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Authors are the souls of any journal, and deserve much respect. To publish a journal manuscripts are needed from authors. Authors have a great responsibility for producing facts of their work in terms of number and results truthfully and an individual honesty is expected from authors in this regards. Both ways its true "No authors-No manuscripts-No journals" and "No journals–No manuscripts–No authors". Reviewing a manuscript is also a very responsible and important task of any peer-reviewed journal and to be taken seriously. It needs knowledge on the subject, sincerity, honesty and determination. Although the process of reviewing a manuscript is a time consuming task butit is expected to give one's best remarks within the time frame of the journal.
Salient features of the JCDR: It is a biomedical, multidisciplinary (including all medical and dental specialities), e-journal, with wide scope and extensive author support. At the same time, a free text of manuscript is available in HTML and PDF format. There is fast growing authorship and readership with JCDR as this can be judged by the number of articles published in it i e; in Feb 2007 of its first issue, it contained 5 articles only, and now in its recent volume published in April 2011, it contained 67 manuscripts. This e-journal is fulfilling the commitments and objectives sincerely, (as stated by Editor-in-chief in his preface to first edition) i e; to encourage physicians through the internet, especially from the developing countries who witness a spectrum of disease and acquire a wealth of knowledge to publish their experiences to benefit the medical community in patients care. I also feel that many of us have work of substance, newer ideas, adequate clinical materials but poor in medical writing and hesitation to submit the work and need help. JCDR provides authors help in this regards.
Timely publication of journal: Publication of manuscripts and bringing out the issue in time is one of the positive aspects of JCDR and is possible with strong support team in terms of peer reviewers, proof reading, language check, computer operators, etc. This is one of the great reasons for authors to submit their work with JCDR. Another best part of JCDR is "Online first Publications" facilities available for the authors. This facility not only provides the prompt publications of the manuscripts but at the same time also early availability of the manuscripts for the readers.
Indexation and online availability: Indexation transforms the journal in some sense from its local ownership to the worldwide professional community and to the public.JCDR is indexed with Embase & EMbiology, Google Scholar, Index Copernicus, Chemical Abstracts Service, Journal seek Database, Indian Science Abstracts, to name few of them. Manuscriptspublished in JCDR are available on major search engines ie; google, yahoo, msn.
In the era of fast growing newer technologies, and in computer and internet friendly environment the manuscripts preparation, submission, review, revision, etc and all can be done and checked with a click from all corer of the world, at any time. Of course there is always a scope for improvement in every field and none is perfect. To progress, one needs to identify the areas of one's weakness and to strengthen them.
It is well said that "happy beginning is half done" and it fits perfectly with JCDR. It has grown considerably and I feel it has already grown up from its infancy to adolescence, achieving the status of standard online e-journal form Indian continent since its inception in Feb 2007. This had been made possible due to the efforts and the hard work put in it. The way the JCDR is improving with every new volume, with good quality original manuscripts, makes it a quality journal for readers. I must thank and congratulate Dr Hemant Jain, Editor-in-Chief JCDR and his team for their sincere efforts, dedication, and determination for making JCDR a fast growing journal.
Every one of us: authors, reviewers, editors, and publisher are responsible for enhancing the stature of the journal. I wish for a great success for JCDR."
Thanking you
With sincere regards
Dr. Rajendra Kumar Ghritlaharey, M.S., M. Ch., FAIS
Associate Professor,
Department of Paediatric Surgery, Gandhi Medical College & Associated
Kamla Nehru & Hamidia Hospitals Bhopal, Madhya Pradesh 462 001 (India)
E-mail: drrajendrak1@rediffmail.com
On May 11,2011
Dr. Shankar P.R.
"On looking back through my Gmail archives after being requested by the journal to write a short editorial about my experiences of publishing with the Journal of Clinical and Diagnostic Research (JCDR), I came across an e-mail from Dr. Hemant Jain, Editor, in March 2007, which introduced the new electronic journal. The main features of the journal which were outlined in the e-mail were extensive author support, cash rewards, the peer review process, and other salient features of the journal.
