Category: Covid-19

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The Impact of COVID-19 on Acute Surgical Admissions at the Sunshine Coast University Hospital – Cureus

February 28, 2022

Purpose

It has been noted in international literature that acute surgical admissions and number of operations reduced as a result of coronavirus disease2019 (COVID-19). This study assesses the impact of the COVID-19 pandemic on the number of acute surgical admissions, operations, and length of stay (LoS) at the Sunshine Coast University Hospital (SCUH), Queensland, Australia.

A retrospective study was conducted on patients admitted to the Acute Surgical Unit (ASU) during March and April for the years 2018, 2019, and 2020. Admission data for ASU patients in 2018 and 2019 were combined (pre-COVID) and compared with 2020 (COVID) to determine impact of the pandemic on presentations and procedures.

ASU admissions reduced in 2020 (461 patients) compared with pre-COVID years (mean: 545 patients per year). There was an increase in the number (%) of operations performed in 2020, 175 patients (38%) compared with pre-COVID years, mean 158 patients (29%), p = 0.001. There was a significant decrease in the number (%) of functional presentations in 2020, 29 patients (6.3%) compared with pre-COVID years, mean 105 patients (9.6%), p = 0.04. LoS was not significantly different (52 hours vs. 54 hours, p = 0.11).

COVID-19 has reduced the absolute number of acute surgical admissions at SCUH. This effectively reduced triage workload. Contrary to the literature, this study did not demonstrate a reduction in the number of operations or change in LoS. These data could be used by health administrators to help with resource allocation during future pandemics.

In early March 2020, Australia reported its first death from coronavirus disease 2019 (COVID-19). Throughout the month of March, many more Australians tested positive for COVID-19. Educational institutions began to close, and airlines began suspending flights. By mid-March, Australia banned all international arrivals by non-citizens and residents. By the end of March, the Australian Prime Minister introduced lockdown and the closure of all non-essential services, and the Queensland Premier introduced tight social distancing restrictions. These lockdown laws had a profound effect on peoples movement and behaviors [1]. In 2021, these restrictions have continued, and lockdown rules are ever-changing.

Prior to the COVID-19 pandemic, there was a paucity of information in the literature with regard to surgical admission rates during pandemics. During the Ebola virus outbreak in West Africa, hospital admission rates reduced and surgical procedures reduced up to 50% [2-5]. COVID restrictions in Canada and Hong Kong resulted in a reduction in hospital admissions and surgical procedures [6,7].

Since the beginning of the pandemic, there have been multiple retrospective analyses on the effects of COVID-19 on different parts of the health sector. A study performed by O'Connell et al. in the Republic of Ireland assessed patients presenting to their emergency surgical service between March 1, 2020, and April 3, 2020, and compared it with the preceding three years. They noted a 42.8% reduction in the number of patients admitted and a 25.4% reduction in operations [8]. Another study by Callan et al. in the United Kingdom found a similar reduction in admissions, though the rate of operations remained the same as before [9]. A study performed by Moustakis et al. in South Africa compared surgical admissions in the weeks before lockdown and during the lockdown and found a reduction in both non-trauma and trauma admissions [10].

The COVID-19 pandemic has had a significant effect on health systems worldwide and in Australia [11]. While elective surgery was reduced to category 1 (defined as needing treatment within 30 days) cases only in both the public and private health systems on the Sunshine Coast, there was no change to emergency surgery or the rostering of the Acute Surgical Unit (ASU) in the Sunshine Coast Hospital and Health Service (SCHHS). Despite this, there has been an anecdotal decline in the number of acute surgical presentations across the SCHHS. The reason for this perceived reduction is unclear, and it is hypothesized that the COVID-19 pandemic should not affect acute surgical admissions on the Sunshine Coast, as it is presumed that acute surgical presentations should be independent of co-existing viral infection and community quarantine. The objective of this study is to assess the impact of the COVID-19 pandemic on the number of public acute surgical admissions and to document any variance in length of admission as well as operative versus non-operative management as a consequence of COVID-19. The SCHHS comprises the following public facilities: Sunshine Coast University Hospital (SCUH), Nambour General Hospital, Caloundra Hospital, Gympie Hospital, and Maleny Hospital. These facilities service the Sunshine Coast, Hinterland, and Gympie regions. The policy both pre-COVID and during COVID is for all acute surgical presentations at these peripheral hospitals to be transferred to SCUH ASU, therefore enabling us to capture all acute surgical admissions on the Sunshine Coast.

This retrospective clinical audit was performed at the SCUH. Ethics exemption was obtained from the Metro North Health Human Research Ethics Committee (HREC Reference: Project ID 64819 LNR/2020/QPCH/64819). Baseline patient demographic and clinical details were obtained via the electronic patient medical record (iEMR).

The study population comprised all patients who were admitted under the ASU at SCUH for the dates March 1 to April 30 for the years 2018, 2019, and 2020. The same time frame each year was used to minimize the effect of seasonal fluctuations. Patients were excluded from the study if the majority of their care took place at another facility, under another inpatient team, or if they were under the age of 18 years. Patients were further categorized by age, gender, length of stay, readmission within seven days, and disposition. Medical diagnosis was made based on the discharge summary or working diagnosis at the end of the admission if a discharge summary was not completed. Treatment was categorized as antibiotics, surgical, endoscopic, or radiological intervention. Endoscopic intervention included gastroscopy, colonoscopy, and endoscopic retrograde cholangiopancreatography (ERCP), while radiological intervention included percutaneous drainage, and embolization. Outcomes were categorized as discharged (treatment complete), discharged against medical advice, transferred to another facility, or died in hospital.

Within the diagnostic categories, the functional category represented patients with an impairment of normal bodily function without evidence of acute surgical pathology, trauma was defined as all patients who sustain a mechanism or display physiological features of trauma requiring admission, biliary pathology included cholelithiasis and all related complications, and malignancy was defined as presentations where symptoms were a direct consequence of cancer.

As the objective of the study was to analyze the effect of the global pandemic on acute surgical admissions, the data from 2018 and 2019 were combined as pre-COVID data and compared with 2020 as COVID data.

Where appropriate, summary statistics are presented as number (%) for binary and categorical data, mean (SD) for normally distributed continuous data, and median (IQR) for non-normal continuous data. The Shapiro-Wilk test was used to determine the normality or otherwise of the data. Further binary comparisons were performed using either the standard Students t-test for normally distributed continuous data or the Wilcoxon sign-rank test for non-normal continuous data or Fishers exact test for categorical data. Stata Version 15.0 (StataCorp, College Station, TX) was used throughout, and the level of significance was set at p < 0.05.

Demographic variables between the pre-COVID and COVID data are presented in Table 1. The only significant difference was an increase in male gender in 2020.

The distribution of diagnoses from the pre-COVID and COVID data is presented in Table 2. In 2020, there was a statistically significant increase in the number of patients with appendicitis and malignancy. In 2020, there was a statistically significant decrease in the number of patients with a functional diagnosis and the number of patients with a hernia.

Treatment interventions by category for pre-COVID and COVID patients have been presented in Table 3. There was a statistically significant increase in the percentage of patients who received antibiotics or who underwent surgery in 2020. The increase in endoscopic procedures from pre-COVID to COVID approached significance (p = 0.06).

Further categorization of surgical, endoscopic, and radiological interventions has been presented in Table 4. In 2020, there were statistically significant increases in patients who underwent appendicectomy, abscess incision and drainage, and ERCP. There was a statistically significant decrease in the number of patients who did not undergo any procedure.

Analysis of the operative versus non-operative management of appendicitis and hernias has been presented in Table 5. Fishers exact test was used to compare operative rates for transferred patients, if it was assumed all, or none of the transferred patients underwent an operation.

The COVID-19 pandemic had a significant effect on Australian healthcare systems, including acute surgical patients. This retrospective analysis of acute surgical presentations during the COVID-19 pandemic and social isolation on the Sunshine Coast documented significant variation when compared with previous years. The number of admissions to the ASU for 2018 was 528 compared with 562 in 2019, while in 2020 the number of admissions was 461. The annual increase in total admissions in the pre-COVID years could be partly explained by the population increase on the Sunshine Coast from 356,823 to 361,870 (growth rate of 1.41%) [12]. Despite a population increase in 2020 to 367,180, there was an 18.34% decrease in the number of acute surgical admissions for 2020 compared with the average from the pre-COVID.

