S M. Biradar^1*, B. Kohima¹, M S. Mulimani^2*, Vishwanath Nayak¹, Vijayakumar Warad², Avinash Jugati², B S. Hunasagi ¹, Indu Pathi¹, Chetankumar M¹, Santhosh R. Awasthi¹, Basavaraj V¹ and Jyoti Hawaldar¹

¹Department of PharmD (Doctor of Pharmacy), SSM College of Pharmacy and Research Centre, Vijaypura, Karnataka, India

²Department of General Medicine, Shri B M. Patil Medical College Hospital and Research Centre, Vijaypura Karnataka, India

Corresponding Author E-mail:smbiradar@rediffmail.com

DOI : https://dx.doi.org/10.13005/bpj/2889

Abstract

Corona virus disease 2019 (Covid-19) is an acute respiratory illness caused by the Corona virus. Corona virus 2 (SARS-CoV-2) is a continuing global health crisis that has harmed the physiological and psychological health of people in over 200 countries worldwide. The current study performed a narrative review of its origin, epidemiology, transmission, clinical parameters, effects on mental health, management, vaccines and their trails, and future perspectives. The ease with which humans may transmit information to one another is unnoticeable in the early stages, making COVID-19 both terrifying and remarkable, but as time progresses, it can be managed successfully with the available therapies to some extent. Based on the condition and co-morbidities, therapeutic management is used in the pandemic situation, which includes drugs like antivirals, chloroquine and hydroxychloroquine, convalescent plasma therapy, Azithromycin, Corticosteroids, Cytokine’s, and oxygen therapy. Strategies such as self-quarantine, social isolation, and 70-day nationwide and state-by-state lockdowns in India aided in slowing the virus's spread, which may have been catastrophic otherwise. However, there are no clinically approved safer vaccines until the end of 2020. Several businesses have taken the lead in producing COVID-19 vaccines and came up with vaccines like Pfizer, Moderna from the US and UK, Covaxin, and Covishield from India, and vaccination programs began in India for targeting more than 300 million people.

Keywords

Covid-19; Social and Mental Health; Symptomatic therapy; Vaccinization

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Copy the following to cite this article: Biradar S. M, Kohima B, Mulimani S. M, Nayak V, Warad V, Jugati A, Hunasagi B. S, Pathi I, Chetankumar M, Awasthi S. R, Basavaraj V, Hawaldar J. Prognosis of Covid-19 on its 1st Anniversary: Global V/s Indian Scenario. Biomed Pharmacol J 2024;17(2).

Copy the following to cite this URL: Biradar S. M, Kohima B, Mulimani S. M, Nayak V, Warad V, Jugati A, Hunasagi B. S, Pathi I, Chetankumar M, Awasthi S. R, Basavaraj V, Hawaldar J. Prognosis of Covid-19 on its 1st Anniversary: Global V/s Indian Scenario. Biomed Pharmacol J 2024;17(2). Available from: https://bit.ly/3yE9HOz

Introduction

The Corona virus (Covid-19) is the greatest threat to world health now, and the greatest issue facing the cosmos is pandemic¹. Corona viruses, which cause sickness in animals and humans, are members of the family Coronaviridae of the Nidovirales family. Corona viruses are named after the crown-like spikes on their outer surface. They are a form of enclosed virus with a non-segmented, single-stranded, positive-sense RNA genome. Corona virus subgroups include alpha, beta, gamma, and delta coronaviruses ^{2, 3}. Seven coronaviruses can infect people all across the world, but the four most prevalent are 29E, NL63 (alpha coronavirus), OC43, and HKU1 (beta coronavirus).

MERS-CoV, the virus responsible for Middle East respiratory disease (MERS), and SARS-CoV, the virus responsible for severe acute respiratory disease (SARS), are rarer variants that induce more severe consequences. A severe new strain of SARS-CoV-2 began circulating in 2019, generating the disease COVID-19². Prior to the 2002 outbreak of SARS in Guangdong, China, caused by SARS-CoV, these viruses were thought to solely affect animals ^{3, 4}.