Over a span of over four years, we (I and my colleagues) have published around 25 articles in the journal. In this editorial, I plan to briefly discuss my experiences of publishing with JCDR and the strengths of the journal and to finally address the areas for improvement.
My experiences of publishing with JCDR: Overall, my experiences of publishing withJCDR have been positive. The best point about the journal is that it responds to queries from the author. This may seem to be simple and not too much to ask for, but unfortunately, many journals in the subcontinent and from many developing countries do not respond or they respond with a long delay to the queries from the authors 1. The reasons could be many, including lack of optimal secretarial and other support. Another problem with many journals is the slowness of the review process. Editorial processing and peer review can take anywhere between a year to two years with some journals. Also, some journals do not keep the contributors informed about the progress of the review process. Due to the long review process, the articles can lose their relevance and topicality. A major benefit with JCDR is the timeliness and promptness of its response. In Dr Jain's e-mail which was sent to me in 2007, before the introduction of the Pre-publishing system, he had stated that he had received my submission and that he would get back to me within seven days and he did!
Most of the manuscripts are published within 3 to 4 months of their submission if they are found to be suitable after the review process. JCDR is published bimonthly and the accepted articles were usually published in the next issue. Recently, due to the increased volume of the submissions, the review process has become slower and it ?? Section can take from 4 to 6 months for the articles to be reviewed. The journal has an extensive author support system and it has recently introduced a paid expedited review process. The journal also mentions the average time for processing the manuscript under different submission systems - regular submission and expedited review.
Strengths of the journal: The journal has an online first facility in which the accepted manuscripts may be published on the website before being included in a regular issue of the journal. This cuts down the time between their acceptance and the publication. The journal is indexed in many databases, though not in PubMed. The editorial board should now take steps to index the journal in PubMed. The journal has a system of notifying readers through e-mail when a new issue is released. Also, the articles are available in both the HTML and the PDF formats. I especially like the new and colorful page format of the journal. Also, the access statistics of the articles are available. The prepublication and the manuscript tracking system are also helpful for the authors.
Areas for improvement: In certain cases, I felt that the peer review process of the manuscripts was not up to international standards and that it should be strengthened. Also, the number of manuscripts in an issue is high and it may be difficult for readers to go through all of them. The journal can consider tightening of the peer review process and increasing the quality standards for the acceptance of the manuscripts. I faced occasional problems with the online manuscript submission (Pre-publishing) system, which have to be addressed.
Overall, the publishing process with JCDR has been smooth, quick and relatively hassle free and I can recommend other authors to consider the journal as an outlet for their work."
Dr. P. Ravi Shankar
KIST Medical College, P.O. Box 14142, Kathmandu, Nepal.
E-mail: ravi.dr.shankar@gmail.com
On April 2011 Anuradha
Dear team JCDR, I would like to thank you for the very professional and polite service provided by everyone at JCDR. While i have been in the field of writing and editing for sometime, this has been my first attempt in publishing a scientific paper.Thank you for hand-holding me through the process.
Dr. Anuradha
E-mail: anuradha2nittur@gmail.com
On Jan 2020
Original article / research
Full Version
Genomic Characterisation and Epidemiology of XBB Recombinant Variant of Severe Acute Respiratory Syndrome Coronavirus 2 in Uttarakhand using Next Generation Sequencing: A Retrospective Cross-sectional Study
Correspondence Address :
Dr. Geetika Rana,
Associate Professor, Department of Microbiology, Government Doon Medical College, Patel Nagar, Dehradun-248001, Uttarakhand, India.
