigue and pain), cognition (subjective and objective), and functioning (physical activity and social participation) in these individuals. In this study, we will continuously assess objective autonomic nervous system and physical activity, and will collect self-reported symptoms at five intervals throughout each day for 175 individuals with SCI. In addition, participants will complete an internet-based daily diary that consists of brief questionnaires on symptoms and functional outcomes. We will also conduct a standardized neuropsychological exam at the end of the study that evaluates cognitive domains known to be impacted by poor sleep. The use of these multiple methods will increase measurement reliability and elucidate the role that sleep quality plays in day to day functioning.