Analysis of admission diagnosis revealed that there was a significant decrease in the number of functional admissions to the ASU in 2020 when compared with previous years. In the pre-COVID data set, these admissions made up 9.6% of all acute surgical admissions, and during COVID, they only comprised 6.3% of the admissions. This decline could be explained by the public health lockdown initiatives, which may have deterred patients without pathology requiring surgical intervention from presenting to the hospital. Importantly, there was no significant decrease in patients with organic surgical pathologies in 2020 compared with previous years, with the exception of hernias. In the pre-COVID data set, the percentage of patients with a hernia diagnosis that proceeded to an operation was 37% compared with 86% for 2020. This suggests that during 2020, patients with uncomplicated hernias did not present to the hospital during lockdown.

The only pathologies with a statistically significant increase in 2020 were appendicitis (13.5% vs. 8.4%) and malignancy (1.7% vs. 0.6%). The percentage of patients with appendicitis who underwent an appendicectomy in 2018/2019 was 73% compared with 90% in 2020. In 2018, 17 patients with a diagnosis of appendicitis were transferred to Sunshine Coast University Private Hospital under a public/private contract. When it was assumed that all transferred patients underwent an appendicectomy, the rate of operatively managed appendicitis was 91%, indicating no change in rates of appendicectomy post-COVID. While there is current evidence to suggest that some cases of appendicitis can be managed conservatively with a similar efficacy to surgical intervention [13], this was not the policy of the SCHHS during the study years analyzed.

There was also a significant increase in the percentage of patients who underwent a procedure and/or received antibiotics in 2020 compared with previous years. This could be attributed to the increase in appendicitis and the decrease in patients with functional presentations and uncomplicated hernias.

There was no statistically significant difference between the pre-COVID and COVID populations with regard to the duration of stay and rates of readmission. This is an important note, as duration of stay and readmission rates are measures of morbidity. In contrast, a study in the United Kingdom found that the COVID-19 lockdown resulted in prolonged admissions and higher rates of complications [14]. Another study in New Zealand found that there were fewer acute surgical admissions, though there were increased rates of complications and length of stay [15].

It has been noted in the international literature that acute surgical admissions and number of operations reduced because of COVID-19. The SCUH noted a significant drop in acute surgical admissions; however, there was an increase in surgical operations and no significant decrease in patients with acute surgical pathology. This could be a consequence of the difference in the burden of COVID-19 between Australia and other countries. Although Australia had similar lockdown rules to other countries, our geographical isolation meant that there were significantly less cases of COVID-19 and that our health systems were not overwhelmed. There was no redirection of service provision in surgery to ICU and emergency at SCUH, and there was no reduced access to emergency theater nor changes in standard of operation (i.e. avoidance of laparoscopic surgery). This study, therefore, demonstrates that the reduction in acute surgical admissions is more likely a result of the public avoidance of hospitals rather than redistribution of workload and highlights the importance of the continued function of the ASU during future pandemics. It may also service as insight into resource allocation, possibly supporting the continuation of Categories 2 and 3 elective surgery throughout the pandemic.

While the study demonstrated that there was no significant change in the percentage of patients with acute surgical pathologies between 2020 and the pre-COVID years, this study is limited by the fact that the SCUH was only operational for four years prior to 2020, and an analysis of a longer time frame may improve the data. Further limitations include the minimal impact of COVID-19 on Australia in 2020 with low case numbers of COVID-19 and inconsistent and ever-changing lockdown rules at the start of the pandemic. Further analysis of the duration of symptoms and severity of disease at presentation may give an insight into whether the public health lockdown laws caused any detriment to patient outcomes by prolonging sickness prior to hospital presentation.

This study demonstrated a decrease in the total number of acute surgical admissions, mainly in the functional presentation category. There was an increase in the percentage of patients who had surgery, but there was no significant change in the length of hospital stay. Further analysis into patient outcomes, such as time to surgery and post-operative complications, could be useful to assess other effects of the pandemic on patient care. This study provides valuable information regarding the possible trends to be anticipated in future global pandemics to help with resource allocation.

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The Impact of COVID-19 on Acute Surgical Admissions at the Sunshine Coast University Hospital - Cureus

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Could COVID-19 increase the risk of dementia? – Medical News Today

February 26, 2022

For most, COVID-19 causes a few days of mild to moderate symptoms, but others feel the effects for months. Some of these effects are neurological, leading scientists to ask whether COVID-19 could increase the risk of dementia. Medical News Today looked at the evidence and spoke with experts to find out the latest views.

Since the start of the COVID-19 pandemic, more than 425 million SARS-CoV-2 infections have been confirmed worldwide. Globally, almost 6 million people have died from, or with, the infection.

For most, when SARS-CoV-2 infection leads to COVID-19, the symptoms are mild to moderate. But for some, symptoms of the illness are prolonged.

Experts have described this issue, long COVID, as not recovering [for] several weeks or months following the start of symptoms that were suggestive of COVID, whether you were tested or not.

Symptoms of long COVID vary, but some are common COVID-19 symptoms, such as fatigue, shortness of breath, a cough, and joint pain.

Other respiratory virus infections have been associated with neurological and psychiatric after-effects. The authors of one review observe that Numerous respiratory viruses can infect the cells of the peripheral and central nervous systems, elicit inflammatory cascades, and directly and indirectly cause various neurologic manifestations.

And it seems that COVID-19 is no exception, with many people reporting neurological symptoms after SARS-CoV-2 infections. These symptoms may include:

Experts are now investigating how COVID-19 might affect neurocognitive function and whether it may increase dementia risk.

SARS-CoV-2 usually gains access to the body via droplets that enter the nose or mouth. From there, the virus moves to the throat. It can then travel to the lungs and other organs, and, various studies suggest, may enter the nervous system.

The blood-brain barrier stops most viruses from entering the brain. So some studies have investigated whether the neurological effects of COVID-19 stem from either a viral invasion of the central nervous system or the systemic effects of the infection.

One review suggests that both may occur in parallel. In severe infections, oxygen deprivation and a cytokine storm may damage the blood-brain barrier and allow SARS-CoV-2 to enter the brain.

Another review backs this up, suggesting that SARS-CoV-2 may disrupt the blood-brain barrier or infect the peripheral neurons, then enter the central nervous system.

Prof. Harris Gelbard, director of the Center for Neurotherapeutics Discovery at the University of Rochester Medical Center, told Medical News Today:

A recent cerebrospinal fluid study suggests that patients with COVID-19 infection have blood-cerebrospinal fluid barrier dysfunction, with pathology occurring in endothelial cells that line blood vessels in the blood-brain barrier. While this study did not demonstrate evidence for the presence of SARS-CoV-2 in any of the cerebrospinal fluid samples, all patients in this study had PCR-proven COVID-19.

Evidence is growing that COVID-19 can cause neurological damage. One 2020 review observed that COVID-19 is also anticipated to take a toll on the nervous system in the long term.

Another asserts that Respiratory virus neurotropism and collateral injury due to concurrent inflammatory cascades result in various neurologic pathologies, including Guillain-Barr syndrome, encephalopathy, encephalitis, ischemic stroke, intracerebral hemorrhage, and seizures.

Some research has suggested that SARS-CoV-2 might invade the nervous system in the same way that it invades other cells, via agiotensin-converting enzyme 2 (ACE2) receptors.

However, only certain cells in the nervous system have these receptors. Among them are excitatory and inhibitory neurons and other types of cells, such as astrocytes, oligodendrocytes, and endothelial cells.

One review points out that that ACE2 receptors are expressed in small blood vessels in the brain, which could provide a potential entry route for SARS-CoV-2 into the brain.

Prof. Gelbard emphasized that the evidence so far of how SARS-CoV-2 might enter the central nervous system is not conclusive: The pathologic evidence for direct infection of neural cell types, particularly neurons, remain[s] equivocal at best. Despite survey studies of neuronal expression of ACE2 receptors from brain transcriptome databases, [] the correlative neuropathology from postmortem human cases is scant.

