covid-19

Introduction: COVID-19 is an infectious disease caused by the severe acute respiratory syndrome coronavirus 2 and it was first reported in China. The aim of this study was to compare clinical features, chest CT findings and laboratory examinations of suspected COVID-19 inpatients according to RT-PCR analysis. Methods: Demographics, comorbidites, symptoms and signs, laboratory results and chest CT findings were compared between positive and negative groups. The study included 292 patients (134 females, 158 males) suspected of COVID-19. All statistical calculations were performed with SPSS 23.0. Results: 158 (54.1%) of the cases were male and 134 (45.9%) were female. Their ages ranged from 17 to 95 years, with an average of 50.46 ± 20.87. A symptom or sign was detected in 86.3% of all patients. The chest CT images of 278 patients were analyzed. Chest CT was negative in 59.2% of patients with positive RT-PCR and 43.9% of patients with negative RT-PCR results. Chest CT findings were atypical or indeterminate in 22.4% of patients with positive RT-PCR results and 20% of patients with negative RT-PCR analysis. ALP, bilirubine, CRP, eosinophil count, glucose, CK-MB mass and lactate were significantly lower in patients with positive RT-PCR test. LDH, lipase, MCV, monocyte, neutrophil count, NLR, platelet, pO2, pro-BNP, procalcitonin, INR, prothrombin time, sodium, troponin T, urea, WBC were significantly lower in patients with positive RT-PCR test results. Conclusion: The diagnosis of COVID-19 is based on history of patient, typical symptoms or clinical findings. Chest CT, RT-PCR and laboratory abnormalities make the diagnosis of disease stronger.

Introduction: the perennial pandemic: There are serious challenges posed by the SARS-CoV-2 virus and COVID-19 as the disease. With the persistence of the pandemic over one and half year, it is being feared that the COVID-19 may have become the new reality associated with human existence world over and the mankind may have to live with it for years or even decades. Further, the grievous nature of the disease is evolving further with genomic changes in the virus in form of mutations and evolution of variants, with enhanced infectivity and probably virulence. Acute and chronic phases of COVID-19: Epidemiologically, it is becoming clear that apart from the advanced age and pre-existing conditions, such as diabetes, cardiovascular, pulmonary, and renal diseases, certain constituent factors render some patients more vulnerable to more severe forms of the disease. These factors influence the COVID-19 manifestations, its course, and later the convalescence period as well as the newly defined ‘Long COVID phase. The substantial continuing morbidity after resolution of the infection indicates persisting multisystem effects of ‘Long Covid’. Lung damage associated with COVID-19: COVID-19 is primarily a respiratory disease presenting with a broad spectrum of respiratory tract involvement ranging from mild upper airway affliction to progressive life-threatening viral pneumonia and respiratory failure. It affects the respiratory system in various ways across the spectrum of disease severity, depending on age, immune status, and comorbidities. The symptoms may be mild, such as cough, shortness of breath and fevers, to severe and critical disease, including respiratory failure, shock, cytokine crisis, and multi-organ failure. Implications for the post-COVID care: Depending on the severity of respiratory inflammation and damage, as well as associated comorbidities, duration of injury and genetics, the progressive fibrosis leads to constriction and compression of lung tissues and damage to pulmonary microvasculature. Consequently, the COVID-19 patients with moderate/severe symptoms are likely to have a significant degree of long-term reduction in lung function. Depending on the severity of the disease, extensive and long-lasting damage to the lungs can occur, which may persist after resolution of the infection. Managing the long COVID’s challenges: Given global scale of the pandemic, the healthcare needs for patients with sequelae of COVID-19, especially in those with lung affliction are bound to increase in the near future. The challenge can be tackled by harnessing the existing healthcare infrastructure, development of scalable healthcare models and integration across various disciplines with a combination of pharmacological and non-pharmacological modalities. Following clinical and investigational assessment, the therapeutic strategy should depend on the disease manifestations, extent of damage in lungs and other organs, and associated complications.

