Microfluidic culture platform for studying neuronal response to mild to very mild axonal stretch injury

Yap, Yiing C.; Dickson, Tracey C.; King, Anna E.; Breadmore, Michael C.; Guijt, Rosanne M.

doi:10.1063/1.4891098

Cited by 30 publications

(32 citation statements)

References 46 publications

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“…In a similar approach, Yap et al () designed a microfluidic device (Table ) to induce strain injury to dissociated rat cortical axons. Unlike Dolle's strain injury model (Dolle et al, ; Dolle et al, ) which applied injury to axons over 2 mm, this device applies a localized stretch injury to axons over 90 μm.…”

Section: Physical (Stretch/strain) Injurymentioning

confidence: 99%

“…Pneumatic deflection of a cavity beneath the axonal microchannels Yap et al (2014) Study the role of axon diameter and mitochondrial membrane potential changes in response to axonal strain injuries (organotypic hippocampal brain slices of rat).…”

Section: Aim Of Study (Neuronal Cells Used) Injury Approach Referencesmentioning

confidence: 99%

“…In a similar approach, Yap et al (2014) designed a microfluidic device (Table 2) to induce strain injury to dissociated rat cortical axons.…”

Section: Physical (Stretch/strain) Injurymentioning

confidence: 99%

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Microfluidic platforms for the study of neuronal injury in vitro

Shrirao

Kung

Omelchenko

et al. 2018

Biotech & Bioengineering

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Traumatic brain injury (TBI) affects 5.3 million people in the United States, and there are 12,500 new cases of spinal cord injury (SCI) every year. There is yet a significant need for in vitro models of TBI and SCI in order to understand the biological mechanisms underlying central nervous system (CNS) injury and to identify and test therapeutics to aid in recovery from neuronal injuries. While TBI or SCI studies have been aided with traditional in vivo and in vitro models, the innate limitations in specificity of injury, isolation of neuronal regions, and reproducibility of these models can decrease their usefulness in examining the neurobiology of injury. Microfluidic devices provide several advantages over traditional methods by allowing researchers to (1) examine the effect of injury on specific neural components, (2) fluidically isolate neuronal regions to examine specific effects on subcellular components, and (3) reproducibly create a variety of injuries to model TBI and SCI. These microfluidic devices are adaptable for modeling a wide range of injuries, and in this review, we will examine different methodologies and models recently utilized to examine neuronal injury. Specifically, we will examine vacuum-assisted axotomy, physical injury, chemical injury, and laser-based axotomy. Finally, we will discuss the benefits and downsides to each type of injury model and discuss how researchers can use these parameters to pick a particular microfluidic device to model CNS injury.

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Section: Physical (Stretch/strain) Injurymentioning

confidence: 99%

Section: Aim Of Study (Neuronal Cells Used) Injury Approach Referencesmentioning

confidence: 99%

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Microfluidic platforms for the study of neuronal injury in vitro

Shrirao

Kung

Omelchenko

et al. 2018

Biotech & Bioengineering

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“…Among these technologies, pneumatic valve based microfluidic systems demonstrate the highest potential for flexible and scalable integrated platforms. Microfluidic automation of exceedingly complex fluid handling protocols has been achieved utilising pneumatic valve based systems for numerous applications 18 , including lab-on-a-chip platforms [19][20][21] , and biosensors 22, 23 . Of particular interest, this technology has been applied to fluidic automation of photonic biosensors [24][25][26] .…”

Section: Paper Introductionmentioning

confidence: 99%

An automated optofluidic biosensor platform combining interferometric sensors and injection moulded microfluidics

et al. 2017

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A primary limitation preventing practical implementation of photonic biosensors within point-of-care platforms is their integration with fluidic automation subsystems. For most diagnostic applications, photonic biosensors require complex fluid handling protocols; this is especially prominent in the case of competitive immunoassays, commonly used for detection of low-concentration, low-molecular weight biomarkers. For this reason, complex automated microfluidic systems are needed to realise the full point-of-care potential of photonic biosensors. To fulfil this requirement, we propose an on-chip valve-based microfluidic automation module, capable of automating such complex fluid handling. This module is realised through application of a PDMS injection moulding fabrication technique, recently described in our previous work, which enables practical fabrication of normally closed pneumatically actuated elastomeric valves. In this work, these valves are configured to achieve multiplexed reagent addressing for an on-chip diaphragm pump, providing the sample and reagent processing capabilities required for automation of cyclic competitive immunoassays. Application of this technique simplifies fabrication and introduces the potential for mass production, bringing point-of-care integration of complex automated microfluidics into the realm of practicality. This module is integrated with a highly sensitive, label-free bimodal waveguide photonic biosensor, and is demonstrated in the context of a proof-of-concept biosensing assay, detecting the low-molecular weight antibiotic tetracycline.

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“…, biomolecular treatment to isolated axons) or physical ( e.g. , direct damage to isolated axons with integrated microfluidic components such as pneumatically actuated valves) axotomy can be investigated [20–25]. Although, successful in performing localized axonal damage and demonstrating their potential use for axon regeneration studies, they were low in throughput and had limitations in practically screening potential drug candidates.…”

Section: Introductionmentioning

confidence: 99%

A Microchip for High-Throughput Axon Growth Drug Screening

et al. 2016

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It has been recently known that not only the presence of inhibitory molecules associated with myelin but also the reduced growth capability of the axons limit mature central nervous system (CNS) axonal regeneration after injury. Conventional axon growth studies are typically conducted using multi-well cell culture plates that are very difficult to use for investigating localized effects of drugs and limited to low throughput. Unfortunately, there is currently no other in vitro tool that allows investigating localized axonal responses to biomolecules in high-throughput for screening potential drugs that might promote axonal growth. We have developed a compartmentalized neuron culture platform enabling localized biomolecular treatments in parallel to axons that are physically and fluidically isolated from their neuronal somata. The 24 axon compartments in the developed platform are designed to perform four sets of six different localized biomolecular treatments simultaneously on a single device. In addition, the novel microfluidic configuration allows culture medium of 24 axon compartments to be replenished altogether by a single aspiration process, making high-throughput drug screening a reality.

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Microfluidic culture platform for studying neuronal response to mild to very mild axonal stretch injury

Cited by 30 publications

References 46 publications

Microfluidic platforms for the study of neuronal injury in vitro

Microfluidic platforms for the study of neuronal injury in vitro

An automated optofluidic biosensor platform combining interferometric sensors and injection moulded microfluidics

A Microchip for High-Throughput Axon Growth Drug Screening

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