E-mail: drgeetikarana@gmail.com
Introduction: Following the surge of Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) in late 2019, there was an 11-month period of relative evolutionary stability. However, since late 2020, SARS-CoV-2 evolution has been characterised by the emergence of mutation sets impacting virus characteristics like transmissibility and antigenicity, termed “variants of concern.” This shift likely responds to changing immune profiles within the human population. There is mounting evidence suggesting that post-vaccination serum is less effective in neutralising certain SARS-CoV-2 genotypes. XBB is a recombinant variant comprising sublineages BA.2.10.1 and BA.2.75 of the Omicron variant.
Aim: To investigate the genomic characterisation and epidemiology of the XBB recombinant variant of SARS-CoV-2 in Uttarakhand, India.
Materials and Methods: A retrospective cross-sectional study was conducted at the Viral Research Diagnostic Laboratory (VRDL Lab), Government Doon Medical College (GDMC), Dehradun, Uttarakhand, India. A total of 1,162 nasopharyngeal swabs received between September 2022 and February 2023 from various healthcare facilities were included for Next Generation Sequencing (NGS) of coronavirus. NGS was performed and all results were forwarded to the Indian SARS-CoV-2 Genomics Consortium (INSACOG) and the Indian Biological Data Centre (IBDC) for variant determination. Data collection occurred from March to April 2023, with data analysis following from May to June 2023. Statistical analysis was conducted using Microsoft Excel and Omnicalculator.
Results: Among the 1,162 processed samples, 41 (3.53%) were identified as the XBB variant of Omicron. Within the XBB variants, XBB.2 was predominant 22 (53.7%). Maximum XBB samples (38, 92.7%) originated from District Dehradun, Uttarakhand, India.
Conclusion: SARS-CoV-2 has been evolving and advancing with each new variant coming across. As XBB is impacting both previously infected individuals and those vaccinated, there is an imperative to develop new and efficacious vaccines against circulating variants to reduce associated risks of morbidity and mortality.
Coronavirus variants, Coronavirus disease-2019 vaccines, Omicron variants
The Coronavirus Disease 2019 (COVID-19) pandemic, caused by SARS-CoV-2 that was first identified in Wuhan City, Hubei Province, China, in December 2019, is still raging due to the emergence of the Omicron variant and its descendant sublineages (1),(2). The Omicron Variant of Concern (VOC), which first emerged in November 2021, has since emerged to be the most widespread and dominant variant worldwide (3). On January 30, 2020, the first case of COVID-19 was reported in Kerala, India (4). Subsequent lockdowns were announced on March 23, 2020, in Kerala and on March 25, 2020, across the nation (5). Infection rates started to decline after September- October 2020 (6). The daily reported cases peaked in mid-September 2020, exceeding 90,000, before falling to under 15,000 by January 2021 (7). The second wave, commencing in March 2021, was markedly more destructive than the initial wave, leading to shortages of vaccines, hospital beds, oxygen cylinders, and other medical essentials in various regions (8). The third wave hit India in January 2022, lasting until March 2022, with 22,487 cases nationwide as of March 2022 (9),(10). Since the onset of the pandemic, the coronavirus has undergone various mutations globally. Several COVID-19 patients have experienced reinfections due to the persistent nature of the pandemic (11). With Omicron variants, reinfections are anticipated to rise due to diminishing immune responses from earlier Omicron infection and the ongoing evolution of Omicron variants (12). Omicron’s mutation enhances its ability to bind more strongly to Angiotensin-Converting Enzyme 2 (ACE2) host cell receptors compared to other identified variants (13). Additionally, it evades many (though not all) of the virus- blocking or “neutralising” antibodies produced by vaccinated individuals or those exposed to other variants (14).