Whether or not the virus invades the central nervous system, it is clear that SARS-CoV-2 infection can lead to cognitive dysfunction that may last for months or even years after the acute phase of COVID-19.

Many people who are hospitalized with COVID-19 have inflammatory complications, which can affect the nervous system. One study has reported that these patients experience delirium, reduced consciousness, stroke, and other encephalopathies following SARS-CoV-2 infection.

In this study, the researchers found that the degree of inflammation was correlated with the severity of COVID-19 symptoms and an increase in pro-inflammatory cytokines.

Prof. Gelbard, who was not involved in this study, explains how experts interpret the findings:

Our collective view of this is that SARS-CoV-2 infection/COVID-19 impacts elderly patients with underlying neurovascular disease, whether it is from cerebrovascular disease, subclinical Alzheimers disease, Parkinsons disease or other neurodegenerative disease, by creating a pro-inflammatory central nervous system milieu that is permissive for cognitive impairment, either manifesting as acute delirium or delirium superimposed on dementia.

Studies have shown that people with dementia have increased morbidity and mortality from COVID-19. Many have comorbidities associated with poor COVID-19 outcome, such as cardiovascular disease, diabetes, hypertension, and obesity.

Dr. Heather Snyder, Alzheimers Associations vice president of medical and scientific relations, told MNT:

The factors causing or contributing to dementia, including hypertension and diabetes, may be what make individuals with dementia more vulnerable to contracting COVID-19. [] Research published in February 2021 in Alzheimers & Dementia: The Journal of the Alzheimers Association found that risk of contracting COVID-19 was twice as high for people living with dementia than those without it.

People with dementia are more at risk of COVID-19 but might the disease worsen existing dementia or cause the development of dementia?

It may be that for people with dementia, SARS-CoV-2 can more easily enter the brain, as the blood-brain barrier is damaged. This might explain worsening symptoms reported in people with dementia after COVID-19.

One study states: There is evidence for a bidirectional relationship between viral infections and dementia: People with dementia have an increased risk for infection, while a poor immune response to infection places individuals at increased risk for dementia.

Another risk of COVID-19, and particularly severe forms of this disease, is thrombosis, a cause of strokes. According to one large study, a stroke can double the risk of developing dementia.

People with severe COVID-19 are more likely to have neurological symptoms of the illness, both during its acute phase and afterwards. And severe COVID-19 is more common in those who are older or have comorbidities, such as overweight or obesity, diabetes, chronic lung disease, and cancers.

Studies suggest that the best way to avoid neurological effects of COVID-19 is to optimize brain and body health in these ways:

Drug treatments to combat inflammation are also an option. Prof. Gelbard, who is now working on developing such a treatment, commented, What is sorely needed is an appropriate anti-neuroinflammatory intervention with a brain-penetrant therapy that can mitigate this type of neuroinflammatory response.

And, as several experts have noted, vaccination against COVID-19 is one of the most effective ways of minimizing the risk of both severe COVID and long COVID, a view Dr. Snyder reiterated:

While we work to further understand the lasting impacts of COVID-19 on the brain, the take-home message for protecting your cognition is simple: Dont get COVID-19. The best way to not get COVID-19 is to get vaccinated.

As yet, it is unclear whether COVID-19 may be a risk factor for dementia.

Dr. Snyder told MNT that The ongoing COVID-19 pandemic gives us an unwelcome opportunity to study the impact of viral infection on the brain in the short and long term.

She added: Potential viral contributions to Alzheimers and dementia have been long debated within the research community. However, no research to date has shown definitively that a virus can cause Alzheimers disease. Because COVID-19 is still relatively new, we wont know if infection will have an impact on dementia risk for some time.

Prof. Gelbard concurred: Unfortunately, we believe this is the tip of the iceberg. Not to sound like an alarmist, but we echo the sentiments of public health experts: We may feel like we are done with COVID-19, but the virus is not done with us. We expect the aftershocks of this pandemic to continue amplifying the challenge of dealing with neurodegenerative disease in the elderly and immunocompromised.

If you have had COVID-19, it doesnt mean youre going to get dementia. Were still trying to understand this relationship.

Dr. Heather Snyder

While researchers have yet to arrive at conclusive evidence, it appears that the neurological and psychiatric effects of COVID-19 are likely to be with us for many years to come.

For live updates on the latest developments regarding COVID-19, click here.

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Could COVID-19 increase the risk of dementia? - Medical News Today

COVID-19 is killing more people now than during most of the pandemic – KCRA Sacramento

February 26, 2022

Plummeting COVID-19 case counts across the United States are leading to lifted mask mandates and more conversations about steps toward normalcy but more people are dying of the coronavirus now than during most points of the pandemic.More than 2,000 COVID-19 deaths have been reported in the United States each day for the past month. Average daily deaths are falling, but from a very high point. They dipped just below that mark in recent days, to about 1,900 on Monday; the federal holiday may have delayed reporting.Before omicron became the dominant coronavirus strain in the U.S., there were only about 100 other days when there were more than 2,000 COVID-19 deaths, according to data from Johns Hopkins University.The only other time that deaths have been this high for this long was during the first winter surge, before vaccines were available. The omicron wave has also been deadlier for longer than the delta surge: In September, when delta was dominant, average daily deaths topped 2,000 for half as long.More than 120,000 people in the U.S. have died of COVID-19 since omicron became the dominant variant in December, and COVID-19 has accounted for more than 1 in 5 deaths reported in 2022.A common refrain early in the pandemic was that COVID-19 was most deadly for the elderly and people with certain health conditions. The people dying from COVID-19 now tend to be younger than before, and they're overwhelmingly unvaccinated, experts say."I've long since lost track of the number of people I've seen die of the disease, but the reality is that almost everybody who is critically ill, in the ICU or dying now remains unvaccinated. That has been true since the beginning. But in the beginning, people didn't have the opportunity to be vaccinated," said Dr. Stephen Threlkeld, medical director of the infectious diseases program at Baptist Memorial Health Care in Memphis."None of us taking care of COVID patients need CDC statistics or anyone else to tell us that, because we simply see that reality play out every day and have for quite some time."But the data from the U.S. Centers for Disease Control and Prevention is clear. In December, the risk of dying from COVID-19 was 14 times higher for unvaccinated adults than it was for adults who were fully vaccinated with their initial series. The gap was even larger when looking at those who also got their booster shot: 51 times higher.Throughout the pandemic, the majority of COVID-19 deaths have happened in hospitals. But that share is even larger now, as nursing homes have become less of a hotspot. In 2020, more than 1 in 5 COVID-19 deaths was in a nursing home. But in 2022, fewer than 1 in 10 deaths have been in nursing homes, according to provisional data from the CDC.Vaccination rates are higher among older people in the U.S., leaving a larger share of younger, unvaccinated people at higher risk for severe outcomes.Nearly 90% of seniors 65 and older are fully vaccinated with their initial vaccine series, and about two-thirds of those eligible have gotten their booster shot. But less than two-thirds of adults under the age of 40 and less than a third of children are fully vaccinated.And the vaccines are working. Seniors accounted for 81% of COVID-19 deaths in 2020, a number that dropped to 69% in 2021 and has stayed at 76% so far in 2022, despite the increased risk for breakthrough infection amid exponential community spread."The virus simply went to the fuel that it had remaining," Threlkeld said.Racial disparities in COVID-19 deaths persist, but have decreased over time. Black, Hispanic and American Indian people are still about twice as likely to die of COVID-19 than white people, but that risk has fallen from about three times higher at the end of 2020.And white people, who are less likely to be vaccinated than Hispanic people, have accounted for a growing share of deaths recently. An analysis by the Kaiser Family Foundation found that early in the omicron surge, the death rate for Hispanic people remained lower than the rate for white people, but death rates among Black people rose.And as the virus spread rapidly throughout the country, social determinants of health have started to play a larger role in who becomes seriously ill and dies from COVID-19."Delta was much more deadly. But omicron is so widespread," said Dr. Faisal Masud, director of the critical care center at Houston Methodist.Extremely high transmission rates mean the virus is reaching everyone, but it's hitting those from disadvantaged neighborhoods especially hard, he said. These are the people who are more likely to be uninsured and who may delay care, leaving chronic conditions such as diabetes and hypertension untreated."Patients who start with poor health come at a disadvantage," he said.Texas has reported more COVID-19 deaths than any other state in the past week and is on track to soon outpace California in terms of total COVID-19 deaths. It's important to note the significant differences in health insurance rates and vaccination rates in the two states, Masud said. More than 70% of Californians are fully vaccinated, compared with about 60% of Texans, according to CDC data.Overall, the proportion of omicron cases that have resulted in deaths appears to be lower than the case-mortality ratio for delta.But it's a "denominator phenomenon," Threlkeld said, meaning a lower percentage of a much larger number is still going to be large."I think that's what people have forgotten: Just because something is a little less likely in a given person to cause severe disease, there are so many more people who've contracted this infection that you're going to have a lot of people who are ill," he said."We've certainly seen a lot of unvaccinated people who've done very poorly."

