A possible pathogenetic factor of sickle-cell disease based on fluorescent analysis via an optofluidic resonator

Hailang Dai; Cheng Yin; Xiaona Ye; Bei Jiang; Maowu Ran; Zhuangqi Cao; Xianfeng Chen

doi:10.1038/s41598-017-03634-8

Scientific Reports (Jun 2017)

A possible pathogenetic factor of sickle-cell disease based on fluorescent analysis via an optofluidic resonator

Hailang Dai,
Cheng Yin,
Xiaona Ye,
Bei Jiang,
Maowu Ran,
Zhuangqi Cao,
Xianfeng Chen

Affiliations

Hailang Dai: The State Key Laboratory on Fiber Optic Local Area Communication Networks and Advanced Optical Communication Systems, Department of Physics and Astronomy, Shanghai JiaoTong University
Cheng Yin: The State Key Laboratory on Fiber Optic Local Area Communication Networks and Advanced Optical Communication Systems, Department of Physics and Astronomy, Shanghai JiaoTong University
Xiaona Ye: The State Key Laboratory on Fiber Optic Local Area Communication Networks and Advanced Optical Communication Systems, Department of Physics and Astronomy, Shanghai JiaoTong University
Bei Jiang: The State Key Laboratory on Fiber Optic Local Area Communication Networks and Advanced Optical Communication Systems, Department of Physics and Astronomy, Shanghai JiaoTong University
Maowu Ran: Department of Physics and Electronic Science, Tongren University
Zhuangqi Cao: The State Key Laboratory on Fiber Optic Local Area Communication Networks and Advanced Optical Communication Systems, Department of Physics and Astronomy, Shanghai JiaoTong University
Xianfeng Chen: The State Key Laboratory on Fiber Optic Local Area Communication Networks and Advanced Optical Communication Systems, Department of Physics and Astronomy, Shanghai JiaoTong University

DOI: https://doi.org/10.1038/s41598-017-03634-8
Journal volume & issue: Vol. 7, no. 1
pp. 1 – 6

Abstract

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Abstract Waveguide based optofluidic resonator features high precision and high sensitivity in real-time fluorescent analysis. We present a novel optofluidic resonator following the hollow-core metal-cladding waveguide structure, which is then used to record the real-time binding process of Fe2+ and Fe3+ with protoporphyrin IX (PpIX) in PBS solution, respectively. The central fluorescent wavelength of compound with Fe2+ is in good accordance with that of the normal hemoglobin, whilst the peaks of the Fe3+ compound match the hemoglobin specimen from sickle-cell disease (SCD) patients. Similar statement holds when we monitor the real-time oxidation processes of these products by injecting oxygen into the optofluidic chip. These observations lead to the speculation that the SCD is caused by replacing the Fe2+ in hemoglobin with Fe3+, which may be insightful in the discovery of new clinical routes to cure this disease.

Published in Scientific Reports

ISSN: 2045-2322 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Medicine; Science
Website: https://www.nature.com/srep/

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