The original Omicron BA.1 was replaced by the BA.2 sublineage, leading to further sublineage evolution like BA.2.12.1, BA.2.75, BA.2.75.2, BA.4, and BA.5, with BA.5 holding the majority in several nations (15). XBB was initially detected in mid-August 2022 in India and swiftly became predominant in India, Singapore, and other Asian regions (1). XBB is a recombinant of the BA.2.10.1 and BA.2.75 sublineages (16). Besides XBB and XBB.1, XBB.1.5 represents another Omicron subvariant (17). The “X” denotes that these subvariants resulted from the recombination of two or more sublineages, specifically BA.2.10.1 and BA.2.75.2 (18),(19).
Against this backdrop, present study aim was to explore the genomic characterisation and epidemiology of the XBB recombinant variant of SARS-CoV-2 in Uttarakhand, India. The study aims to investigate the epidemiological trends and genetic characteristics of recombinant variant identified at the VRDL lab, Government Doon Medical College, Dehradun, Uttarakhand, India.
This research will enhance our understanding of the genome of the newly emerged XBB recombinant variant of the coronavirus. It will contribute to the existing data on the epidemiology of various coronavirus variants circulating in Uttarakhand and adjacent regions during the study period. Given the rapid genomic alterations in the coronavirus and its impact on fully vaccinated individuals, a comprehensive comprehension of the viral genome and unique mutations in the circulating variants is crucial.
This retrospective cross-sectional study was conducted at the VRDL lab, Government Doon Medical College, Dehradun, Uttarakhand, India from September 2022 to February 2023. Data collection took place from March 2023 to April 2023, and data analysis was conducted from May 2023 to June 2023. Ethics approval was obtained from the Institutional Ethical Committee (Approval No. GDMC/IEC/2023/39).
Inclusion criteria: All samples that tested positive for SARS-CoV-2 by Reverse Transcriptase Polymerase Chain Reaction (RT-PCR) across all age groups were included in the study.
Exclusion criteria: Samples included samples that tested negative for SARS-CoV-2 by RT-PCR were excluded from the study.
Sample size: A total of 1,162 upper respiratory tract samples (nasopharyngeal and oropharyngeal swabs) from all age groups were included in the study. These samples were received for SARS-CoV-2 sequencing during the study period and comprised samples from inpatients, outpatients, and community surveillance. Sample size calculation was not performed as this was a retrospective study, and all samples received during the study period for sequencing were considered the study population.
Study Procedure
Samples were collected in 3 mL viral transport media tubes following standard protocols for sequencing (20). These samples were tested positive by RT-PCR in the set-up. Samples obtained from other hospitals were received in cryovials after testing positive for SARS-CoV-2 at Viral Research Diagnostic Laboratory (VRDL), Government Doon Medical College, Dehradun, Uttarakhand, India. RNA isolation was extracted using an automated magnetic bead-based extraction process in a Biosafety Level 2 (BSL) laboratory. RNA extraction was carried out using a 200 μL sample of viral transport media transferred to a 96-well deep well cartridge plate, following the manufacturer’s instructions with the QIA Symphony instrument. Library preparation and sequencing were conducted using the Ion AmpliSeqTM library kit plus, according to the manufacturer’s instructions. The Ion AmpliSeqTM SARS-CoV-2 Research Panel library was created, covering all possible serotypes and offering >99% coverage of the SARS-CoV-2 genome. The MagMAXTM Viral/Pathogen Nucleic Acid Isolation Kit was used for RNA isolation, and TaqManTM 2019-nCoV Assay Kit v1 was used for quantification and normalisation of RNA.
Sequenced findings were analysed using the Torrent SuiteTM Software with COVID-19 Annotate SnpEff, IRMA report, and Assembler Trinity SARS-CoV-2 plugins. Sequences from libraries with the highest concentration were used in FASTQ files and sent to the INSACOG for variant determination. Overall, the study followed a systematic approach in sample collection, processing, and analysis to identify SARS-CoV-2 variants in the study population.
Statistical Analysis
Microsoft Excel and Omnicalculator were used for the statistical analysis.
A total of 1,162 samples were processed for NGS of the coronavirus from September 2022 to February 2023. Out of the 1,162 processed samples, 41 (3.53%) samples were found to be the XBB variant of SARS-CoV-2 (Table/Fig 1).