Plummeting COVID-19 case counts across the United States are leading to lifted mask mandates and more conversations about steps toward normalcy but more people are dying of the coronavirus now than during most points of the pandemic.

More than 2,000 COVID-19 deaths have been reported in the United States each day for the past month. Average daily deaths are falling, but from a very high point. They dipped just below that mark in recent days, to about 1,900 on Monday; the federal holiday may have delayed reporting.

Before omicron became the dominant coronavirus strain in the U.S., there were only about 100 other days when there were more than 2,000 COVID-19 deaths, according to data from Johns Hopkins University.

The only other time that deaths have been this high for this long was during the first winter surge, before vaccines were available. The omicron wave has also been deadlier for longer than the delta surge: In September, when delta was dominant, average daily deaths topped 2,000 for half as long.

More than 120,000 people in the U.S. have died of COVID-19 since omicron became the dominant variant in December, and COVID-19 has accounted for more than 1 in 5 deaths reported in 2022.

A common refrain early in the pandemic was that COVID-19 was most deadly for the elderly and people with certain health conditions. The people dying from COVID-19 now tend to be younger than before, and they're overwhelmingly unvaccinated, experts say.

"I've long since lost track of the number of people I've seen die of the disease, but the reality is that almost everybody who is critically ill, in the ICU or dying now remains unvaccinated. That has been true since the beginning. But in the beginning, people didn't have the opportunity to be vaccinated," said Dr. Stephen Threlkeld, medical director of the infectious diseases program at Baptist Memorial Health Care in Memphis.

"None of us taking care of COVID patients need CDC statistics or anyone else to tell us that, because we simply see that reality play out every day and have for quite some time."

But the data from the U.S. Centers for Disease Control and Prevention is clear. In December, the risk of dying from COVID-19 was 14 times higher for unvaccinated adults than it was for adults who were fully vaccinated with their initial series. The gap was even larger when looking at those who also got their booster shot: 51 times higher.

Throughout the pandemic, the majority of COVID-19 deaths have happened in hospitals. But that share is even larger now, as nursing homes have become less of a hotspot. In 2020, more than 1 in 5 COVID-19 deaths was in a nursing home. But in 2022, fewer than 1 in 10 deaths have been in nursing homes, according to provisional data from the CDC.

Vaccination rates are higher among older people in the U.S., leaving a larger share of younger, unvaccinated people at higher risk for severe outcomes.

Nearly 90% of seniors 65 and older are fully vaccinated with their initial vaccine series, and about two-thirds of those eligible have gotten their booster shot. But less than two-thirds of adults under the age of 40 and less than a third of children are fully vaccinated.

And the vaccines are working. Seniors accounted for 81% of COVID-19 deaths in 2020, a number that dropped to 69% in 2021 and has stayed at 76% so far in 2022, despite the increased risk for breakthrough infection amid exponential community spread.

"The virus simply went to the fuel that it had remaining," Threlkeld said.

Racial disparities in COVID-19 deaths persist, but have decreased over time. Black, Hispanic and American Indian people are still about twice as likely to die of COVID-19 than white people, but that risk has fallen from about three times higher at the end of 2020.

And white people, who are less likely to be vaccinated than Hispanic people, have accounted for a growing share of deaths recently. An analysis by the Kaiser Family Foundation found that early in the omicron surge, the death rate for Hispanic people remained lower than the rate for white people, but death rates among Black people rose.

And as the virus spread rapidly throughout the country, social determinants of health have started to play a larger role in who becomes seriously ill and dies from COVID-19.

"Delta was much more deadly. But omicron is so widespread," said Dr. Faisal Masud, director of the critical care center at Houston Methodist.

Extremely high transmission rates mean the virus is reaching everyone, but it's hitting those from disadvantaged neighborhoods especially hard, he said. These are the people who are more likely to be uninsured and who may delay care, leaving chronic conditions such as diabetes and hypertension untreated.

"Patients who start with poor health come at a disadvantage," he said.

Texas has reported more COVID-19 deaths than any other state in the past week and is on track to soon outpace California in terms of total COVID-19 deaths. It's important to note the significant differences in health insurance rates and vaccination rates in the two states, Masud said. More than 70% of Californians are fully vaccinated, compared with about 60% of Texans, according to CDC data.

Overall, the proportion of omicron cases that have resulted in deaths appears to be lower than the case-mortality ratio for delta.

But it's a "denominator phenomenon," Threlkeld said, meaning a lower percentage of a much larger number is still going to be large.

"I think that's what people have forgotten: Just because something is a little less likely in a given person to cause severe disease, there are so many more people who've contracted this infection that you're going to have a lot of people who are ill," he said.

"We've certainly seen a lot of unvaccinated people who've done very poorly."

Read more here:

COVID-19 is killing more people now than during most of the pandemic - KCRA Sacramento

New CDC Covid-19 metrics drop strong mask recommendations for most of the country – CNN

February 26, 2022

CNN

Most people in the United States live in areas where those who are healthy do not need to wear masks indoors, according to new US Centers for Disease Control and Prevention guidance a sweeping change from what earlier Covid-19 metrics recommended.

New CDC metrics indicate that about 28% of people in the United States live in a county where they need to wear masks indoors. Previously, CDC pointed to levels of coronavirus transmission within communities as a key metric for restrictions and recommended that people in areas with high or substantial levels of transmission about 99% of the population should wear masks indoors.

Now, the CDCs Covid-19 community level metrics are based on three pieces of data in a community: new Covid-19 hospitalizations, hospital capacity and new Covid-19 cases. The CDCs website includes a list of US counties and their current Covid-19 levels.

Under the updated guidance, more than 70% of the US population is in a location with low or medium Covid-19 community levels. For those areas, there is no recommendation for indoor masking unless you are at potential increased risk for Covid-19 and if so, the CDC recommends to talk to your health care provider about wearing a mask.

Were in a better place today than we were six months ago, six weeks ago, six days ago, US Health and Human Services Secretary Xavier Becerra said in a statement to CNN. Now its time to focus on severity, not just cases, of COVID. Because of all the hard work thats been done and the many tools weve developed to tackle COVID, we can ease the guidance on mask use not everyone in every place needs to wear a mask.

At all levels, the CDC recommends people get vaccinated and boosted, and get tested if they have symptoms.

In areas with high levels, the CDC also advises wearing a mask in public indoor settings, including schools. In areas with medium levels, the CDC advises talking with your doctor about wearing a mask if youre at increased risk for Covid-19. In areas with low Covid-19 community levels, there is no recommendation for mask wearing.

The CDC notes that anyone who wants to wear a mask should continue to do so.

The updated CDC recommendations reflect a new approach for monitoring Covid-19 in communities, Dr. Gerald Harmon, president of the American Medical Association, said in a statement Friday.

But even as some jurisdictions lift masking requirements, we must grapple with the fact that millions of people in the U.S. are immunocompromised, more susceptible to severe COVID outcomes, or still too young to be eligible for the vaccine. In light of those facts, I personally will continue to wear a mask in most indoor public settings, and I urge all Americans to consider doing the same, especially in places like pharmacies, grocery stores, on public transportation locations all of us, regardless of vaccination status or risk factors, must visit regularly, Harmon said.

Although masks may no longer be required indoors in many parts of the U.S., we know that wearing a well-fitted mask is an effective way to protect ourselves and our communities, including the most vulnerable, from COVID-19particularly in indoor settings when physical distancing is not possible.