Introduction - evolution of SARS-CoV-2 variants: With the unrestrained pandemic for over last one-and-half year, SARS-CoV-2 seems to have adapted to its habitat, the human host, through mutations that facilitate its replication and transmission. The G variant incorporating D614G mutation, potently more transmissible than the ancestral virus arose during January 2020 and spread widely. Since then, various SARS-CoV-2 variants of concern (VOCs) and variants of interest (VOIs) with higher infectivity or virulence or both, have evolved on the background of G variant, and spread widely. SARS-CoV-2 infection and the immunodynamics: As the virus becomes more transmissible, its lethality may drop. Apart from the humoral immunity, T-cell recognition from a previous SARS-CoV-2 infection or vaccination may modify the disease transmission correlates and its clinical manifestations. On the other hand, the immunity generated may reduce probability of re-infection as well as limit evolution of adaptive mutations, and emergence of highly infectious and immune-escape variants. There are complex issues related to the SARS-CoV-2 evolutionary dynamics and host’s immunodynamics. Trending etiopathoimmunological correlates: The evolution potential of SARS-CoV-2 is limited because of proofreading function of nsp14. The S protein mutations affect transmissibility, virulence, and vaccine efficacy. The D614G mutation in G variant with higher infectivity has turned the Chinese epidemic into a pandemic. Other SARS-CoV-2 variants, such as Alpha, Beta, Gamma, and Delta seem to have evolved as result of adaptation to selective pressures during periods of prolonged infections and subsequent transmission. Further, there is issue of convergent association of mutations. Basics of immunity and immune system failure: The nature of the immune response after natural SARS-CoV-2 infection is variable and diverse. There are pre-existing neutralizing antibodies and sensitized T cells elicited during previous infection with seasonal CoVs influencing the disease susceptibility and course. The virus has evolved adaptive mechanisms to reduce its exposure to IFN-I and there are issues related to erratic and overactive immune response. The altered neutralizing epitopes in the S protein in SARS-CoV-2 variants modify the immune landscapes and clinical manifestations. Conclusion: current scenarios and prospects: Presently, the SARS-CoV-2 infection is widespread with multiple evolving infectious variants. There is probability of its transition from epidemic to endemic phase in due course manifesting as a mild disease especially in the younger population. Conversely, the pandemic may continue with enhanced disease severity due to evolving variants, expanded infection pool, and changing immunity landscape. There is need to plan for the transition and continued circulation of the virus during the endemic phase or continuing pandemic for indefinite period.

COVID-19 pandemic soon apparently proved to be havoc and a great stressor. During such a stressful time, mental health is in threat. Here, we intend to review the presenting problems/ symptoms as shared in psychiatry helpline of a Teaching Hospital in eastern Nepal during the second week of lockdown and to reflect on to emotional, including mood problems. It is an institute based period observation noted for all psychiatry helpline calls during 1 week of lockdown days of COVID-19. Their concerns and problems were listened and symptoms clarified by a consultant psychiatrist to help them as far as possible through the telephonic conversation. Maintaining the confidentiality, basic information were noted down in a semi-structured proforma to record certain socio-demographic and clinical information (including mood and other emotional symptoms). We received 102 helpline calls of 60 clients for psychiatry in 1 week, from 14 districts. More patients being discussed were males (35/60), average age being 34.15 (15 - 70) years. More patients were regular follow-up cases with some new issues (24/60) and 18/60 each were new clients and regular follow-up cases. Majority had exacerbated symptoms in the wake of COVID-19 as: emotional (47/60; mood 24/60, anxiety/worry 23/60) symptoms along with disturbed sleep (32/60); treatment/service issues (31/60) and changed routines. Most common mental problems were Bipolar affective disorder, Psychosis, Anxiety and Depression and advices included Antipsychotics, Benzodiazepines, Antidepressants, along with some Psycho-education. Most common concerns were about OPD service, worsening symptoms and local unavailability of medicines. Many had mood and emotional symptoms in this stressful time, both simple amenable to telephonic advices and severe requiring to be called to emergency service.