Among patients infected with the XBB variant of the coronavirus and its sublineages, 26 (63.4%) were males and 15 (36.6%) were females. In the case of both males and females, young adults were affected more (age group 21-30 years) as shown in (Table/Fig 2).
The XBB and its sublineages were identified from patients in three districts of Uttarakhand, India. 38 (92.7%) of patients were from district Dehradun, followed by 2 (4.9%) in Haridwar and 1 (2.4%) in Uttarkashi. Among the patients with XBB and its sublineages, 8 (19.51%) patients were vaccinated, 19 (46.34%) were not vaccinated, and the vaccination status was unknown in 14 (34.15%) patients. Among vaccinated individuals, 6 (75%) were vaccinated with Covishield, 1 (12.5%) was vaccinated with Covaxin, and 1 (12.5%) was vaccinated with Moderna.
Eight (19.5%) patients were hospitalised, 31 (75.6%) patients were not hospitalised, while the hospitalisation status was unknown for 2 (4.9%) patients. All the patients with the XBB or its sublineages were symptomatic for SARS-CoV-2 infection. Five variants of XBB and its sublineages was found during the study period-XBB, XBB.1, XBB.1.5, XBB.2, and XBB.3. Majority of the patients 22 (53.7%) were affected by XBB.2, other variants are shown in (Table/Fig 3).
Eight hospitalised patients and their vaccination details are shown in (Table/Fig 4). Two patients with XBB.2 and XBB.3 sublineages were reported to have died. Both patients who passed away were elderly males who had been hospitalised in the Intensive Care Unit (ICU) for the management of severe COVID-19 disease. Death was not reported among the rest of the hospitalised patients during the study period. The genetic makeup of XBB, XBB.1, XBB.1.5, XBB.2, and XBB.3 lineages of the Omicron variant were studied, and the differences in mutations among the various lineages were analysed. (Table/Fig 5) depicts the differences in mutations in XBB and its sublineages. There were some mutations that were unique in the case of XBB, XBB.1, XBB.1.5, XBB.2, and XBB.3 lineages of the Omicron variant.
Conducted over a six-month period, this study involved NGS of SARS-CoV-2 positive samples, indicating that among the 1162 processed samples, the majority (82.62%) belonged to the Omicron variant, excluding XBB, while 3.53% (41 samples) were identified as XBB and its sublineages, as illustrated in (Table/Fig 1). Lineage detection was unsuccessful in 19 samples (1.63%), and sequencing failed in 142 samples (12.22%), with potential reasons for sequencing failure including issues such as improper sample collection, delayed transport of collected samples, or inadequate transport procedures for the collected samples. A total of 41 patients (3.53% of 1162) were identified with the XBB variant and its sublineages, predominance (63.4%). In contrast, a study by Selvavinayagam ST et al., in Tamil Nadu revealed that the XBB variant affected both male and female populations almost equally (males: 52.5%), indicating no gender based preference for the virus (19). According to Indian Biomedical Data Centre data, the maximum number of patients suffering from the XBB variant of SARS-CoV-2 were from Gujarat, and the minimum cases were seen in Assam, Bihar, and Uttarakhand. Patients with the XBB.1 sublineage were the maximum in Maharashtra and the minimum in Jharkhand. Six cases of XBB.1 sublineage infection have been reported from Uttarakhand. XBB.1.5 sublineage was least reported from Tripura and maximum from Maharashtra. There were three reported XBB.1.5 variants from Uttarakhand. XBB.2 sublineage was found in the maximum numbers in Gujarat and the minimum from Tripura, Punjab, Himachal Pradesh, and Manipur. Eleven samples were reported with XBB.1.5 sublineage from Uttarakhand. XBB.3 is most reported from Tamil Nadu and least from Madhya Pradesh (21).