Counties with fewer than 200 new Covid-19 cases per 100,000 people in the past week are considered to have low Covid-19 community levels if they have fewer than 10 new Covid-19 hospital admissions per 100,000 or less than 10% of staffed hospital beds occupied by Covid-19 patients on average in the past week.

Levels are medium if counties have 10 to nearly 20 new Covid-19 hospital admissions per 100,000 or between 10% and 14.9% of staffed hospital beds occupied by Covid-19 patients on average in the past week.

Levels are considered high if counties have 20 or more new Covid-19 hospital admissions per 100,000 or at least 15% of staffed hospital beds occupied by Covid-19 patients on average in the past week.

Counties with 200 or more new Covid-19 cases per 100,000 people in the past week are not considered to have low levels of Covid-19. They are considered medium if they have fewer than 10 new Covid-19 hospital admissions per 100,000 or less than 10% of staffed hospital beds occupied by Covid-19 patients on average in the past week. They are considered high if they have if they have 10 or more new Covid-19 hospital admissions per 100,000 or at least 10% of staffed hospital beds occupied by Covid-19 patients on average in the past week.

This new framework moves beyond just looking at cases and test positivity, to evaluate factors that reflect the severity of disease including hospitalizations and hospital capacity and helps to determine whether the level of Covid-19 and severe disease are low, medium or high in a community, CDC Director Dr. Rochelle Walensky told reporters during a telebriefing call Friday.

The Covid-19 community level we are releasing today will inform CDC recommendations on prevention measures, like masking, and CDC recommendations for layered prevention measures will depend on the Covid-19 level in the community, Walensky said. This updated approach focuses on directing our prevention efforts towards protecting people at high risk for severe illness and preventing hospitals and health care systems from being overwhelmed.

The update to CDC guidance comes at a time when daily Covid-19 cases in the United States have fallen to a tenth of what they were at their peak last month, according to data from Johns Hopkins University. The 90% drop from an average of more than 802,000 cases per day on January 15 to less than 75,000 currently happened over the course of about six weeks.

In recent weeks, some states seem to have already made this shift in focus from community transmission to hospitalizations. Many states have made plans to lift indoor or school mask mandates based on their own metrics: declining hospitalization rates and having a larger share of fully vaccinated residents than the national average.

The CDCs updated Covid-19 community metrics signal an important moment in the pandemic, Lori Tremmel Freeman, chief executive officer of the National Association of County and City Health Officials, told CNN on Friday.

I think that this is one of the long-awaited moments of the pandemic to hear of such a significant shift in how we view the data to identify the proper mitigation strategies, Freeman said.

An important moment during the pandemic in the sense that were able to now pivot to more of these community burden metrics that allow us to look at these mitigation strategies differently than we have perhaps before, Freeman said, adding that, looking ahead, I think we have to really watch the hospitalization data and identify ways to improve collection of data that allows us to account for individuals who come into the hospital with Covid versus for Covid.

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New CDC Covid-19 metrics drop strong mask recommendations for most of the country - CNN

COVID-19 has turned deadlier for Black Californians, who have the states lowest vaccination rate – ABC10.com KXTV

February 26, 2022

Californias African Americans are dying from COVID at a higher rate now.

CALIFORNIA, USA This story was originally published by CalMatters.

Deondray Moore sat in a plastic folding chair, rolled up his sleeve and got his first COVID-19 shot in the parking lot of Center of Hope Community Church in Oakland a week ago. He was the last in his family to get vaccinated after putting it off for more than a year, and only acquiesced because he wants to be in the delivery room when his son is born this summer.

My mom has been trying to get me vaccinated forever, since the (vaccines) came out, Moore said. My partner got it quick, and her kids got it as fast as they could. She wasnt playing around. She was like Dont miss out on the baby.

The 35-year-old Oakland native, an African American, knows multiple people who have contracted COVID-19 and died. Moore wears a mask and doesnt go out much. But hes suspicious of the vaccine and the way it was developed. I just dont trust the government, he said.

African Americans, who have alitany of historical reasons to mistrust public health officials and doctors, have the lowest vaccination rate in the state, at 55%.

COVID-19 has become deadlier for Black Californians since the widespread availability of vaccinations, and vaccine hesitancy could be among the reasons why. Other races, which have higher vaccination rates, have seen death rates rise, but not as dramatically.

A CalMatters analysis shows since last summer, the rate of Black Californians dying from COVID-19 has increased tenfold from one death per 100,000 people last July to 10.4 deaths this week. That surpasses Latinos and all races exceptPacific Islanders, who are dying at the rate of 14.7 per 100,000, according tostate data.

And while statewide deaths from COVID have declined in the past week, they have continued to rise for African Americans.

So far, 5,544 Black people have died from the virus in California.

Dr. Kim Rhoads, an associate professor of epidemiology at University of California, San Francisco, said she isnt surprised by the growing death rate among African Americans. Disparities arent new. They arent new to COVID, said Rhoads, who helped organize the community clinic where Moore got his shot.

For some Black residents, the disparity grew worse after vaccines became widely available last summer, according to astudy from UC Santa Cruz and UC San Francisco researchers.

Middle-aged Blacks make up a growing, disproportionate share of the Californians who died, while the proportion shrank for Latinos and others: In March 2021, Black people aged 40-64, who make up roughly 5% of all middle-aged Californians, accounted for 6% of COVID-19 deaths in that age group. But a few months later, their numbers skyrocketed, accounting for 21% by last July, according to the study.

In contrast, middle-aged Latinos accounted for 66% of all COVID-19 deaths at the beginning of March 2021, but then last July shrank to 30%, mirroring their proportion of all middle-aged Californians.

Lead researcher Alicia Riley said preliminary data through November shows continuing disparities.

So why did the vaccines apparently help Latinos but not Black Californians? Its possible that those who are most at risk of dying from the disease arent getting vaccinated. Younger African Americans also may not have been included in early vaccination campaigns or may have felt they werent at risk of severe illness or death.

Whats puzzling to me is that they have a really different story in terms of whos dying, said Riley, a UCSC assistant professor of global and community health. Are the people who were at risk of dying in the Latino community actually being reached with vaccination, whereas somehow thats not happening for Black Californians as effectively?

Experts say myriad other factors could also be driving the trend, including poverty, lack of insurance, distrust of the health care system and higher rates of health complications like diabetes or heart disease.

The increased share of deaths for Black Californians is a powerful sign of who was left behind when everyone else was kind of moving on out of the pandemic, Riley said.

The study did not find significant differences for other age groups, although state data suggests Black children fare worse than other races, too.

Black children in California are the second most likely to die from the virus among Californians younger than 18, with 1.2 deaths per 100,000 Black children. Pacific Islanders are twice as likely to die from COVID as Black children, while all other races have less than one COVID-19 death per 100,000 children.

The drivers for African American deaths are likely deeper than vaccination disparities.

Rhoads, who studies death disparities in Black cancer patients, said pre-existing health complications also arent entirely to blame. Structural factors like poor quality health care also likely contribute to higher death rates, she said. For instance, medical devices like the pulse oximeter, which is used to determine whether a patient needs supplemental oxygen,dont work well on dark skin.

If we just say comorbidities, then were blaming the victim number one and were washing our hands of any responsibility, Rhoads said.

Vaccine campaigns successful for some

Substantial gains have been made among Latinos, according to Rileys study. After bearing the brunt in the early stages, Latinos death rate dropped from nearly 25 deaths per 100,000 people in January 2021 to 1 death per 100,000 in July. Over the last month, theCalifornia Department of Public Health estimates 7.2 Latinos died of COVID per 100,000 people, lower than the statewide rate of 8 per 100,000.

Around June 2021 the percentage of fully vaccinated Latinos outstripped Blacks and Native Americans, leaving Blacks in last place. Only 57% of Latinos are fully vaccinated, but somehard-hit agricultural areas like Imperial County were quick to accept the vaccine and it has made a difference.

Eduardo Garcia, senior policy manager for the Latino Community Foundation, said high death rates among Latinos early in the pandemic galvanized local groups and clinics to dole out vaccines and combat misinformation.

Over 34,000 California Latinos have died since the beginning of the pandemic, Garcia said. It touched people close to home. I think that also created an impulse for people to get information from reliable sources and get the vaccine.

