An integrated fiber-optic microfluidic device for detection of muscular force generation of microscopic nematodes

Liu, Peng; Mao, Depeng; Martin, Richard J.; Dong, Liang

doi:10.1039/c2lc40459a

Cited by 19 publications

(14 citation statements)

References 58 publications

(68 reference statements)

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“…As a result, it is applied to study the nematode. The nematode has the same locomotion pattern as C. elegans such as Oesophagostomum species parasites of humans [ 29 ]. Furthermore, a basic principle of our method is the same as a strain gauge, therefore it can be used as a sensor to detect the environment in a microfluidic device such as pressure in a micro channel.…”

Section: Discussionmentioning

confidence: 99%

“…For these reasons, research has focused on characterizing the locomotion of C. elegans [ 25 , 26 , 27 ]. The use of microfluidic devices for the study of C. elegans locomotion has successfully investigated its locomotion, and additionally, its force level [ 24 , 28 , 29 ], adaptability [ 30 ], and behavior [ 19 ]. In these works, the use of an imaging system and software to observe the undulatory locomotion of C. elegans limited the size of the observing system, therefore, making it difficult to develop a small and portable biological assay for C. elegans .…”

Section: Introductionmentioning

confidence: 99%

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Microfluidic Device to Measure the Speed of C. elegans Using the Resistance Change of the Flexible Electrode

et al. 2016

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This work presents a novel method to assess the condition of Caenorhabditis elegans (C. elegans) through a resistance measurement of its undulatory locomotion speed inside a micro channel. As the worm moves over the electrode inside the micro channel, the length of the electrode changes, consequently behaving like a strain gauge. In this paper, the electrotaxis was applied for controlling the direction of motion of C. elegans as an external stimulus, resulting in the worm moving towards the cathode of the circuit. To confirm the proposed measurement method, a microfluidic device was developed that employs a sinusoidal channel and a thin polydimethylsiloxane (PDMS) layer with an electrode. The PDMS layer maintains a porous structure to enable the flexibility of the electrode. In this study, 6 measurements were performed to obtain the speed of an early adult stage C. elegans, where the measured average speed was 0.35 (±0.05) mm/s. The results of this work demonstrate the application of our method to measure the speed of C. elegans undulatory locomotion. This novel approach can be applied to make such measurements without an imaging system, and more importantly, allows directly to detect the locomotion of C. elegans using an electrical signal (i.e., the change in resistance).

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Microfluidic Device to Measure the Speed of C. elegans Using the Resistance Change of the Flexible Electrode

et al. 2016

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“…Microfluidics-based biotechnologies have been extensively developed to enable system miniaturization, automation, and parallelization of biochemical processes, 19 as well as highthroughput culture, manipulation, and detection of cells and microorganisms. [20][21][22][23][24][25][26] Several microfluidic devices have been reported for on-chip cultivation, analysis, and transformation of microalgal cells under various growth conditions. [27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42] For example, toxicity screening using marine microalgal cultures in a microfluidic device was reported.…”

Section: 064104-1mentioning

confidence: 99%

Microfluidic chip for automated screening of carbon dioxide conditions for microalgal cell growth

Wang

Chen

et al. 2017

Biomicrofluidics

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This paper reports on a microfluidic device capable of screening carbon dioxide (CO) conditions for microalgal cell growth. The device mainly consists of a microfluidic cell culture (MCC) unit, a gas concentration gradient generator (CGG), and an in-line cell growth optical measurement unit. The MCC unit is structured with multiple aqueous-filled cell culture channels at the top layer, multiple CO flow channels at the bottom layer, and a commercial hydrophobic gas semipermeable membrane sandwiched between the two channel layers. The CGG unit provides different CO concentrations to support photosynthesis of microalgae in the culture channels. The integration of the commercial gas semipermeable membrane into the cell culture device allows rapid mass transport and uniform distribution of CO inside the culture medium without using conventional agitation-assisted convection methods, because the diffusion of CO from the gas flow channels to the culture channels is fast over a small length scale. In addition, automated in-line monitoring of microalgal cell growth is realized via the optical measurement unit that is able to detect changes in the light intensity transmitted through the cell culture in the culture channels. The microfluidic device also allows a simple grayscale analysis method to quantify the cell growth. The utility of the system is validated by growing cells under different low or very-low CO levels below the nominal ambient CO concentration.

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“…Microfluidics technology has been the focus of intense research and development as it promises a multitude of advantages in a number of markets including chemical and biological analysis (Shih et al 2015 ; Liberale et al 2013 ), drug delivery (Majedi et al 2013 ) and medical diagnose (Lee et al 2014 ; Ng Alphonsus et al 2010 ), such as small sizes, high throughput and low cost of microfluidic systems (Paul et al 2006 ). Microfluidic has also revolutionized some aspects of optical area (Tseng et al 2009 ; Liu et al 2012 ). Lim et al ( 2014 ) reported a microfluidic optical fiber devices composed of microfluidic channels which can be used for sensitive refractive index sensing and biosensing applications.…”

Section: Introductionmentioning

confidence: 99%

Controllable liquid colour-changing lenses with microfluidic channels for vision protection, camouflage and optical filtering based on soft lithography fabrication

Zhang

2016

SpringerPlus

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In this work, liquid colour-changing lenses for vision protection, camouflage and optical filtering are developed by circulating colour liquids through microfluidic channels on the lenses manually. Soft lithography technology is applied to fabricate the silicone liquid colour-changing layers with microfluidic channels on the lenses instead of mechanical machining. To increase the hardness and abrasion resistance of the silicone colour-changing layers on the lenses, proper fabrication parameters such as 6:1 (mass ration) mixing proportion and 100 °C curing temperature for 2 h are approved for better soft lithography process of the lenses. Meanwhile, a new surface treatment for the irreversible bonding of silicone colour-changing layer with optical resin (CR39) substrate lens by using 5 % (volume ratio) 3-Aminopropyltriethoxysilane solution is proposed. Vision protection, camouflage and optical filtering functions of the lenses are investigated with different designs of the channels and multi-layer structures. Each application can not only well achieve their functional demands, but also shows the advantages of functional flexibility, rapid prototyping and good controllability compared with traditional ways. Besides optometry, some other designs and applications of the lenses are proposed for potential utility in the future.

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An integrated fiber-optic microfluidic device for detection of muscular force generation of microscopic nematodes

Cited by 19 publications

References 58 publications

Microfluidic Device to Measure the Speed of C. elegans Using the Resistance Change of the Flexible Electrode

Microfluidic Device to Measure the Speed of C. elegans Using the Resistance Change of the Flexible Electrode

Microfluidic chip for automated screening of carbon dioxide conditions for microalgal cell growth

Controllable liquid colour-changing lenses with microfluidic channels for vision protection, camouflage and optical filtering based on soft lithography fabrication

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