Rapid diagnosis of COVID-19 using disposal paper capacitive sensor.

Accurate and rapid detection and isolation become indispensable to restrict the spread of COVID-19. Since the start of COVID-19 pandemic in December 2019, many indisposal diagnostic tools are being developed incessantly. Out of all presently used tools, the gold standard rRT- PCR tool having very high sensitivity and specificity is a time consuming complicated molecular technique having requirements of special expensive equipment. Here, the main focus of this work is to develop rapid disposal paper capacitance sensor having simple and easy detection. We discovered a strong interaction between limonin and Spike-glycoprotein of SARS-COV-2 in comparison to its interaction with other similar viruses such as HCOV-OC43, HCOV-NL63, HCOV-HKU1, Influenza B and A viruses. The antibody free capacitive sensor having comb electrode structure was fabricated on whatman paper with drop coating of limonin (extracted using green method from pomelo seeds) and calibrated with known swab samples. The Blind test with unknown swab samples shows high sensitivity of 91.5% and high specificity of 88.37%. Requiring low sample volume and detection time and using biodegradable materials in the sensor fabrication assure the potential application as a point of care disposal diagnostic tool.

In Silico Screening of Prospective MHC Class I and II Restricted T-Cell Based Epitopes of the Spike Protein of SARS-CoV-2 for Designing of a Peptide Vaccine for COVID-19

Multiple vaccines were developed and administered to immunize people worldwide against SARS-CoV-2 infection. However, changes in platelet count following the course of vaccination have been reported by many studies, suggesting vaccine-induced thrombocytopenia. In this context, designing an effective targeted subunit vaccine with high specificity and efficiency for people with low platelet counts has become a challenge for researchers. Using the in silico-based approaches and methods, the present study explored the antigenic epitopes of the spike protein of SARS-CoV-2 involved in initial binding of the virus with the angiotensin converting enzyme-2 receptor (ACE-2) on the respiratory epithelial cells. The top ten major histocompatibility complex-I (MHC-I) and MHC-II restricted epitopes were found to have 95.26% and 99.99% HLA-class-I population coverage, respectively. Among the top ten promiscuous MHC-I restricted epitopes, 'FTISVTTEI' had the highest global HLA population coverage of 53.24%, with an antigenic score of 0.85 and a docking score of -162.4 Kcal/mol. The epitope 'KLNDLCFTNV' had the best antigenic score of 2.69 and an HLA population coverage of 43.4% globally. The study predicted and documented the most suitable epitopes with the widest global HLA coverage for synthesis of an efficient peptide-based vaccine against the deadly COVID-19.

SARS-CoV-2 and Influenza Virus Co-Infection Cases Identified through ILI/SARI Sentinel Surveillance: A Pan-India Report.

SARS-CoV-2/influenza virus co-infection studies have focused on hospitalized patients who usually had grave sequelae. Here, we report SARS-CoV-2/influenza virus co-infection cases from both community and hospital settings reported through integrated ILI/SARI (Influenza Like Illness/Severe Acute Respiratory Infection) sentinel surveillance established by the Indian Council of Medical Research. We describe the disease progression and outcomes in these cases. Out of 13,467 samples tested from 4 July 2021-31 January 2022, only 5 (0.04%) were of SARS-CoV-2/influenza virus co-infection from 3 different sites in distinct geographic regions. Of these, three patients with extremes of age required hospital admission, but none required ICU admission or mechanical ventilation. No mortality was reported. The other two co-infection cases from community settings were managed at home. This is the first report on SARS-CoV-2/Influenza virus co-infection from community as well as hospital settings in India and shows that influenza viruses are circulating in the community even during COVID-19. The results emphasize the need for continuous surveillance for multiple respiratory pathogens for effective public health management of ILI/SARI cases in line with the WHO (World Health Organization) recommendations.

An Epidemiological Analysis of SARS-CoV-2 Genomic Sequences from Different Regions of India.

The number of Severe Acute Respiratory Syndrome Coronavirus-2 (SARS-CoV-2) cases is increasing in India. This study looks upon the geographic distribution of the virus clades and variants circulating in different parts of India between January and August 2020. The NPS/OPS from representative positive cases from different states and union territories in India were collected every month through the VRDLs in the country and analyzed using next-generation sequencing. Epidemiological analysis of the 689 SARS-CoV-2 clinical samples revealed GH and GR to be the predominant clades circulating in different states in India. The northern part of India largely reported the 'GH' clade, whereas the southern part reported the 'GR', with a few exceptions. These sequences also revealed the presence of single independent mutations-E484Q and N440K-from Maharashtra (first observed in March 2020) and Southern Indian States (first observed in May 2020), respectively. Furthermore, this study indicates that the SARS-CoV-2 variant (VOC, VUI, variant of high consequence and double mutant) was not observed during the early phase of virus transmission (January-August). This increased number of variations observed within a short timeframe across the globe suggests virus evolution, which can be a step towards enhanced host adaptation.

Haemophilus influenzae and SARS-CoV-2: Is there a role for investigation?