Rhoads said refocusing COVID-19 vaccination messaging on preventing deaths rather than infections is important for equity, particularly since getting her community to trust the vaccine has been harder.

Its about a historical relationship between Black people and public health and health care, Rhoads said. Instead of saying lack of trust, Im saying theres no relationship there, so there should be no expectation of trust.

That trust was further shaken last spring when the Food and Drug Administration warned of rare but severe side effects associated with the Johnson and Johnson vaccine. Rhoads said the number of people seeking vaccinations at her clinic dropped precipitously.

To help bridge the gap, Rhoads founded Umoja Health, a collective of community and faith-based organizations in the Bay Area, to make COVID-19 testing and vaccination easy and accessible for African Americans. They bring pop-up clinic supplies to churches, schools and neighborhoods where they know vaccination rates are low. It takes patience and continued effort, Rhoads said.

At Castlemont High School in Oakland, where the clinic frequently sets up shop, it was several weeks before many Black students trusted them enough to get the vaccine.

The Latino students came immediately, she said. But as weve been there over time, were starting to see more and more of the African American students come through, and then we started to see people bringing their parents.

Back to normal threatens Blacks and Pacific Islanders

Gov. Gavin Newsoms recent announcement that California would be moving into anew phase of the pandemic worries advocates and community health organizers like Rhoads.

The newstate action plan acknowledges continuing disparities when it comes to COVID-19 deaths and highlights money in Newsoms budget that includes $819 million to expand Medi-Cal to undocumented individuals next year, $1.7 billion to invest in a more diverse health care workforce over five years and$65 million to fund the creation of an office of community partnerships and strategic communication.

But the plan offers little in terms of immediate action to fix disparities, and includes no specific programs to help Black communities.

The state health department on Thursday announced new $27 million contracts would be awarded to more than 100 community-based health organizations to shore up vaccination efforts in underserved communities, including African American ones.

However, community advocates worry that rhetoric used by Newsom like turning the page on the pandemic will ultimately prevent groups that have never caught up from moving forward.

We still have growing death rates and case rates. How can we move forward in the pandemic when were still suffering? said Karla Thomas, policy director for theUCLA Native Hawaiian and Pacific Islander COVID-19 Data Policy Lab.

Throughout the pandemic, Pacific Islanders have beenhit the hardest by COVID-19. Their mortality rate is nearly twice that of the statewide rate and nearly six times higher than the lowest rate of 2.5 deaths per 100,000 people among those who identify as multi-racial.

While data suggests that Pacific Islanders are nearly 100% vaccinated, Thomas said there is reason to believe that the states numbers are inaccurate. At times that number has creeped above 100%. From a personal experience, Thomas said she is one of only two people in her 50-person Samoan church in San Bernardino that she knows is vaccinated. Its not uncommon for there to be more than two funerals a month in her community.

Im really concerned that were not taking an equitable approach to mitigate the pandemic among (Native Hawaiian and Pacific Islander) communities and other communities of color, Thomas said. She criticized the lifting of the states mask mandate on Feb. 15 and the governors endemic plan.

Rhoads echoed Thomas sentiments.

The pandemic is not over. Its not for people who arent vaccinated, who dont have regular health care, she said.

Last week Rhoads and more than 35 organizations sent a letter to the state health department in part criticizing the states inconsistent and confusing messaging on masking. The health departments initial criteria for lifting the indoor mask mandate included vaccination and infection rates that were unmet when the mandate expired.

Rhoads said instances like this erode public trust in government and scientific organizations, particularly among groups that placed little faith in the institutions to begin with.

In response, the department agreed to schedule a meeting between Rhoads and State Public Health Officer Dr. Tomas Aragon.

In a separate response to CalMatters, the state health department said vaccine equity was the north star of its efforts to reach marginalized communities, and that it would continue to partner with community organizations, ethnic media, translators and faith-based groups.

This work is ongoing, and closing the equity gap across all California communities remains a priority to the states vaccination efforts, the department said in a statement.

Nothing to be afraid of

In Oakland at the Umoja clinic last week, George Dowell, a 40-year-old African American, said he was getting his second vaccination dose because he didnt want to be left behind as more and more businesses require proof of vaccination for entry.

Dowell is among the age group experiencing higher death rates in Rileys study. He spent the past year watching vaccinated friends and family carefully for side effects before deciding to get the shot himself.

Social media and misinformation played a role in Dowells hesitation. I was listening to certain people, social media, instead of listening to myself and doing whats right, Dowell said.

Three weeks ago, he decided it was time. He found the Umoja clinic while driving around the neighborhood and got his first Pfizer shot. Dowell wanted to show his school-aged nieces and nephews that there was nothing to be afraid of as they became eligible for the vaccine.

Dowells 27-year-old son is also unvaccinated, and Dowell said he promised he would call to let him know how he feels after this second shot.

CALmatters.org is a nonprofit, nonpartisan media venture explaining California policies and politics.

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COVID-19 has turned deadlier for Black Californians, who have the states lowest vaccination rate - ABC10.com KXTV

COVID-19: Top news stories about the pandemic on 25 February | World Economic Forum – World Economic Forum

February 26, 2022

Confirmed cases of COVID-19 have passed 431.4 million globally, according to Johns Hopkins University. The number of confirmed deaths has now passed 5.92 million. More than 10.67 billion vaccination doses have been administered globally, according to Our World in Data.

Japan has announced that international travellers showing proof of a Johnson & Johnson COVID-19 vaccine will be allowed to enter the country and qualify for a shorter time in quarantine from next month. The Johnson & Johnson shot, which has not been approved in Japan, will join a list of three other vaccines that have been approved by regulators as sufficient for non-residents to enter, after a nearly two-year ban on such travellers.

The European health regulator has also recommended the approval of Moderna's COVID-19 vaccine for use in children aged 6-11.

Hong Kong SAR, China, has rolled out vaccine passports, requiring people aged 12 and above to have at least one COVID-19 jab. It comes as it reported a new record of daily COVID-19 infections.

China on Friday reported its highest daily count of COVID-19 cases arriving from outside the mainland in nearly two years, with infections mostly from Hong Kong as the financial hub grapples with a wave of infections.

Drugmaker Shionogi & Co has applied for approval to make and sell its oral COVID-19 treatment in Japan, the firm said on Friday.

Daily new confirmed COVID-19 cases per million people in selected countries.

Image: Our World in Data

The COVID Response Alliance to Social Entrepreneurs - soon to continue its work as the Global Alliance for Social Entrepreneurship - was launched in April 2020 in response to the devastating effects of the pandemic. Co-founded by the Schwab Foundation for Social Entrepreneurship together with Ashoka, Echoing Green, GHR Foundation, Skoll Foundation, and Yunus Social Business.

The Alliance provides a trusted community for the worlds leading corporations, investors, governments, intermediaries, academics, and media who share a commitment to social entrepreneurship and innovation.

Since its inception, it has since grown to become the largest multi-stakeholder coalition in the social enterprise sector: its 90+ members collectively support over 100,000 social entrepreneurs across the world. These entrepreneurs, in turn, have a direct or indirect impact on the lives of an estimated 2 billion people.

Together, they work to (i) mobilize support for social entrepreneurs and their agendas; (ii) take action on urgent global agendas using the power of social entrepreneurship, and (iii) share insights from the sector so that social entrepreneurs can flourish and lead the way in shaping an inclusive, just and sustainable world.

The Alliance works closely together with member organizations Echoing Green and GHR Foundation, as well as the Centre for the New Economy and Society on the roll out of its 2022 roadmap (soon to be announced).

Health Canada has approved Medicago's COVID-19 vaccine, making it the first authorization of the plant-based shot anywhere in the world.

The two-dose vaccine, which uses an adjuvant from GlaxoSmithKline to boost efficacy, has been approved for people aged 18 to 64, the health agency said.

The shot was 75.3% effective against the Delta variant of the virus in a late-stage study.

The vaccine also showed overall efficacy of 71% against all variants of the coronavirus except Omicron, which was not in circulation when the study was underway.

The shot is based on a technology that uses plants to produce virus-like particles that mimic the structure of the coronavirus but contain no genetic material from it.