In present study, 13 (31.7%) COVID-19 positive patients infected with XBB and its sublineages were from the age group of 21-30 years, followed by 10 patients (24.4%) in the age group 51-60 years and eight (19.5%) from the age group 41-50 years. The age group least affected by the XBB variant and sublineages in present study were 61-70 years, 71-80 years, and >80 years with one patient (2.4%) each. In present study population, five variants of XBB and its sublineages were found-XBB, XBB.1, XBB.1.5, XBB.2, and XBB.3. Out of the 41 patients with XBB and its sublineages, 8 (19.5%) were hospitalised (four patients were affected with XBB.2, two patients with XBB.1, and one patient each with XBB and XBB.3 lineages of the Omicron variant), 31 (75.6%) patients were not hospitalised whereas hospitalisation status was unknown for two (4.9%) patients. The majority of the patients with XBB strains were not hospitalised signifying that the circulating XBB variant and its sublineages do not cause significant morbidity and mortality in the majority of the patients.
Among the eight hospitalised patients, four patients were vaccinated with Covishield (both doses), one was not vaccinated, and vaccination status was not known for three patients. Among the hospitalised patients, 50% were previously vaccinated with the Covishield vaccine (two doses), which signifies the potentiality of the XBB variants and its sublineages to enter vaccinated hosts and cause disease. Findings from a study conducted by Tamura T et al., in Japan indicate that XBB exhibits enhanced fitness and displays resistance against the antiviral humoral immunity triggered by breakthrough infections of the previous Omicron variant. All vaccinated individuals took two complete doses of the vaccine (22).
Death was reported in two patients affected by XBB.2 and XBB.3 sublineages. Both patients who succumbed to death were elderly males and were admitted to the ICU for severe COVID-19 disease management. This points towards the virulent nature of XBB.2 and XBB.3 sublineages compared to other XBB sublineages. Although elderly patients were least affected by the XBB sublineages, deaths were only reported in the elderly age group. This could be because of their already compromised immune systems due to old age. In present study, hospitalised patients with the XBB.1 variant did not experience any mortality, consistent with the results of a study conducted by Selvavinayagam ST et al., in Tamil Nadu, which demonstrated a significant association between XBB.1 and the development of mild disease (19).
Present study analysed the mutations in XBB and its sublineages in terms of mutated amino acids, and found that the XBB variant differed from its sublineages by having two unique mutations. One was at amino acid Q94H of the S gene, and the other was at amino acid T2231 in the ORF3a gene. The unique mutations in the XBB sublineages are highlighted in (Table/Fig 5). Although the ORF3a in SARS-CoV is not essential for virus replication, it contributes to pathogenesis by regulating the Spike (S protein) trafficking (23).
All the mutations found in the XBB variant were shared by one or more of the four sublineages of the XBB variant. Two unique mutations were identified in XBB.1: one in the G252V amino acid of the S gene and the other in the G8 amino acid of the ORF8 gene. The unique mutation in the G252V amino acid of the S gene in the XBB.1 variant was also reported by Selvavinayagam ST et al., from Tamil Nadu (19). The wide array of S-protein mutations in the XBB and XBB.1 sublineages raises significant concerns regarding the potential compromise in the efficacy of existing vaccines and antibodies (mAbs, neutralising antibodies) used as therapeutics against COVID-19 (17). There was one unique mutation in the XBB.1.5 sublineage in the F486P amino acid of the S gene. The unique mutation in the S gene of XBB.1.5 at position F486P may enhance its infectivity and pave the way for future evolutionary advancements and the acquisition of further mutations (24).
A unique mutation for the XBB.2 sublineage was observed in the D253G amino acid of the S gene. The XBB.3 sublineage had two unique mutations: one in the G82D amino acid of the ORF1a gene and the other in the I1998V amino acid of the ORF1b gene. The unique mutation in the I1988V amino acid of the ORF1b in the XBB.3 variant was also reported by Selvavinayagam ST et al., from Tamil Nadu (19). These unique mutations in various genes of SARS-CoV-2 may potentially help the virus develop resistance against vaccination, further complicating disease outcomes.