This paper focuses on the mental health burden on medical and healthcare residents during the 1st wave of COVID-19 pandemic crisis in 2020 describing the activities of a mental health service for residents (NAPREME) in a public university, UNIFESP, Sao Paulo, Brazil; and a preliminary study showing an increasing of depressive symptoms and depression among residents. Data is related to the screening interviews of medical residents and healthcare multi-professional residents who sought the mental health service from March to December 2020. A comparison was conducted with the same period in 2019 (covering a period when Covid-19 was not affecting the Brazilian population). There was a 22% demand increase in 2020. Of the total amount who sought treatment: 23% were medical residents, 22% nursing residents, and the remaining distributed among other professions; and 58% were first year residents and 34% second year. Data from the BDI questionnaire showed some variance between the two years: the mean score for 2020 was 24.67 (± 7.86) which is in the depression range, higher than the mean score of 19.91 points in the previous year (± 10.15) which is only in the depressive symptoms range (p < 0.005). In the pandemic period there was an increase in residents with depression from 49% to 70%. Depression, anxiety, stress and burnout syndrome were observed, demanding psychological and psychiatric care for this population. Assessment of residents’ mental health will continue during 2021, during the 2nd wave of COVID-19 and an additional analysis will be conducted along the year.

In the late of 2019, there is an outbreak of novel coronavirus disease (COVID-19) in Wuhan, China. The patients appear respiratory symptoms, fever, and cough, shortness of breath and breathing difficulties. In more severe cases, infection can cause pneumonia, severe acute respiratory syndrome, kidney failure and even death. A novel coronavirus (nCoV) is a new strain that has not been previously identified in humans and is transmitted mostly via droplets or contact. People of all ages are susceptible to the virus. Up to the middle of February 2020, the number of infected persons in China is over 65,000. The case fatality rate was 2.38%, and elderly men with underlying diseases were at a higher risk of death [1].

We know that Corona Virus develops in animals, birds and humans’ body. Now it is a pandemic and many people are dying with each passing day and a number of patients are increasing every hours. If we do not control it then it is dangerous for humanity. As we know that incubation period for COVID-19 is 1 to 14 days and it’s live in the environment for 12 to 14 hours. The only solution to spread of virus is by social distancing. As we know that it affects person with low immunity so it is advised for all people to have balance diet, exercise daily and spend time in meditation for increasing immunity. I want to share a natural method to develop and increase the immunity power by the bile juice of animals, birds and we can try for corona virus too.

We have been hearing for centuries that ‘fever is not a disease but a symptom’. Physicians say that fever is a symptom of diseases like flu to cancer.

Among the abounding lessons we learned from the SARS-C0V-2 pandemic is the uttermost determinant that people are not equal before the severity of COVID-19. Indeed, the disease course differs with age, gender, ethnicity, underlying clinical conditions and virus variants. Other diseases modifying factors are associated with genetic traits such as those driving the immune response, the blood groups, the coagulation system and the ACE2 receptor variants [1-4].

The outbreak of new coronavirus acute respiratory disease (SARS-CoV-2) has been a major global challenge for the scientific community to save humanity. While, the unviability of the vaccine keeps most classes of society, especially African countries, suffer from the healthcare problem. Conventional medicine plants become the alternative method for the therapeutic because it contains valuable bioactive compounds. This brief review devoted the importance of medicinal plants such as Citrus, olive, garlic, ginger, green tea, woad, broad-leaf privet, Japanese torreya, and saffron crocus, by their antiviral effects (anti-SARS coronavirus, anti-HSV, and anti-HIV diseases) and their promising uses as probable boosters of the immune and anti-inflammatory response from SARS-CoV-2 infection. Based on scientific reports, bioactive compounds could inhibit 3-chymotrypsin-like cysteine protease and human protein ACE2, where these facts can be attractive to develop effective drugs. 