The Omicron BA.2 sub-variant of COVID-19 appears to be more infectious than the original BA.1 sub-variant, but does not cause more severe disease, the head of Africa's top public health body said yesterday citing data from South Africa.

"South Africa is reporting that it is more transmissible than the BA.1 variant, but interestingly and very encouragingly the severity seems to be the same," said Dr John Nkengasong, Director of the Africa Centres for Disease Control and Prevention (CDC).

South Africa was one of the first countries to detect the Omicron variant of COVID-19, which has since swept around the globe and become dominant in most places.

Although South Africa is well over the peak of its Omicron wave, its daily number of new infections has stabilised at around 3,000 per day, a higher level than that seen at the tail end of previous waves of COVID-19 infections.

Nkengasong said the trend may be linked to the BA.2 sub-variant, but did not elaborate.

Written by

Joe Myers, Writer, Formative Content

The views expressed in this article are those of the author alone and not the World Economic Forum.

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COVID-19: Top news stories about the pandemic on 25 February | World Economic Forum - World Economic Forum

Specialized interferon action in COVID-19 – pnas.org

February 26, 2022

The impact of interferon (IFN) signaling on the course of COVID-19 pathology has been the subject of much investigation, with both protective and deleterious effects being reported. There are three major types of IFN signaling defined by the transmembrane receptors and downstream signaling kinases engaged (1). Type I signaling involves IFN-, -, -, -, and - IFNs, the IFNAR1 and IFNAR2 receptors, and the downstream kinases JAK1 and TYK2. Type II signaling involves the IFNG, the IFNGR1 and IFNGR2 receptors, and the downstream kinases JAK1 and JAK2. Type III IFN signaling involves the IFNs, the IFNLR1 and IL10RB receptors, and the JAK1 and TYK2 kinases. However, this broad classification does not capture the biological complexity driven by subtypes acting through the same receptors. This is most evident by the differential effects of -subtypes versus IFNB1 within type I signaling (1). Even within -subtypes there is significant heterogeneity in cellular source, site of action, and downstream effects (1).

In the context of SARS-CoV-2 infections, the protective effects of IFN signaling are demonstrated by studies showing that severe COVID-19 is associated with decreased IFN signaling (24), the presence of autoantibodies blocking the action of specific IFNs (59), and genetic variants that impair IFN signaling (10, 11). In the nasal mucosa, autoantibodies targeting type I IFNs correlate with high viral load and severe COVID-19 (8). In the upper respiratory tract, high levels of type III IFNs, and to a lesser extent type I IFNs, are associated with reduced disease risk or severity (12). In bronchial aspirates, increased levels of type III IFNs correlate with lower viral load and faster clearance (3). However, type I IFN signaling has been established as a driver of pathology in mouse models of both SARS-CoV-1 and SARS-CoV-2 infections (13, 14), and type I and III IFNs have been implicated in disruption of lung barrier function and increased susceptibility to secondary bacterial infections in mice (15, 16). This duality in the role of IFN signaling could be explained in part by an untuned viral response during SARS-CoV-2 infections, whereby antiviral IFN signaling is delayed relative to proinflammatory signaling (3). Furthermore, the impacts of IFN signaling could vary at different sites, even along the upper versus lower respiratory tracts (12). This complexity has fueled the design of seemingly contradictory clinical trials using either IFNs (17) or agents that block IFN signaling, such as JAK inhibitors (18). Thus, it is possible that context-dependent variations in IFN signaling may attenuate or exacerbate COVID-19 pathology. Indeed, retrospective analysis of IFN-2b treatment in COVID-19 showed that early administration was associated with reduced mortality, whereas late administration was associated with increased mortality (19).

Within this context, we report here a multiomics analysis of systemic IFN signaling in hospitalized COVID-19 patients, including a comprehensive examination of the whole-blood transcriptome, plasma proteome, antiSARS-CoV-2 antibodies, peripheral immune cell repertoire, plasma and red blood cell (RBC) metabolomes, as well as immune and clinical markers of disease risk and severity in relationship to circulating levels of 12 different IFNs. These analyses revealed heterogeneity in the relationship between levels of each IFN and key molecular, cellular, metabolic, and physiological processes relevant to COVID-19 pathophysiology. These results indicate that modulation of IFN signaling in the clinic, with either agonists or antagonists, must take into account the endogenous state of the IFN milieu at the time of intervention, and that subtype-specific effects are to be expected.

We analyzed the datasets generated by the COVIDome Project (covidome.org) to investigate IFN signaling in hospitalized COVID-19 patients. The COVIDome Project datasets have been previously described (20, 21) and include matched whole-blood transcriptomes, plasma proteomics via complementary SOMAscan and mass spectrometry (MS) assays, measurement of 82 immune factors by multiplexed immunoassays, SARS-CoV-2 seroconversion assays, immune cell profiling by mass cytometry, plasma and RBC metabolomics, as well as annotated clinical metadata. The cohort analyzed in this study consists of 73 hospitalized COVID-19 patients with mild-to-moderate disease at the time of research blood draw and 32 controls (SI Appendix, SI Extended Methods; see Dataset S1 for cohort characteristics).

To monitor IFN signaling, we first analyzed the transcriptome dataset. DESeq2 analysis, adjusting for age and sex as covariates, identified 2,299 genes differentially expressed in the blood of COVID-19 patients (Fig. 1A and Dataset S2). Gene set enrichment analysis (GSEA) identified the Hallmark Interferon Alpha and Gamma Response gene sets as the most significant positively enriched signatures in COVID-19 patients (Fig. 1B and Dataset S3). To assess interindividual variation in expression of these IFN gene signatures, we calculated z-scorebased IFN- and - scores for each sample, showing that COVID-19 patients display significantly increased yet variable IFN scores relative to controls (Fig. 1C and SI Appendix, Fig. S1A). In order to assess the degree to which this variability in IFN signaling is associated with the levels of circulating IFNs, we mined the SOMAscan proteomics and multiplexed immunoassay datasets (Meso Scale Discovery, MSD), which collectively measured a total of 17 different IFNs. To validate the reagents in these two platforms, we spiked single (SOMAscan) or multiple concentrations (MSD) of commercially available recombinant IFNs into a pooled plasma reference sample (SI Appendix, SI Extended Methods). We discarded five SOMAscan measurements (IFNA5, IFNA8, IFNA14, IFNA21, IFNL2) due to lack of sensitivity, and relabeled three measurements based on apparent cross-reactivity (IFNA4/16, IFN7/17/21, IFNL3/2) (SI Appendix, Fig. S1B). When the same IFN was measured by both platforms, we preferred the MSD measurement, which is quantified against a standard curve (SI Appendix, Fig. S1C). This exercise allowed us to focus on measurements for 12 IFNs in our subsequent analyses: IFNA1, IFNA2, IFNA4/16, IFNA6, IFNA7/17/21, IFNA10, IFNA16, IFNB1, IFNG, IFNL1, INFL3/2, and IFNW1 (SI Appendix, Fig. S1 BD).

IFN signaling at the whole-blood transcriptome level correlates with a subset of IFNs. (A) Volcano plot for differential mRNA expression analysis by COVID-19 status, adjusted for age and sex. Horizontal dashed line indicates a false-discovery rate (FDR) 10% for negative binomial Wald test; numbers above plot indicate significant genes. ISGs are highlighted in green. (B) Bar plot of top 10 Hallmark gene sets as ranked by absolute normalized enrichment score (NES) from GSEA. Bar color represents NES; bar length represents -log10(q-value). (C) RNA-based IFN- scores by COVID-19 status. Data are presented as a modified sina plot with box indicating median and interquartile range; number above bracket is the q-value for MannWhitney U test. (D) Ranked heatmap representing correlations between RNA-based IFN- scores and plasma levels of IFNs. Values are Spearman correlation coefficients (rho); asterisks indicate significant correlations (10% FDR). (E) Sina plots comparing abundance for the indicated IFNs by COVID-19 status. Data are presented as modified sina plots with boxes indicating median and interquartile range. Numbers above brackets are q-values for MannWhitney U tests. (F) Scatter plots showing the relationship between RNA-based IFN- score and plasma abundance of IFNs in COVID-19 patients. Points are colored by density; blue lines represent linear model fit with 95% confidence intervals in gray. (G) Scatter plots showing the relationship between ISG mRNA levels and plasma abundance of IFNs in COVID-19 patients. (H) Heatmap representing enrichment of Hallmark gene sets among Spearman correlations between mRNA levels and plasma levels of IFNs. Values displayed are NES from GSEA; asterisks indicate significant enrichment (10% FDR); columns and rows are grouped by hierarchical clustering. See also SI Appendix, Figs. S1 and S2. n.s., not significant.