Origin and Transmission

The first known human coronavirus outbreak, known as HCoV-229E, occurred in 1965. Two subsequent outbreaks of comparable size, known as SARS-CoV and MERS-CoV, occurred in 2003 and 2012, respectively ⁵. CoVs have been found to be human-susceptible viruses, with CoVs HCoV-229E and HCoV-NL63 and CoVs HCoV-HKU1 and HCoV-OC43 both causing moderate respiratory symptoms comparable to the flu. The other two known CoVs, SARS-CoV and MERS-CoV, cause serious and potentially fatal respiratory tract diseases ⁶. SARS-CoV-2’s genomic sequence shared 79.5% similarity with SARS-CoV while sharing 96.2% identity with a bat CoV, RaTG13. According to viral genome sequencing investigations and evolutionary studies, the bat is the virus’s natural host, and SARSCoV-2 may be transferred from bats to humans via unidentified intermediary animals, as seen in figure-1³. SARS-CoV-2 may infect people by exploiting the angiotensin-converting enzyme 2 (ACE2) receptor, which is the same as SARS-CoV ⁷. According to WHO reports for 2020, almost 30% of the nations were unready and had no plans for the spread of COVID-19. In healthcare institutions, a complete infection prevention and control programme, as well as water, sanitation, and hygiene requirements, are only found in select countries. In the absence of a COVID-19 vaccine, preserving social and physical distance seeks to limit the spread of this infectious illness ⁸.

Figure 1: Transmission of Covid-19 to Human Host. Click here to view Figure

Epidemiology

The first case of Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) infection, which causes coronavirus illness (COVID-19), was discovered in December 2019 in Wuhan, China, and quickly spread to many other regions. The World Health Organisation (WHO) has recorded 69,592,545 positive COVID-19 cases as of December 10^th, 2020, and the death toll from COVID-19 had reached 1,581,854 globally. As of January 24, 2020, at least 830 instances had been documented in nine countries, including China, Thailand, Japan, South Korea, Singapore, Vietnam, Taiwan, Nepal, and the United States. The WHO classified COVID-19 as a public health emergency of international concern on January 30, 2020. The most impacted nations on the globe are the United States, India, Brazil, Russia, and the and the United Kingdom, and a high fatality rate is seen in countries like the United States (441K), Brazil (225K), Mexico (159K), India (154K), and the United Kingdom (106K). On January 30th, 2020, the state of Kerala reported the first SARS-CoV-2 positive case in India ^{9, 10}. Following that, just two further instances were recorded in February.  As of March 26th, the Indian Council of Medical Research and the Ministry of Family Welfare had confirmed a total of 649 cases, 42 recoveries, 1 migration, and 13 fatalities, In India, the COVID-19 infection rate is 1.7, which is far lower than in the worst-affected countries ¹¹. The first death in India was on March 12^th, 2020, in Kalaburagi, Karnataka, of a 76-year-old man with comorbidities of asthma, hypertension, diabetes, and a history of international travel. More instances occurred in March, and the number of cases has increased significantly since the second part of April 2020. According to the Ministry of Health and Family Welfare (MoHFW), as of June 9, 2020, there had been a total of 2,66,598 confirmed COVID-19 cases reported by 32 states and union territories ¹². The most affected states in India are Maharashtra, Karnataka, Kerala, Andhra Pradesh, Tamil Nadu, and Delhi. High fatality rates are seen in states like Maharashtra (51k), Karnataka (12.2k), Tamil Nadu (12.3k), Delhi (10.8k), and West Bengal (10.1k). On March 22^nd, 2020, the Janta Curfew was declared by the Government of India for quarantine and to prevent the spread of disease. Along with its positive effects, the government’s harsh public health policy also has negative effects on the populace, which can result in social, psychological, and economic stress, which can have long-term detrimental health effects ⁵.

Effect on Mental Health

Social determinants of health include race, gender, ethnicity, sexual orientation, disability status, and resources such as a job, money, food, shelter, and social supports ¹³. Health care workers (HCWs) have been observed to experience the psychological effects the most. Long working hours, strict rules and regulations, the constant need for attention and attentiveness, limited social contact, and completing tasks for which one may not have been prepared are all instances of extremely high work-related stressors. The COVID-19 pandemic-related emotional discomfort that healthcare workers experienced has been strongly linked to depression, stress, and anxiety ¹⁴. The pandemic of COVID-19 has had a profound psychological impact, and the social influence on the population may have an effect on both people’s health, safety, and well-being (due to insecurity, confusion, emotional isolation, and stigma) as well as communities’ (due to economic loss, closure of workplaces and educational institutions, insufficient funding for medical responses, and improper distribution of necessities) safety and well-being. These consequences can manifest as a wide range of emotional reactions (such as distress or psychiatric conditions), unhealthy behaviours (such as excessive substance abuse), and noncompliance with public health regulations (such as home confinement and vaccination) in both those who contract the disease and the general population ^15,16,17. COVID-19’s mental health implications are being referred to as the “fourth wave” of the pandemic and are expected to be responsible for the greatest and most long-lasting health footprint illustrated in figure 2.

