Jifu Mao

Title: Innovations in Cardiac Care by Inventor Jifu Mao

Introduction

Jifu Mao, based in Shanghai, China, is a notable inventor who has contributed significantly to the field of biomedical engineering. With a focus on innovative solutions for cardiac health, Mao has developed cutting-edge technologies aimed at improving the quality of life for patients with heart conditions.

Latest Patents

Mao holds a patent for a "Stable Conductive Myocardial Patch with Negative Poisson's Ratio Structure and Preparation Method Thereof." This inventive patch is designed to enhance cardiac function and stability. The preparation method involves creating a myocardial patch substrate with concave polygons through weaving or knitting and applying a conductive coating to its surface. Importantly, the patch is engineered to maintain a relative resistance change of less than 5% at 50% tensile strain, effectively mimicking the mechanical behavior of natural myocardium. This innovative design demonstrates a negative Poisson's ratio effect, allowing for expansion in the perpendicular direction of applied tensile loads.

Career Highlights

Mao's academic and research endeavors are rooted at Donghua University, where he has been instrumental in advancing research in the field of materials science and biomedical applications. His work not only highlights his inventiveness but also his commitment to practical solutions in medical technology.

Collaborations

In his research journey, Jifu Mao collaborates with talented peers, including Yimeng Li and Yaya Gao. Together, they are working on further innovations in biomedical engineering, striving to push the boundaries of existing technologies and create impactful advancements in healthcare.

Conclusion

Jifu Mao stands out in the realm of medical inventions with his innovative myocardial patch. His unique approach to enhancing cardiac support through materials science reflects a promising future in medical technology. As he continues to develop groundbreaking solutions, his contributions are likely to inspire further advancements in the field, ultimately improving patient care and outcomes in cardiology.