Shi-Jiang Li

Title: Innovations and Contributions of Inventor Shi-Jiang Li

Introduction

Shi-Jiang Li is an accomplished inventor based in Brookfield, WI (US). She has made significant contributions to the field of neuroscience and biomarker research, holding a total of 5 patents. Her work focuses on developing systems and methods that enhance the understanding and prediction of brain disorders.

Latest Patents

One of her latest patents is titled "Systems and methods for quantitatively characterizing Alzheimer's disease risk events based on multimodal biomarker data." This patent describes systems and methods for computing a quantitative index that characterizes Alzheimer's disease (AD) risk events based on a temporally ordered sequence of biomarker events. The systems implement a modified event-based probabilistic (EBP) model to calculate the risk index from biomarker data.

Another notable patent is "Systems and methods for detection and prediction of brain disorders based on neural network interaction." This invention obtains functional connectivity data in the whole brain to detect and predict brain disorders. The whole brain data is regionalized and manipulated to derive functional connectivity data sets that can show measured functional connectivity changes. By identifying and quantifying the functional connectivity differences between healthy and diseased subjects, a classification for individual subjects can be made.

Career Highlights

Shi-Jiang Li has worked with reputable organizations such as the Medical College of Wisconsin, Inc. and Mcw Research Foundation, Inc. Her innovative approaches have contributed to advancements in understanding brain health and disorders.

Collaborations

Some of her notable coworkers include Piero Antuono and James Stewart Hyde. Their collaborative efforts have furthered research in the field of neuroscience.

Conclusion

Shi-Jiang Li's contributions to the field of neuroscience through her patents and collaborations highlight her role as a leading inventor. Her work continues to pave the way for advancements in understanding and predicting brain disorders.