During the current pandemic of COVID-19, the authors observed that during screening test for SARS-CoV-2 targeting the E-gene by qRT-PCR, few nasopharyngeal/oropharyngeal samples showed amplification signals at late cycle threshold (CT-value) > 35 despite being negative for other confirmatory target genes. Thirty such samples (taken as cases) showing detectable CT of > 35 cycle in E-gene which were negative for other target genes of SARS-CoV-2 and 30 samples with undetectable fluorescence in E-gene were taken as controls for investigation. An in-vitro diagnostic approved commercial qRT-PCR multiplex kit detecting 33 respiratory pathogens which can also detect Haemophilus influenzae was used for screening the samples. It was observed that out of the 30 samples showing detectable CT> 35 in E-gene, 11 samples were positive for Haemophilus influenzae whereas in the controls only three samples were positive for H. influenzae (p-value: 0.03) which was statistically significant. Further, the probes and primers were screened against H. influenzae for matches in the genome. It was observed that all primers and probes for the E-gene of SARS-CoV-2 had over 13 bp long sequences matching 100% with multiple sites across the H. influenzae genome. This qRT-PCR primer & probes are being used extensively across India, and laboratories using them should be aware of the cross-reactivity of primers & probes with the H. influenzae genome. Further, the authors observed that 95.9% (5415/5642) of COVID-19 positive cases detected in their laboratory were asymptomatic at the time of collection of samples. This warrants further investigations.

TSP-based PCR for rapid identification of L and S type strains of SARS-CoV-2.

BACKGROUND: In the initial few months of the COVID-19 pandemic, two distinct strains of severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) were identified (L and S strain) based on a tightly linked SNP between two widely separated nucleotides at location 8782 (ORF1ab T8517C) and position 28,144 (ORF8: C251T, codon S84L). MATERIALS AND METHODS: A Type Specific Primer based one step RT-PCR (TSP-PCR) test to distinguish the L and S type strains of SARS-CoV-2 without the need for viral genome sequencing, was developed. The study also analyzed 18,221 whole genome sequences (WGS) available up to April 2020 to know the prevalence of L and S type of strains. Phylogenetic and recombination analysis of SARS-CoV-2 genome with nearest animal and human coronaviruses were analyzed using MEGA X and SimPlot version 3.5.1 software respectively. RESULTS: The rapid TSP-PCR distinguished the L and S type strains of SARS-CoV-2 by amplifying a specific 326 bp and 256 bp fragment of the L and S type strain respectively. The test was used to analyzed 120 random SARS-CoV-2 positive samples from Assam, India among which 118 were found to be of L-type strains only. On analysis of 18,221 WGS, it was found that L type was the predominant strain with an overall prevalence ∼90%. However, pockets of high prevalence of S-type strains (>35%) were still in circulation in Washington region in April 2020. The study did not detect any significant recombination events between closely related coronavirus and SARS-CoV-2. CONCLUSION: TSP-based PCR for identification of circulating strains of SARS-CoV-2, will add in rapid identification of strains of COVID-19 pandemic to understand the spread of the virus, its transmissibility and adaptation into human population. Though, the S-type strains have decreased drastically across the globe since April 2020, the role of TSP-PCR in geographical niches where such strains are still prevalent may help in rapidly distinguishing the strains and study its evolution.

Pooled testing for COVID-19 diagnosis by real-time RT-PCR: A multi-site comparative evaluation of 5- & 10-sample pooling.

BACKGROUND & OBJECTIVES: Public health and diagnostic laboratories are facing huge sample loads for COVID-19 diagnosis by real-time reverse transcription-polymerase chain reaction (RT-PCR). High sensitivity of optimized real-time RT-PCR assays makes pooled testing a potentially efficient strategy for resource utilization when positivity rates for particular regions or groups of individuals are low. We report here a comparative analysis of pooled testing for 5- and 10-sample pools by real-time RT-PCR across 10 COVID-19 testing laboratories in India. METHODS: Ten virus research and diagnostic laboratories (VRDLs) testing for COVID-19 by real-time RT-PCR participated in this evaluation. At each laboratory, 100 nasopharyngeal swab samples including 10 positive samples were used to create 5- and 10-sample pools with one positive sample in each pool. RNA extraction and real-time RT-PCR for SARS-CoV-2-specific E gene target were performed for individual positive samples as well as pooled samples. Concordance between individual sample testing and testing in the 5- or 10-sample pools was calculated, and the variation across sites and by sample cycle threshold (Ct) values was analyzed. RESULTS: A total of 110 each of 5- and 10-sample pools were evaluated. Concordance between the 5-sample pool and individual sample testing was 100 per cent in the Ct value ≤30 cycles and 95.5 per cent for Ctvalues ≤33 cycles. Overall concordance between the 5-sample pooled and individual sample testing was 88 per cent while that between 10-sample pool and individual sample testing was 66 per cent. Although the concordance rates for both the 5- and 10-sample pooled testing varied across laboratories, yet for samples with Ct values ≤33 cycles, the concordance was ≥90 per cent across all laboratories for the 5-sample pools. INTERPRETATION & CONCLUSIONS: Results from this multi-site assessment suggest that pooling five samples for SARS-CoV-2 detection by real-time RT-PCR may be an acceptable strategy without much loss of sensitivity even for low viral loads, while with 10-sample pools, there may be considerably higher numbers of false negatives. However, testing laboratories should perform validations with the specific RNA extraction and RT-PCR kits in use at their centres before initiating pooled testing.