11월 25일(목) 대학원 세미나 / Prof. Kanyi Pu(School of Chemical and Biomedical Engineering; School of Physics and Mathematical Science; Lee Kong Chian School of Medicine, Nanyang Technological University, Singapore)

by 관리자 posted Nov 25, 2021
?

단축키

Prev이전 문서

Next다음 문서

ESC닫기

크게 작게 위로 아래로 댓글로 가기 인쇄
Extra Form
초청강사 Prof. Kanyi Pu
소속 School of Chemical and Biomedical Engineering; School of Physics and Mathematical Science; Lee Kong Chian School of Medicine, Nanyang Technological University, Singapore
일시 2021년 11월 25일(목) 오후 5:00
장소 ZOOM

Pushing Molecular Optical Imaging Probes Towards Clinical Translation

 

Molecular optical imaging plays a crucial role in biology and medicine. However, the strong tissue autofluorescence and shallow tissue penetration of optical imaging not only compromise its sensitivity and specificity but also limit its clinical translation. In this talk, I will introduce our approaches (afterglow imaging and artificial urinary biomarkers) to tackle the challenges to advance the clinical translation of molecular optical probes. First, I will introduce molecular afterglow probes with long-lasting luminescence after removal of light excitation for ultrasensitive in vivo imaging. Molecular afterglow probes have the signal to background ratio more than two orders of magnitude higher than NIR fluorescence, allowing for sensitive detection of tiny peritoneal metastatic tumors and monitoring therapeutic outcome. Second, I will discuss how to design renal-clearable optical probes as artificial urinary biomarkers for early diagnosis of acute kidney injury (AKI) and prognosis of cancer immunotherapy. Molecular renal probes (MRPs) are developed to specifically activate their NIR/chemiluminescence signals towards the biomarkers of AKI or immune cells, followed by rapid renal clearance for urine tests. MRPs thus can act as artificial urinary biomarkers to bypass the in vivo imaging challenges, permitting optical urinalysis that outperforms typical clinical/preclinical assays. These studies provide the basis for an entirely new class of molecular optical probes with ultrahigh sensitivity and high translational potential for disease diagnosis and prognosis.