Your search keyword '"Yuan, Qunchen"' showing total 4 results

1. Long-Term Flexible Neural Interface for Synchronous Recording of Cross-Regional Sensory Processing along the Olfactory Pathway.

Author

Duan Y, Wang S, Yuan Q, Shi Y, Jiang N, Jiang D, Song J, Wang P, and Zhuang L

Subjects

Animals, Humans, Olfactory Bulb physiology, Odorants, Perception, Mammals, Olfactory Pathways physiology, Smell physiology

Abstract

Humans perceive the world through five senses, of which olfaction is the oldest evolutionary sense that enables the detection of chemicals in the external environment. Recent progress in bioinspired electronics has boosted the development of artificial sensory systems. Here, a biohybrid olfactory system is proposed by integrating living mammals with implantable flexible neural electrodes, to employ the outstanding properties of mammalian olfactory system. In olfactory perception, the peripheral organ-olfactory epithelium (OE) projects axons into the olfactory relay station-olfactory bulb (OB). The olfactory information encoded in the neural activity is recorded from both OE and OB simultaneously using flexible neural electrodes. Results reveal that spontaneous slow oscillations (<12 Hz) in both OE and OB closely follow respiration. This respiration-locked rhythm modulates the amplitude of fast oscillations (>20 Hz), which are associated with odor perception. Further, by extracting the characteristics of odor-evoked oscillatory signals, responses of different odors are identified and classified with 80% accuracy. This study demonstrates for the first time that the flexible electrode enables chronic stable electrophysiological recordings of the peripheral and central olfactory system in vivo. Overall, the method provides a novel neural interface for olfactory biosensing and cognitive processing., (© 2023 Wiley-VCH GmbH.)

Published

2023

2. A wearable system for olfactory electrophysiological recording and animal motion control.

Author

Zhang B, Zhuang L, Qin Z, Wei X, Yuan Q, Qin C, and Wang P

Subjects

Action Potentials physiology, Animals, Conditioning, Operant, Electric Stimulation, Electroencephalography, Male, Microelectrodes, Olfactory Pathways cytology, Rats, Rats, Sprague-Dawley, Sensory Receptor Cells physiology, Brain-Computer Interfaces, Evoked Potentials, Somatosensory physiology, Motion, Olfactory Pathways physiology, Smell physiology, Wearable Electronic Devices

Abstract

Background: Bran-computer interface (BCI) is an important technique used in brain science. However, the large size of equipment and wires severely limit its practical applications., New Methods: This study presents a wearable system with bidirectional brain-computer interface based on Wi-Fi technology, which can be used for olfactory electrophysiological recording and animal motion control., Results: On the "brain-to-computer" side, the results show that the wireless system can record high-quality olfactory electrophysiological signals for over a month. By analyzing the recorded data, we find that the same mitral/tufted (M/T) cells can be activated by many odorants and different M/T cells can be activated by a single odorant. Further, we find neurons in dorsal lateral OB are highly sensitive to isoamyl acetate. On the "computer-to-brain" side, the results show that we can efficiently control rats' motions by applying electrical stimulations to electrodes implanted in specific brain regions., Comparison With Existing Methods: Most existing wireless BCI systems are designed for either recording or stimulating while our system is a bidirectional BCI featured with both functions. Taking advantage of our years of experience in olfactory decoding, we developed the first wireless system for olfactory electrophysiological recording and animal motion control. It provides high-quality recording and efficient motion control for a long time., Conclusions: The system provides possibility of practical BCI applications, such as in vivo bioelectronic nose and "rat-robot"., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

3. An In Vitro HL-1 Cardiomyocyte-Based Olfactory Biosensor for Olfr558-Inhibited Efficiency Detection.

Author

Yuan, Qunchen, Qin, Chunlian, Zhang, Saisai, Wu, Jianguo, Qiu, Yong, Chen, Changming, Huang, Liquan, Wang, Ping, Jiang, Deming, and Zhuang, Liujing