Figure 2: Four Waves of Covid-19. Click here to view Figure

Risk factors effecting COVID 19

Risk factors for the Corona virus include older age (geriatric population), pre-existing cardiovascular or cerebrovascular diseases, Diabetes, Obesity, Chronic Kidney Disease (CKD), Chronic Liver Disease, Chronic Lung Illness (Chronic Obstructive Pulmonary Disease (COPD), Asthma, Interstitial Lung Disease (ILD), Idiopathic Pulmonary Fibrosis (IPF), or Bronchiectasis), Carcinoma, Dyslipidemia, Hypertension, Immune-compromised state (weakened immune system) ^18,19. COVID-19 can be spread by direct contact with infected animals or through human-to-human transmission and touching contaminated surfaces, which are the main forms of transmission. Along with risk factors, some clinical findings associated with COVID-19 are shown in Table 1.

Table 1: Clinical Findings Associated with Covid-19.

	Mild	Moderate	Severe
SPO2	>94% in room air	90-94% in room air	<90% in room air
RR	<24/minute	24-30	>30
	No pneumonia	Pneumonia +	Pneumonia++
CT Chest Criteria
	Normal or <25%	25%-75%	75%-100%
	Grade I	GradeII/III	Grade IV
Laboratory Findings
NLR	<3.2	>3.2	>5.5
CRP	<40	40-125	>125
Ferritin	<500	>500	>800
D Dimer	<0.5	>0.5	>1.0
LDH	<300	300-400	>400
IL6	<4.8	5-50	>80
LFT	Normal	Slight derangement	Moderate derangement

 

Treatment

COVID-19 does not have a specific antiviral therapy, and no safer vaccines were available until the end of 2020. The treatment was symptomatic, with oxygen therapy serving as the main treatment intervention for patients with severe infections. Antibiotics were also used to maintain body fluid balance and avoid subsequent bacterial infections. In situations of respiratory failure that is resistant to oxygen treatment, mechanical ventilation may be necessary; nonetheless, hemodynamic support is crucial for treating septic shock ²⁰. Patients with refractory hypoxemia should get extracorporeal membrane oxygenation (ECMO), according to the WHO. According to their circumstances, some serious patients receive rescue therapy using convalescent plasma and immunoglobulin G ⁷. The MOHFW and the Government of India have implemented a revised protocol for COVID-19 clinical care. The protocol also includes instructions for investigational medicines, including Remdesivir, Tocilizumab, Convalescent Plasma Therapy, and a prophylactic dose of low-molecular-weight heparin such as Enoxaparin. Corticosteroid dexamethasone has also been included in the treatment protocols for COVID-19 patients with moderate to severe illness. It is no longer recommended to use azithromycin and hydroxychloroquine combined to treat people with severe Corona virus infections ²¹.

Antiviral therapy

Antiviral drugs are Lopinavir/Ritonavir, Ribavirin, Oseltanavir, Penciclovir/Acyclovir, Ganciclovir, and Favipiravir. The experimental antiviral drug is Remdesivir. Antiviral medications and systemic corticosteroid therapy, such as neuraminidase inhibitors (Oseltamivir, Peramivir, Zanamivir, etc.), Ganciclovir, Acyclovir, and Ribavirin, as well as methyl prednisolone for influenza virus, are ineffective against COVID-19 and are not indicated ^4,7. Remdesivir, a nucleoside analogue and broad-spectrum antiviral, significantly suppresses SARSCoV-2 infection at low micromolar dosages and has a high selectivity index. Ritonavir and Lopinavir (protease inhibitors) can bind to the endopeptidase C30 of the SARS-CoV-2 protease and have an antiviral impact by lowering SARS-CoV-2 protein synthesis. Remdesivir was claimed to have been successful in treating the first COVID case in the United States. Acute Respiratory Distress Syndrome was reduced in severe SARS or MERS patients treated with Lopinavir/Ritonavir alone or in combination with other antiviral medications, which improved the patients’ prognosis ²².

