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− | + | <h2>Access to safe and nutritious food is key to good health and development. Although food regulations already exist throughout most jurisdictions, there is still a great need to reduce the prevalence of foodborne diseases (FBD). An estimated 600 million people fall ill from FBDs every year, with about 420 000 dying from them (20). Such statistics reveal a great need for better FBD prevention and detection mechanisms. This is especially true for small-scale businesses and customers, which need quick, easy to use, reliable and affordable FBD detection devices.</h2> | |
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− | + | <h2>Devices that can detect specific nucleic acid sequences can be tailored to detect a specific DNA sequence associated with a particular FBD. Unfortunately, most of the devices remain in the prototype stage and are not available to the average consumer or are very costly to use. Even worse, of the available devices, most of them fail to meet all the necessary criteria for widespread implementation in the prevention of FBDs. Taking the increasing need of rapid tests in low-resource settings, WHO has summarized the ideal features of such tests under the acronym ASSURED (Affordable, Sensitive, Specific, User-friendly, Rapid, Robust, Equipment-free and Delivered to those who need it) (21). An example of a device failing to meet the ASSURED criteria is the recently published “mobile platform for multiplexed detection and differentiation of disease-specific nucleic acid sequences” prototype, which is capable of performing ten simultaneous DNA amplification through Loop-mediated Isothermal Amplification (LAMP) to detect target DNA sequences (22). This device is then paired with a smartphone for data interpretation, and the results are displayed and reported to an online database (22). However, the prototype suffers several drawbacks in its implementation. Although it can provide results relatively quickly (~30 min), it requires sample preparation by centrifugation and heating, which are not readily available and hard to perform in the field. These manual steps significantly reduce the ease of use and portability. Furthermore, the cost of the components for the instrument amounts to approximately 550 USD, which consumers may not be willing or able to pay (22). Our project seeks to address these shortcomings. | |
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− | + | <h5><u>References:</u></h5> | |
− | + | <h2>1. Havelaar AH, et al.(2015) World Health Organization Global Estimates and Regional Comparisons of the Burden of Foodborne Disease in 2010. PLOS Medicine 12(12):e1001923. | |
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− | + | <h2>2. A guide to aid the selection of diagnostic tests (2017) World Health Organization. Available at: http://www.who.int/bulletin/volumes/95/9/16-187468/en/. | |
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− | + | <h2>3. Chen W, et al.(2017) Mobile Platform for Multiplexed Detection and Differentiation of Disease-Specific Nucleic Acid Sequences, Using Microfluidic Loop-Mediated Isothermal Amplification and Smartphone Detection. Analytical Chemistry 89(21):11219-11226. | |
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Revision as of 20:06, 12 October 2018
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