Subjects

SHORT-chain fatty acids, BODY odor, BIOSENSORS, OLFACTORY receptors, CONDUCTING polymers, SMELL, OLFACTORY perception, LIGAND binding (Biochemistry)

Abstract

Some short-chain fatty acids with a pungent or unpleasant odor are important components of human body odor. These malodors severely threaten human health. The antagonists of malodors would help to improve odor perception by affecting the interaction between odors and their receptors. However, the traditional odor detection and analysis methods, such as MOS, electrochemical, conductive polymer gas sensors, or chromatography-mass spectrometry are not suitable for screening the antagonists since they are unable to detect the ligand efficacy after odor-receptor binding. In this study, RT-PCR results showed that HL-1 cardiomyocytes endogenously express the olfactory receptor 558 (Olfr558) which can be activated by several malodorous short-chain fatty acids. Therefore, an in vitro HL-1 cardiomyocyte-based olfactory biosensor (HCBO-biosensor) was developed by combining cardiomyocytes and microelectrode array (MEA) chips for screening the potential antagonists of the Olfr558. Firstly, it showed that the biosensor specifically responded to ligands of Olfr558 through odor stimulation experiments. Then, an odor response model of HL-1 cardiomyocytes was constructed by a ligand of Olfr558 (isovaleric acid). The response feature of the in vitro HCBO-biosensor to individual odors and mixtures with a potential antagonist (citral or β-damascenone) were extracted and compared. Finally, the Olfr558-inhibited efficiency was indirectly detected by comparing the half-maximal inhibitory concentration of isovaleric acid. The results showed that β-damascenone greatly inhibited Olfr558 while citral showed no significant inhibitory effect. In conclusion, we built a novel screening method for the antagonists of Olfr558 based on HL-1 cardiomyocytes and the MEA chip which will assist odor-related companies to develop novel antagonists of Olfr558. [ABSTRACT FROM AUTHOR]

Published

2022

4. A biohybrid nose for evaluation of odor masking in the peripheral olfactory system.

Author

Zhuang, Liujing, Wei, Xinwei, Jiang, Nan, Yuan, Qunchen, Qin, Chunlian, Jiang, Deming, Liu, Mengxue, Zhang, Yanning, and Wang, Ping

Subjects

*OLFACTORY perception, *ODORS, *SMELL, *NOSE, *BINARY mixtures, *MAGNITUDE (Mathematics), *EPITHELIUM, *SENSORY perception

Abstract

Olfaction is a synthetic sense in which odor mixtures elicit emergent perceptions at the expense of perceiving the individual components. The most common result of mixing two odors is masking one component by another. However, there is lack of analytical techniques for measuring the sense of smell, which is mediated by cross-odorant interactions. Here, we propose a biohybrid nose for objective and quantitative evaluation of malodor masking efficiency of perfumed products. This biohybrid nose is constructed by integrating mammalian olfactory epithelium with microelectrode array chip to read out the olfactory information as electrical signal from multiple tissue sites. The intrinsic odor response of olfactory epithelium is found to be represented by widespread spatiotemporal oscillatory activity. The masking efficiency of fragrance is quantified by calculating the relative difference between the malodor and the binary mixture (malodor + fragrance) response patterns. Results indicate that masking efficiency of fragrance is concentration-dependent, whereas completely masking may occurs when fragrance is employed at a concentration 2–3 orders of magnitude higher than malodor. This study demonstrates for the first time that capitalizing on the biological sense of smell to create biohybrid system provides an effective technique to resolve more complex biosensing-related issues such as odor interactions in mixtures. • A biohybrid nose is proposed for evaluation of odor masking that close to biological sense of smell. • The biohybrid nose is constructed by integrating mammalian olfactory epithelium with microelectrode array chip. • Olfactory information is read out as widespread spatiotemporal oscillatory activity across epithelium. • Masking efficiency is quantified by calculating the relative difference between the malodor and binary mixture response. • The method further allows comprehensive investigations of cross-odorant interactions at the peripheral sensory level. [ABSTRACT FROM AUTHOR]

Published

2021