Chloroquine

Chloroquine and hydroxychloroquine are widely used anti-malarial, auto-immune disease, and broad spectrum anti-viral drugs. They function by inhibiting the cellular receptor ACE2, impairing endosome acidification, and acting against a range of pro-inflammatory cytokines (including IL-1 and IL-6) ⁷. One of the first medical authorities in the world to suggest the use of HCQS prophylaxis among healthcare professionals and close associates caring for COVID-19 or suspected patients was the Indian Council of Medical Research. Azithromycin and hydroxychloroquine proved to work better together, according to certain research. Before using hydroxychloroquine, the likelihood of medication toxicity (including QT interval (QTC) prolongation and retinal toxicity) should be considered, especially in people who may be more vulnerable to these effects, such as those with epilepsy, porphyria, myasthenia gravis, and retinal pathology—glucose-6-phosphate dehydrogenase (G6PD) deficiency. Remdesivir and chloroquine together have been shown to successfully suppress the recently emerging SARS-CoV-2 in vitro ^{20, 22}. Hydroxychloroquine was exported from India to other countries like the US, Canada, UK, Mauritius, UAE, Sri Lanka, Russia, the Philippines, Brazil, Germany, Spain, Butan, Nepal, Afghanistan, Syria, etc.

Glucocorticoids

In individuals with COVID-19 pneumonia, glucocorticoids (Dexamethasone, Methyl Prednisolone) are not advised unless there are other indications (e.g., COPD). Glucocorticoids have been associated with both delayed viral clearance and an increased risk of death in individuals infected with the Middle East respiratory syndrome coronavirus (MERS-CoV) ²⁰. According to Union Health Ministry protocol, dexamethasone is an alternative choice to methyl prednisolone for managing moderate-to-severe COVID-19.

Immunotherapy

Convalescent plasma treatment has been used for over a decade to provide passive immunity in COVID-19 patients by infusing SARS-CoV-2 convalescent plasma from recovered patients with antiviral antibodies (IgG, IgA, IgM, IgE, and IgD). Convalescent plasma therapy has previously been used to treat a variety of diseases, including influenza, poliomyelitis, influenza A (H5N1), and ebola. The Food and Drug Administration stated in the “Diagnosis and Treatment Guidelines of COVID-19 (trial 6th, 7th, and 8th)” issued by the NHC that delivery and testing of experimental CP therapy may have a therapeutic effect on COVID-19 during the public health emergency ²⁴. Throughout India Convalescent plasma therapy, which can restrict the course of infection and reverse the inflammatory process in COVID-19 patients via numerous pathways, was first used in New Delhi. It also includes immune-modulatory cytokines and autoantibodies, which help to control the hyper-inflammatory process and cytokine storm, eventually improving respiratory function and prognosis in COVID-19 patients. Monoclonal antibodies that target the S1 domain of the SARS CoV, such as 80 R, m396, and S230.15, have been demonstrated to be successful in neutralising SARS-CoV infections by preventing their binding to ACE receptors on host cells ²².

Cytokine storm

Interleukin (IL)-1, IL-6, IL-12, interferon (IFN), and tumour necrosis factor (TNF) are cytokines that primarily target lung tissue²⁵. A well-known clinical syndrome called cytokine storm is defined by a massive production of pro-inflammatory cytokines that triggers an out-of-control immune response that damages organs. Particularly in tissues like the colon and kidney that express high levels of ACE2, the cytokine storm will cause harm. The use of mesenchymal stem cells that have been cytokine activated during treatment can cease the inflammatory process and aid in tissue repair ²⁶. According to a report from China, COVID-19 targeting cytokine storms is frequent in older people. Immune modulation may be required for COVID-19 at its most severe stages, in addition to antiviral and supportive therapies ²⁷.