The involvement of F486P in antibody escape post-vaccination in COVID-19 infection, uniquely mutated in the XBB.1.5 sublineage, has been a topic of discussion (25). According to the US Centers for Disease Control and Prevention (CDC), the doubling time of the XBB.1.5 proportion is nine days, and the CDC’s nowcast algorithm estimates the variant’s current prevalence in the US to be around 27.6% (95% prediction interval 14.0- 46.5%). The effect of the spike modification S486P, along with the existing high degree of immune escape by XBB, is likely the reason for its growth advantage (26). XBB.1.5 is identified as one of the Omicron subvariants with the largest immune escape based on pseudotyped viral neutralisation assays (27). The requirement of two nucleotide changes in the same codon to convert from phenylalanine to proline has made this mutation uncommon throughout the pandemic. The fact that XBB.1.5 exhibits a higher ACE2 affinity than XBB.1, without a more pronounced reduction in neutralisation by vaccines and convalescent sera, suggests that the advantage of XBB.1.5 over XBB.1 may be due to an increase in intrinsic transmissibility (28).
Limitation(s)
Vaccination history was not available for all cases, as our laboratory received samples for sequencing from various remote areas. A complete clinical history of patients could have shed better light on the clinical significance of various coronavirus variants. Follow-up was not feasible for all patients, which could have provided a clearer understanding of the disease outcomes caused by various coronavirus variants. Data on XBB and its sublineages could not be compared with other studies due to a lack of existing data on the same.
SARS-CoV-2 has been changing and advancing throughout the ongoing COVID-19 outbreak. With the ability to potentially reduce the efficacy of the existing vaccinations, XBB has rapidly emerged as a global public health concern. Despite this situation, it is still vital to advocate for widespread immunisation using available vaccines and to stress the need of booster shots, as the XBB variant and its sublineages are infecting both previously infected as well as vaccinated individuals. Conducting representative testing and genomic surveillance of each SARS-CoV-2 variant is essential for effectively developing mRNA vaccines, identifying new variants, and predicting their potential for immune evasion. Maintaining a robust level of immunity across all age groups, preventing reinfections, and reducing the risk of protracted COVID-19 are essential. Research efforts like this should be ongoing to monitor novel coronavirus variants, enabling proactive measures to potentially prevent another pandemic.
The authors acknowledge the Indian Council of Medical Research-Department of Health research (ICMR-DHR), New Delhi, India for the financial help extended to set up a Viral Research Diagnostic Laboratory (VRDL) at Government Doon Medical College, Dehradun, Uttarakhand, India. However, the ICMR has no involvement in the study design; collection, analysis, and interpretation of the data; writing of the manuscript; and in the decision to submit the manuscript for publication.
Authors would also like to acknowledge the help extended by Indian SARS-CoV-2 Genomics Consortium (INSACOG) for identification and confirmation of our sequencing data.
DOI: 10.7860/JCDR/2024/67424.19312
Date of Submission: Sep 13, 2023
Date of Peer Review: Nov 22, 2023
Date of Acceptance: Feb 22, 2024
Date of Publishing: Apr 01, 2024
AUTHOR DECLARATION:
• Financial or Other Competing Interests: None
• Was Ethics Committee Approval obtained for this study? Yes
• Was informed consent obtained from the subjects involved in the study? No
• For any images presented appropriate consent has been obtained from the subjects. NA
PLAGIARISM CHECKING METHODS:
• Plagiarism X-checker: Sep 14, 2023
• Manual Googling: Nov 29, 2023
• iThenticate Software: Feb 20, 2024 (11%)
ETYMOLOGY: Author Origin
EMENDATIONS: 6
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