Gerald C Hsu
Eclaire MD Foundation, USA
Keynote: Metabolomics (Los Angels)
Introduction: This paper describes the math-physical medicine approach (MPM) of medical research utilizing
mathematics, physics, engineering models and computer science instead of the current biochemical medicine approach
(BCM) that mainly utilizes biology and chemistry.
Methodology of MPM: Initially, the author spent four years of self-studying six chronic diseases and food nutrition to
gain in-depth medical domain knowledge. During 2014, he defined metabolism as a nonlinear, dynamic, and organic
mathematical system having 10 categories with ~500 elements. He then applied topology concept with partial differential
equation and nonlinear algebra to construct a metabolism equation. He further defined and calculated two variables,
metabolism index and general health status unit. During the past 8.5 years, he has collected and processed 1.5 million
data. Since 2015, he developed prediction models, i.e. equations, for both postprandial plasma glucose (PPG) and fasting
plasma glucose (FPG). He identified 19 influential factors for PPG and five factors for FPG. Each factor has a different
contribution margin to the glucose formation. He developed PPG model using optical physics and signal processing.
Furthermore, by using both wave and energy theories, he extended his research into the risk probability of heart attack
or stroke. In this risk assessment, he applied structural mechanics concepts, including elasticity, dynamic plastic, and
fracture mechanics, to simulate artery rupture and applied fluid dynamics concepts to simulate artery blockage. He
further decomposed 12,000 glucose waveforms with 21,000 data and then re-integrated them into three distinctive PPG
waveform types which revealed different personality traits and psychological behaviors of type 2 diabetes patients. For
single time-stamped variables, he used traditional time-series analysis. For interactions between two variables, he used
spatial analysis. Furthermore, he also applied Fourier Transform to conduct frequency domain analyses to discover some
hidden characteristics of glucose waves. He then developed an AI Glucometer tool for patients to predict their weight,
FPG, PPG, and A1C. It uses various computer science tools, including big data analytics, machine learning (self-learning,
correction, and simplification), and artificial intelligence to achieve very high accuracy (95% to 99%).
Results: In 2010, his average glucose was 280 mg/dL and A1C was >10%. Now, his glucose value is 116 mg/dL and A1C is
6.5%. Since his health condition is stable, he no longer suffers from repetitive cardiovascular episodes.
Conclusion: Instead of utilizing traditional biology, chemistry, and statistics the methodology of GH-Method: mathphysical
medicine uses advanced mathematics, physics concept, engineering modeling, and computer science tools (big
data analytics, artificial intelligence), which can be applied to other branches of medical research in order to achieve a
higher precision and deeper insight.
Gerald C Hsu has completed his PhD in Mathematics and majored in Engineering at MIT. He attended different universities over 17 years and studied seven academic disciplines. He has spent 20,000 hours in T2D research. His approach is quantitative medicine based on mathematics, physics, optical and electronics physics, engineering modeling, signal processing, computer science, big data analytics, statistics, machine learning and artificial intelligence. His main focus is on preventive medicine using prediction tools. He believes that the better the prediction, the more control you have.
E-mail: g.hsu@eclaireMD.com
Metabolomics:Open Access received 895 citations as per Google Scholar report
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