Interferons

Interferons are critical cytokines used in the therapy of cancer, autoimmune disorders, and hepatitis B and C. IFN is a type I IFN that inhibits viral infection by interfering with virus replication and activating immune responses, both innate and adaptive. In vitro tests revealed that IFN efficiently inhibits SARS-CoV multiplication. Clinical and observational studies of SARS-CoV patients revealed a lack of cytokines, IFN-α and IFN-β, as compared to influenza patients ²⁸. COVID-19 patients have been found to have lower levels of IFN-α and IFN-β. IFNs were believed to be systemically efficient in restoring lung function or delaying mortality in SARS and MERS-CoV, but they generally failed to appreciably ameliorate the disease in humans ²⁹.  Potential drugs and their target sites, along with the replication mechanism of SARS-CoV2, are shown in Figure 3.

Figure 3: Replication Mechanism and Potential Drug Targets of SARS-COV2. Click here to view Figure

Need for Vaccine

When combined with good testing and existing prevention efforts, a COVID-19 vaccine will be a vital instrument in bringing the pandemic under control. Although Remdesivir, an antiviral medicine, is available in developed countries, it has been demonstrated to be beneficial in treating COVID-19 illness symptoms and hastening recovery³. Several companies have agreed to develop a COVID-19 vaccine that particularly targets SARS-CoV2. A range of strategies, including live-attenuated virus, viral proteins, viral nucleic acid, virus-like particles, peptides, viral vectors (replicating and non-replicating), and recombinant protein approaches, are being employed to develop a vaccine against SARS-CoV-2 ^{23, 27}. Some of the approved vaccines by different governments worldwide are listed in Table 2.

Table 2: Approved Vaccines All Over the World.

Manufacturer & Vaccine	Country	Efficacy	Type of vaccine
Oxford university Astra Zeneca	U.K, India	Up to 90%	Viral vector (Genetically modified virus)
Bharat biotech ICMR- Covaxin	India	80.6%	Inactivated
Serum Institute of India- Covishield	India	70.4%	Non replicating viral vector
BioNtech- Pfizer	Germany, America	95%	RNA
Moderna- National Institute of allergy and infectious diseases	Canada U.S.A	94.50%	RNA
Gamaleya research centre	Russia	91.4%	Viral vector
CanSino biologics	China	65.7%	Viral vector
Vector institute	Russia	100%	Peptide antigens
Sinovac biotech	China	>50%	Inactivated Virus
Sinopharm	China, U.A.E, Bahrain	79%	Inactivated Virus
Novavax	Russia	96.4%	Protein based

 

Pfizer & Moderna are COVID-19 mRNA vaccines approved by the Medicines and Health Products Regulatory Agency in the U.K. This is the first emergency use authorization granted following a global phase 3 study of a pandemic vaccine ³¹. The US Food and Drug Administration issued the first emergency use license of vaccines for the prevention of COVID-19 for anyone over the age of 16 on December 11, 2020. Soreness at the injection site, weariness, headache, muscular soreness, chills, joint pain, and fever were described as common mild to moderate adverse effects that often lasted several days during the second dose rather than the first treatment. For the existing side effects, the developers are constantly analysing the vaccine’s safety and tolerance ³².

The first vaccine developed in India, “Covaxin” by Bharat Biotech ICMR, is an inactivated whole virus vaccine for BBV 152 that has successfully completed Phase 1 (375 subjects) and Phase 2 (380 subjects) trials. The virus strain used in these trials was obtained from the Indian ICMR National Institute of Virology, Pune. The DNA-based second vaccination in India, “ZyCovD,” produced by Zydus Cadila, has completed Phase 1 and Phase 2 trials (1048 individuals), and following Phase 3, it may receive fast track approval from DCGI ³³. A restricted emergency approval for Covaxin and Covishield (the Oxford-AstraZeneca-designed vaccine that is also produced in India) was given by the country’s medicines authorities in January 2021. On January 16, 2021, India initiated the world’s largest COVID-19 vaccination campaign, with a target population of 300 million people ³⁴.

Conclusion

As the disease is growing at an alarming rate around the world, the COVID-19 pandemic has raised problems for almost every industry¹. Even though the state-wide lockdown has slowed the spread of COVID-19, the country’s constantly rising population, extraordinarily high population density, and deplorable socioeconomic conditions are important difficulties in India’s struggle ¹². Transmission of the virus can be prevented by adhering to the safety guidelines issued by the WHO and their respective governments. Specific therapy was not available, but it can be managed to some extent by the available drugs, and no safer vaccine was available until the end of 2020. Several companies taking initiative for the development of vaccines and vaccination programmes were taking place in India for the prevention of the COVID-19 pandemic. 

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