Background: The rapid spread of “Coronavirus Disease 2019’ (COVID-19) caused by Severe Acute Respiratory Syndrome Coronavirus-type 2 (SARS-CoV-2) significantly impacted health care facilities all across the globe. To assess impact on urology practice in our country, we developed a questionnaire based on relevant questions in current scenario for information regarding challenges and changes urologists were facing in their practices. Material and methods: We conducted an online survey to find out the impact of COVID-19 on urology practice in Indian scenario. The questionnaire comprised of total 18 questions, which were relevant to day to day practice. Results: Total 310 urologists across the India participated and consented to being part of the study. The majority admits change in their practice due to the recent COVID-19 outbreak. The majority admitted to attend fixed numbers of patients per day with prior appointment and to keep detailed records. The majority responded in positive that attendees will not be allowed, opted to wear N-95 mask in OPD, opted to take the relevant history, opted for thermal screening, opted for patients to wear a mask before entering OPD room, opted for using the new prescription at new visit and opted to avoid physical examination unless very necessary. The majority wanted to take consent from the patients that they may get infected by COVID-19 in the hospital and agreed on performing COVID-19 testing for every patient posted for surgery. The majority agreed to assign a separate operation theatre to operate patients with positive COVID-19 test and also preferred open surgery over minimal invasive surgery. Conclusion: Our survey revealed that the recent pandemic led to significant impacts on urology practice in our country. The urologists working in different setups are facing different challenges in this difficult condition. They have made certain changes in their practice to safely provide effective care to their patients.

Ephedra, an ancient herb, is applied to treat common cold and influenza for such a long time in China. Pseudoephedrine is a main active ingredient from Ephedra which is used for relieving nasal congestion clinically. We previously reported that pseudoephedrine showed a potent anti-inflammatory effect other than sympathomimetic effects. In the present study, we aimed to investigate whether pseudoephedrine could protect mice from the H1N1 virus infection. The mice were infected with a 20% LD50 influenza A virus (IAV) suspension via intranasal administration to establish a virus infection model. Further, the mice were orally administered pseudoephedrine or oseltamivir for 4 days from one day after infection. Our results showed that pseudoephedrine improved lung pathological damage during the IVA infection period, and it dramatically increased the survival rate and attenuated loss of body weight compared with the virus-infected control group. In addition, pseudoephedrine inhibited the cytokine storms and mRNAs expression of the TLR7 signaling pathway. Surprisingly, pseudoephedrine showed an inhibitory effect on the replication of IAV. These results give clear evidence that pseudoephedrine is a potential anti-influenza drug by blunting cytokine storms and inhibition of replication of IAV, and following these results, we speculate that it should be tested in the novel coronavirus pneumonia (COVID-19, a severe epidemic in China currently) in which the cytokine storms play a key role to damage bronchi and lung in the early stage.

Research on psychological risk factors for upper respiratory tract illnesses (URTIs) has been conducted for over fifty years. Early studies failed to control for exposure and also often relied on self-report rather than clinical and virological assessment. A universal policy used in the current COVID-19 pandemic has been to restrict exposure by social isolation. This leads to increased stress and removal of social interaction. In addition, information overload about the disease, and incorrect information, can also reduce wellbeing. Studies of experimentally-induced URTIs have shown that stress increases susceptibility to infection. Other research has shown that stress due to job insecurity and few social contacts are key risk factors for infection. This suggests that while social isolation will reduce exposure, it will also lead to an increased risk of illnesses, due to increased stress and reduced social support, should the person become infected with the virus. Other research has shown that infection and illness lead to changes in behaviour. These effects include greater negative affect and impaired attention and slower speed of response. Such effects are not only present when the person is symptomatic but also occur with sub-clinical infections, during the incubation period and after the illness. People with the illness are also more sensitive to other negative influences such as fatigue, and this has implications for safety critical jobs such as those carried out by healthcare professionals treating those with COVID-19.

Among all the countries, Yemen is free of corona virus, and no single case has been recorded till today. Yemen is characterized by its mother geographical location on the Red Sea and its population is approximately 30 million people and an area of ​​555,000 square kilometers.

