key: cord-0757075-92ltdtmj authors: Chandra, Pranjal title: Miniaturized Label-free Smartphone Assisted Electrochemical Sensing Approach for Personalized COVID-19 Diagnosis date: 2020-07-24 journal: Sensors international DOI: 10.1016/j.sintl.2020.100019 sha: 0d69276a4fd391164971c3e00189f84ed726f1f7 doc_id: 757075 cord_uid: 92ltdtmj Abstract The COVID-19, coronavirus disease is an infectious disease caused by a novel virus called Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2). By March 2020 the novel coronavirus known to cause a pandemic has infected nearly about 119 thousand people and killed more than 4,300 around 114 countries. Apart from the current controversial opinions about the origin, spreading, and sociological impact, it is much more imperative to put a halt to this current situation. Understanding, testing, and early to rapid diagnosis may be now the only key that can contain COVID-19 by “flattening the curve”. Biosensing is the platform that allows rapid, highly sensitive, and selective detection of analytes which in turn can serve the purpose for fast and precise detection of COVID-19. In this article, based on recently reported miniaturized sensing strategies, we hereby propose a promising personalized smartphone assisted electrochemical sensing platform for diagnosis of COVID-19. The indications of COVID-19 disease are highly non-specific. Similar to the common flu, the preliminary symptoms of coronavirus disease are related to respiratory illness including cough, fever, difficulty in breathing (WHO 2020) . Coronavirus disease can spread primarily through direct or indirect contact from an infected person. To date the disease has been reported to spread over 210 countries and territories, affecting over 11.3 million people (5 July, Worldometer 2020; Shetti et al., 2020) . From the very beginning of the outbreak scientists all over the world are working extensively to understand the etiology of COVID-19. Though apart from the conventional molecular technique (Zhu et al. 2020 , serological immunoassays (Li et al. 2020b; Vashist 2020) and chest CT imaging (Dai et al. 2020) , there are no relevant methods of detection commercially available yet (Mahapatra and Chandra, 2020) . Moreover, these techniques have also testified with various faults and limitations in their respective applications (Bai et al. 2020; Jia et al. 2020; Li et al. 2020a ). The rapid lateral flowbased immunosensing assays detect the immunoglobulin M (IgM) and immunoglobulin G (IgG) produced in patients in response to SARS-CoV-2. However, the performance of this assays still demands critical evaluation for the clinical diagnosis of COVID-19. Thus, it is a crucial need indeed to develop a system that can sense and diagnose the SARS-CoV-2 infection as well by targeting it's specified-potent biomarkers in a label-free format. Electrochemical biosensors with a nano-engineered surface in recent years have become a critical area of research interest Kumar et al. 2020; Chandra P, 2016) . Scientists from all over the world are focusing on the exceptional atomic and molecular properties of engineered nanomaterials and their composites for better biological / diagnostic applications (Chandra P et al. 2017; Kumar et al. 2018; Prasad et al. 2016) . Engineered nanomaterials integrated with functional nanoscale material can provide a new aspect towards the development of POC based modern immunosensors and other diagnostics platforms Mahato et al. 2018; Mahato et al. 2016) . Recently, along with the development of nanostructured materials, a range of nanomaterials with diverse sizes and shapes have been utilized as the substrates for biorecognition element (BREs) immobilization (Andreescu et al., 2008; Meryam Sardar, 2015; Siqueira et al., 2010) . It has been interpreted that the biomolecules immobilized on the nanostructured materials have various advantages over the bulk solid substrates. However, to proficiently immobilize biomolecules on nanostructured, material surfaces required labored work to modify / functionalize the substrate surface. Additionally, for some of the nanostructured materials, it is difficult to fully characterize their surfaces using conventional surface analytical tools. This eventually limits the detailed understanding of the immobilization mechanism. Hence, new nanostructured materials design and application towards BREs interfacing should be explored for various diseases including development of labelfree platforms or COVID-19 diagnosis. In the last few years, our laboratory has developed various POC-immunosensors based on electrochemically engineered nanocomposites modified sensor surface (Akhtar et al. 2018; Mahato et al. 2020) . In a recent work, we have demonstrated a miniaturized label-free electrochemical impedance spectroscopy-based detection of biomarkers using metallic nanoparticles (NPs), electrochemically engineered nano-dendroids, and graphene oxide (GO) nanocomposites. These materials were sequentially deposited over the screen-printed carbon electrode (SPCE) and antibodies against the specific biomarker were immobilized using a bioconjugation process ). GO, a wonder material with exceptional electrical property can be used for the development of high performance COVID-19 biosensing system utilizing such analytical platform. Besides, the incredibly large specific surface area (two accessible sides), the abundant oxygen-containing surface functionalities, such as epoxide, hydroxyl, and carboxylic groups, and the high water solubility afford GO sheets a great promise for many more sensing applications (Chandra and Prakash., 2020; Lee et al., 2016; Yu et al., 2017) . It is possible to improvise these sensing systems by integrating the detection platform with newly discovered markers which are specific to COVID-19. Recently various molecular biology techniques have used to identify several genes thought to be specific for SARS-CoV-2 detection. In a recent study, aRNA-dependent RNA polymerase (RdRp)/helicase (H) genes of SARS-CoV-2, an important marker that does not show any cross-reactivity with other human coronaviruses or respiratory viruses has been utilized for diagnostic purpose (Chan et al. 2020 ). Thus, if anti-RdRp helicase is successfully immobilized on our recently designed highly conducting surface ) it may pave a new way to detect the infection inevitably, due to its robustness and high analytical performance (Figure 1) . In another study, our group has developed a nonenzymatic electrochemical nanoprobe for the rapid determination of chemical analyte present in the blood samples . A gold sputtered nano-hierarchical 3D dendritic structure is used to attain high surface area, high conductivity, and different degrees of surface roughness possessing a greater catalytic potential. Multi-walled carbon nanotube (MWCNT) integrated dendrite modified electrode is another promising sensing surface with very high conductivity and elcrocatalysis . Conducting monomers and polymers can also be used by integrating with the dendritic system for the development of label-free sensors utilizing their high electron transfer capacity (Naveen et al., 2016; Valera et al., 2019) . Surfaces with such high conductivity can be functionalized using suitable chemistry and additional nanomaterials to accommodate BREs and used for labelfree sensing of specific proten targets of COVID-19. These cost-effective nanoprobes can be useful as a platform to capture and analyze the various reported biomarkers i.e. nucleocapsid protein (N), spike protein (S), envelope protein (E), and membrane protein (M) or the open reading frame 1b (ORF1b) of the viral RNA expressed in COVID-19 disease (Chu et al. 2020 ). Mahato et al. 2020) 5 The advantage of both these sensors are in their robustness and label-free mode of operation, which is one of the most critical parameters when applied in clinical diagnostics in hospitals and / on in personalized disease monitoring. Another important feature of such sensors are data accusation in terms of electronic signals, that can be linked with the smartphone-based analytical systems Chandra, 2016) Recently, smartphone-based sensing systems have gained wider attention as it offers a semiautomated user interface which can be used by common people without extensive training or technical knowledge . With a tailored hardware and sensing software inbuilt, sensing systems can be developed within a smartphones to miniaturise the system to be carried out to any locations and can be operated by any semitrained personnel. Smartphone-driven monitoring and diagnostic devices might provide a cost-effective alternative for expensive stand-alone technologies. It may be possible to develop a COVID-19 biosensor by integrating a complete disposable sensing module as discussed before to a smartphone-based application platform for personalized diagnosis (Figure 2 ). Sensing suface can be optimized according to the marker molecules and can further be improvised for POC diagnosis in real clinical samples. Such a miniaturized system can provide a fast and affordable sensing not only to detect, but also to monitor the outbreak in a large scale. A smartphone-based "cloud" directory can also provide real-time surveillance by the means of geo-tagging. Geo-tagging constitutes the process of defining, creating, and provisioning a set of geolocation information to a computing device securely (Yeluri et al., 2014) . Thus, geolocation can enable identification of a cloud server's approximate location by adding contagion/outbreak information to the server's root of trust. Moreover, In the case of novel outbreaks or pandemics, location and time are indispensable for appropriate clinical administration, infection deterrence, and control. The information can be accessed using secure protocols to assert the integrity of the platform and confirm the location of the host (Web Reference 1). Once this system is employed within a community, tracking of the outbreak will be enabled and updated in real-time to comprehend epidemiological studies through simplifying the restraining strategies. As the race to develop a vaccine for COVID-19 is the primary concern now, it is essential to understand the epidemiological characteristics to stand against this outbreak. Moreover, it is suggested to identify the potent intermediate hosts those who can carry the disease, to prevent as well as to eradicate it from the near future. These steps require a compelling approach for the detection of the disease. Hence, POC based label-free sensing techniques integrated with smartphones can not only track the disease spreading around the globe, but also form a library of data and facts required for future preparation to endure such pandemic. If alarms are raised early in infected areas, physicians can rapidly decide on the appropriate treatment for each new patient and public health organizations can manage the spread of the diseaese. It is anticipated that powerful integrative electrochemical label-free technologies can be escalated to develop a personalized analytical system to combat COVID-19 and other infectious diseases. 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