Microfluidic-Based Approaches for Foodborne Pathogen Detection

Zhao, Xihong; Li, Mei; Liu, Yao

doi:10.3390/microorganisms7100381

Cited by 67 publications

(26 citation statements)

References 118 publications

(114 reference statements)

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“…The surface modification and antibody immobilization of the microspheres were carried out utilizing the coupling method of sulfhydryl maleimide group [ 31 , 32 ]. 10 mg glass microspheres with the diameter 50 μm were accurately weighed and placed in piranha solution (H 2 SO 4 : H 2 O 2 = 3:1) overnight, washed with distilled PBS for 5 times, dried at 70 °C for 30 min, reacted with 2% APTES acetone solution at room temperature for 30 minutes, and washed with acetone and distilled water for five times.…”

Section: Methodsmentioning

confidence: 99%

Microfluidics for the rapid detection of Staphylococcus aureus using antibody-coated microspheres

et al. 2020

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Staphylococcus aureus is a common foodborne pathogenic microorganism which can cause food poisoning and it is pathogenic to both humans and animals. Therefore, rapid detection of S. aureus infection is of great significance. In this study, a microfluidic platform was introduced to detect S. aureus by fluorescence labeling method and a self-made microfluidic chip, which has immune spheres were used to study the effect of capturing S. aureus . Through this experiment, we found that the platform can be used for microbial culture, and S. aureus antibody coated on the diameter of 50 ~ 90 μm microspheres for detection. On the premise of optimizing the sample flow rate and detection time, the bacterial detection was quantitatively monitored. Results showed that our platform can detect S. aureus at injection rate of 5 μL·min −1 reacted for 4 min and the detection limit of bacteria is 1.5 × 10 1 CFU/μL. However, the detection time of traditional method is 24 hs to 72 hs, and the operation is complex and cumbersome. These findings indicated that the microfluidic chip in this study is portable, sensitive, and accurate, laying a good foundation for further research on the application of rapid bacterial detection platform.

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Section: Methodsmentioning

confidence: 99%

Microfluidics for the rapid detection of Staphylococcus aureus using antibody-coated microspheres

et al. 2020

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“…Nowadays, advanced microfluidics integrates a number of operations into a single chip, such as sample pre-treatment and preparation, DNA extraction, amplification, separation and mixing of the samples, a micromechanical system for fluid manipulation, together with optical and electronic components for signal sensing. The microfluidic technology has been widely used to study cell biology for biomedical applications [ 88 , 89 ], protein studies [ 90 ], pathogen detection [ 91 , 92 ], cell culture [ 93 , 94 ] or tissue engineering [ 95 ]. The dimensions of microfluidic channels and the physical scale of cells correspond to each other.…”

Section: Bioreactors and Scaffoldingmentioning

confidence: 99%

Cultivating Multidisciplinarity: Manufacturing and Sensing Challenges in Cultured Meat Production

Djisalov

Knežić

Podunavac

et al. 2021

Biology

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Meat cultivation via cellular agriculture holds great promise as a method for future food production. In theory, it is an ideal way of meat production, humane to the animals and sustainable for the environment, while keeping the same taste and nutritional values as traditional meat and having additional benefits such as controlled fat content and absence of antibiotics and hormones used in the traditional meat industry. However, in practice, there is still a number of challenges, such as those associated with the upscale of cultured meat (CM). CM food safety monitoring is a necessary factor when envisioning both the regulatory compliance and consumer acceptance. To achieve this, a multidisciplinary approach is necessary. This includes extensive development of the sensitive and specific analytical devices i.e., sensors to enable reliable food safety monitoring throughout the whole future food supply chain. In addition, advanced monitoring options can help in the further optimization of the meat cultivation which may reduce the currently still high costs of production. This review presents an overview of the sensor monitoring options for the most relevant parameters of importance for meat cultivation. Examples of the various types of sensors that can potentially be used in CM production are provided and the options for their integration into bioreactors, as well as suggestions on further improvements and more advanced integration approaches. In favor of the multidisciplinary approach, we also include an overview of the bioreactor types, scaffolding options as well as imaging techniques relevant for CM research. Furthermore, we briefly present the current status of the CM research and related regulation, societal aspects and challenges to its upscaling and commercialization.

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“…Microfluidic systems employing such sensors and their integration with micronanofluidic channels provide a single chip-based platform for investigation in the field of chemistry, biochemistry, engineering physics, biotechnology, and nanotechnology, and life process [24]. These not only simplifies the complexity of biosensing and diagnostic tests, but also minimize the size of analysis equipment, and also reduce the hazard of handling harmful pathogens and chemi-cals [25]. Advances in microsystems have revolutionized the way for sensing and diagnostic measurement reliably and flexibly, which manages practices, precise control, and control of liquids that are geometrically obliged to a small, ordinarily submillimeter scale.…”

Section: Recent Development Of Integrated Microfluidics Biosensorsmentioning

confidence: 99%

Magnetic nanoparticles in microfluidic and sensing: From transport to detection

et al. 2020

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Superparamagnetic nanoparticles are attracting significant attention. Therefore, being explored in microsystems for a wide range of applications. Typical examples include labon-a-chip and microfluidics for synthesis, detection, separation, and transportation of different bioanalytes, such as biomolecules, cells, and viruses to develop portable, sensitive, and cost-effective biosensing systems. Particularly, microfluidic systems incorporated with magnetic nanoparticles and, in combination with magnetoresistive sensors, shift diagnostic and analytical methods to a microscale level. In this context, nanotechnology enables the miniaturization and integration of a variety of analytical functions in a single chip for manipulation, detection, and recognition of bioanalytes reliably and flexibly. In consideration of the above, recent development and benefits are elaborated herein to discuss the role of magnetic nanoparticles inside the microchannels to design highly efficient disposable point-of-care applications from transportation to the detection of bioanalytes.

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Microfluidic-Based Approaches for Foodborne Pathogen Detection

Cited by 67 publications

References 118 publications

Microfluidics for the rapid detection of Staphylococcus aureus using antibody-coated microspheres

Microfluidics for the rapid detection of Staphylococcus aureus using antibody-coated microspheres

Cultivating Multidisciplinarity: Manufacturing and Sensing Challenges in Cultured Meat Production

Magnetic nanoparticles in microfluidic and sensing: From transport to detection

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