COVID-19 virus structural components: The 2019-nCoV, also called SARS-CoV-2, was first reported in Wuhan, China in December 2019. The disease was named Coronavirus Disease 2019 (COVID-19) and the virus responsible for it as the COVID-19 virus, respectively, by WHO. The 2019-nCoV has a round, elliptic or pleomorphic form with a diameter of 60–140 nm. It has single-stranded RNA genome containing 29891 nucleotides, a lipid shell, and spike, envelope, membrane and hemagglutinin-esterase (HE) proteins. Steps in progression of COVID-19 illness: Once inside the airways, the S protein on the viral surface recognizes and mediates the attachment to host ACE-2 receptors and gains access to endoplasmic reticulum. The HE protein facilitates the S protein-mediated cell entry and virus spread through the mucosa, helping the virus to attack the ACE2-bearing cells lining the airways and infecting upper as well as lower respiratory tracts. With the dying cells sloughing down and filling the airways, the virus is carried deeper into the lungs. In addition, the virus is able to infect ACE2-bearing cells in other organs, including the blood vessels, gut and kidneys. With the viral infestation, the activated immune system leads to inflammation, pyrexia and pulmonary edema. The hyperactivated immune response, called cytokine storm in extreme cases, can damage various organs apart from lungs and increases susceptibility to infectious bacteria especially in those suffering from chronic diseases. The current therapeutics for COVID-19: At present, there is no specific antiviral treatment available for the disease. The milder cases may need no treatment. In moderate to severe cases, the clinical management includes infection prevention and control measures, and symptomatic and supportive care, including supplementary oxygen therapy. In the critically ill patients, mechanical ventilation is required for respiratory failure and hemodynamic support is imperative for managing circulatory failure and septic shock. Conclusion: Confusion, despair and hopes: There is no vaccine for preexposure prophylaxis or postexposure management. There are no specific approved drugs for the treatment for the disease. A number of drugs approved for other conditions as well as several investigational drugs are being canned and studied in several clinical trials for their likely role in COVID-19 prophylaxis or treatment. The future seems afflicted with dormant therapeutic options as well as faux Espoir or false hopes. As obvious, not all clinical trials will be successful, but having so many efforts in progress, some may succeed and provide a positive solution. Right now, though, confusion and despair prevail.

Background: The development of COVID-19 having been set apart as the third presentation of an exceptionally pathogenic coronavirus into the human populace after the extreme intense SARS-COV and MERS-COV in the twenty-first century. The infection itself doesn’t make a crucial commitment to mortality, anyway “cytokine storm” created by the unreasonable invulnerable reaction activated by the virus can result in a hyperinflammatory response of lung tissues and deadly lung injury, and in this way increment death rate. In this manner, immunomodulatory medications ought to likewise be remembered for treatment of COVID-19. Presentation of the hypothesis: the virus particles invade the respiratory mucosa firstly and infect other cells, triggering a series of immune responses and the production of cytokine storm in the body, which may be associated with the critical condition of COVID-19 patients. Once a cytokine storm is formed, the immune system may not be able to kill the virus, but it will certainly kill many normal cells in the lung, which will seriously damage the of lung function. Patients will have respiratory failure until they die of hypoxia. It is not yet clear what the death rate of Covid-19 will be, though the best estimate right now is that it is around 1 percent, 10 times more lethal than seasonal flu due to cytokines storm which trigger a violent attack by the immune system to the body, cause acute respiratory distress syndrome (ARDS) and multiple organ failure, and finally lead to death in severe cases of COVID-19 infection. Therefore, inhibiting cytokine storm can significantly reduce inflammatory injury in lung tissues. Pyridostigmine (PDG), cholinergic anti-inflammatory pathway (CAP) is a neural mechanism that modulates inflammation through the release of acetylcholine (ACh), resulting in decreased synthesis of inflammatory cytokines such as TNF-α and IL-1. This finding emphasis, the nervous and immune systems work collaboratively during infection and inflammation. Implications of the hypothesis: Administrations of Pyridostigmine (PDG) as cholinergic agonist inhibits the inflammatory response and lower the mortality of COVID-19 patients. Likewise, activation of the CAP during systemic inflammation down-regulates the production and release of inflammatory cytokines. 

The infectivity and pathogenesis: SARS-CoV-2, the causative agent of Covid-19, involves Angiotensin-converting enzyme 2 (ACE2) receptors on type II alveolar type 2 (AT2) cells in lungs. Apart from, the upper and lower respiratory tracts, the disease affects the gastrointestinal system prominently, as evidenced by the significant GI symptoms, early in the course of the disease. In addition, the virus infects ACE2-bearing cells in other organs including the heart and blood vessels, brain, and kidneys. Clinical features and morbidity: The clinical spectrum of COVID-19 varies from asymptomatic or pauci-symptomatic presentation to moderate to severe states characterized by respiratory failure necessitating mechanical ventilation and ICU support and those manifesting critical clinical condition with complications like sepsis, septic shock, and multiple organ dysfunction failure. The CT chest is an important tool for early identification of COVID-19 pneumonia as well as for prognostic purposes. The recovery and residual damage: The recovery and other outcomes vary depending on age and other aspects including sex, comorbidities, and genetic factors. The outlook for older adults, who account for a disproportionate share of critical disease, is unfavorable, and most of those who survive are unlikely to return to their previous level of functioning. The disease affects their long-term health and quality of life as well as brings in propensity for truncated post-disease survival. COVID-19 aftermath and follow up: The patients discharged from hospital following severe COVID-19, continue to suffer with lingering impact of the disease as well as that of the emergency treatments that saved their life. The post-infection reduced exercise tolerance and other subtle factors, like post viral fatigue syndrome, post-traumatic stress disorder, impaired concentration, delirium, and disturbed sleep-wake cycle often underly the functional impairment. In fact, there is need of step-down care and later a multidisciplinary support involving regular clinical assessment, respiratory review, physiotherapy, nutritional advice, and psychiatric support. Conclusion: The life after COVID-19: After recovery from the disease, the virus SARS-CoV-2, may persist for uncertain period. In addition, the chance of reinfection cannot be ruled out. The vitamin D supplementation may be helpful. In general, the quality of life (QOL) in ICU survivors improves but remains lower than general population levels, but most of the patients adapt well to their level of self-sufficiency and QOL. Also, the debility due to co-morbidities may further compromise the activity of daily living and QOL issues. The Age and severity of illness appear to be the major predictors of post-discharge physical functioning.

The coronavirus disease 2019 (COVID-19) pandemic, caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), began in December 2019 in Wuhan, China. To date, the virus has infected roughly 5,000,000 people and caused approximately 345,000 deaths worldwide, and these numbers are increasing rapidly. Because of the rapid spread and the rising disease burden, several antiviral drugs and immunomodulators are in clinical trials, but no drugs or vaccines have yet been approved against this deadly pandemic. At present, computed tomography scanning and reverse transcription (RT)-PCR are used to diagnose COVID-19, and nanotechnology is being used to develop drugs against COVID-19. Nanotechnology also plays a role in diagnosing COVID-19. In this article, we discuss the role of nanotechnology in diagnosing and potentially treating COVID-19.

In late 2019, a pandemic crisis started in Wuhan, China, swept the whole world. The disease is caused by the SARS-CoV-19 virus that belongs to the corona family of viruses. The virus mainly caused failure of respiration, and led to many deaths worldwide. The main focus of research and medicine is to find more about the virus, as well as the development of effective preventive and therapeutic measures. While many trials and opinions have been published, which might support or contradict each other, this article tries to provide a simplified viewpoint about the disease. We highly recommend the therapeutic strategies to include drug combinations that can target the pathogenesis at many levels. For example, a combination of an effective anti-viral Remdesivir, soulable ACE2, and an immune modulator.

The coronavirus disease 19 (COVID-19) is a highly transmittable and pathogenic viral infection caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), which emerged in Wuhan, China and spread around the world (WHO, 2020). The genome of the SARS-CoV-2 has been reported over 80% identical to the previous human coronavirus (SARS-like bat CoV) [1]. As of May 2020, more than 5 million people have been affected worldwide with deaths amounting to 333000, the numbers increasing at an alarming rate day by day.