We next determined Spearman correlations between the RNA-based IFN- scores and levels of these 12 IFNs (Fig. 1D). Interestingly, the correlations were highly variable, with four IFNs lacking significant associations with the IFN- score (IFNB1, IFNA16, IFNW1, and IFNA6). This result is clearly illustrated by the type I subtypes IFNA2 and IFNA6, which are the most and least correlated with IFN- scores, respectively. Although both subtypes are significantly up-regulated in the plasma of COVID-19 patients (Fig. 1E), only IFNA2 levels correlate with the IFN- scores (Fig. 1F) and with mRNA expression of well recognized IFN-inducible genes (ISGs), such as ISG15 and OAS2 (Fig. 1G). Repeating this analysis for IFN- scores produced a similar rank of correlations (SI Appendix, Fig. S1A).

To explore this phenomenon more deeply, we completed a comprehensive analysis of gene expression signatures in the whole-blood transcriptome associated with varying plasma levels of the 12 IFNs, using only data from COVID-19 patients. Toward this end, we defined Spearman correlations between IFNs and 15,000+ mRNAs detected, which identified thousands of significant correlations, with great variability across IFNs (SI Appendix, Fig. S2A and Dataset S4). We then analyzed the ranked correlations for each IFN using GSEA to identify known gene sets with significant enrichment among positive or negative correlations (Fig. 1H and Dataset S5). This analysis showed that the top gene signatures positively associated with eight of the IFNs are indeed the IFN- and - responses, followed by related inflammatory and immune pathways. In contrast, for the other four IFNs (IFNB1, IFNA6, IFNW1, and IFNA16), the top signatures enriched in the positive correlations are related to cell proliferation, such as G2M checkpoint, E2F targets, and MYC targets (Fig. 1H). In fact, some of these IFNs show negative correlations with the IFN- and - responses (Fig. 1H). Again, this differential behavior is illustrated by IFNA2 and IFNA6. Whereas mRNAs positively associated with IFNA2 show clear enrichment of the IFN Alpha Response gene set, these same mRNAs are negatively correlated with IFNA6 levels (e.g., ISG15) (SI Appendix, Fig. S2B).

Altogether, these results suggest functional specialization among circulating IFNs, whereby only specific IFNs associate with the IFN transcriptional response of circulating immune cells.

Next, we investigated the proteomic signatures associated with each IFN. Using linear regression, adjusting for age and sex, we identified 963 epitopes measured by SOMAscan differentially abundant in the plasma of COVID-19 patients (Fig. 2A and Dataset S6). GSEA identified Hallmark IFN alpha and gamma responses as the top proteomic signatures induced in COVID-19 (Fig. 2B and Dataset S7). As for the transcriptome, we calculated protein-based IFN- and - scores for each sample, which showed significantly higher yet variable IFN scores among COVID-19 patients (Fig. 2C and SI Appendix, Fig. S3A). Notably, protein-based IFN scores may inform about the organismal IFN response, not just that of circulating immune cells driving the whole-blood transcriptome IFN signature, as multiple organs and tissues could contribute to secretion of IFN-related proteins.

IFN signaling at the proteome level correlates with features of COVID-19 pathophysiology. (A) Volcano plot for linear regression analysis of SOMAscan proteomics data by COVID-19 status, adjusted for age and sex. Horizontal dashed line indicates an FDR threshold of 10% (q < 0.1); numbers above plot indicate significant proteins. Proteins encoded by ISGs are highlighted in green. (B) Bar plot of top 10 Hallmark gene sets as ranked by absolute NES from GSEA. Bar color represents NES; bar length represents -log10(q-value). (C) Protein-based IFN- scores by COVID-19 status. Data are presented as a modified sina plot with box indicating median and interquartile range. (D) Ranked heatmap representing correlations between protein-based IFN- scores and plasma levels of each IFN. Values displayed are Spearman correlation coefficients (rho); asterisks indicate significant correlations (10% FDR). (E) Heatmap representing enrichment of Hallmark gene sets among Spearman correlations between plasma levels of proteins measured by SOMAscan versus IFNs. Values displayed are NES from GSEA; asterisks indicate significant enrichment (10% FDR); columns and rows are grouped by hierarchical clustering. (FI) Scatter plots comparing relationships between plasma proteins and IFNs in COVID-19 patients. Points are colored by density; blue lines represent linear model fit with 95% confidence intervals in gray. See also SI Appendix, Figs. S3 and S4. n.s., not significant.

We then defined correlations between the 12 IFNs and the protein-based IFN scores, which revealed both similarities and differences relative to the RNA-based IFN scores (Fig. 2D and SI Appendix, Fig. S3A). Whereas IFNA2 and IFNG remained the most correlated with the protein-based IFN- and - scores, other IFNs behaved differently (Fig. 2D and SI Appendix, Fig. S3A). For example, IFNA10, which was significantly correlated with the RNA-based IFN scores, was not so with the protein-based scores. In contrast, IFNA6 and IFNB1 ranked higher in their association with the protein-based scores (Figs. 1D and 2D and SI Appendix, Figs. S1A and S3A). We then defined Spearman correlations between the 12 IFNs and 4,800+ epitopes measured by SOMAscan and analyzed the correlation results with GSEA (Fig. 2E, SI Appendix, Fig. S3B, and Datasets S8 and S9). Interestingly, some IFNs with weak transcriptome signatures present strong proteomic signatures. For example, IFNA6 and IFNB1, which show very weak correlations with mRNAs (SI Appendix, Fig. S1A), are among the IFNs with the most numerous significant associations with circulating proteins (SI Appendix, Fig. S3B). This suggests that whereas IFNA6 and IFNB1 may not contribute to the IFN transcriptional response of circulating immune cells, they may nonetheless contribute to IFN responses in tissues and organs contributing to the protein-based plasma IFN signature. This is illustrated by the behavior of CXCL11, a canonical ISG, which is significantly correlated at the protein level with IFNA2, IFNA6, and IFNB1 (SI Appendix, Fig. S4A). Additionally, IFNs often display highly dissimilar, even opposite, relationships to certain proteomics signatures, as illustrated by the PI3K/AKT/mTOR signature (Fig. 2E; compare correlations to HRAS for IFNA1, IFNA6, and IFNB1 in SI Appendix, Fig. S4B).

To probe further into this phenomenon, we examined the top five positively and negatively correlated epitopes for each IFN using unsupervised clustering analysis, which revealed many specialized relationships of relevance to COVID-19 pathophysiology (SI Appendix, Fig. S4C). For example, several chemokines involved in immune control showed differential associations, such as CXCL10 (compare IFNG to IFNW1 in Fig. 2F), CX3CL1 (compare IFNA10 to IFNA6 in Fig. 2G), CCL7 (compare IFNA2 to IFNA16 in SI Appendix, Fig. S4D), and CCL5 (compare IFNB1 to IFNA10 in SI Appendix, Fig. S4E). Notably, the top positive correlations for IFNB1 are dominated by proteins stored in -granules of platelets, such as PPBP (multiple SOMAscan aptamers), PDGFA, PDGFD, and PF4 (SI Appendix, Fig. S4C and Dataset S8). These markers of platelet degranulation are also associated, albeit to a lesser degree, with IFNA6, but not so with other IFNs (Fig. 2H, compare IFNB1 to IFNA10, and SI Appendix, Fig. S4C). This suggests that IFNB1 production is associated with platelet activation, which could be interpreted as a sign of endothelial damage at sites producing IFNB1. A subset of IFNs showed strong associations with complement factors, such as C1QC (Fig. 2I, compare IFNA2 to IFNB1, and SI Appendix, Fig. S4C). The top correlated epitope for IFNA10 is TRIL, a component of the Toll-like receptor-4 complex, but this association was weaker for many other IFNs (SI Appendix, Fig. S4C, compare IFNA10 to IFNA6 in SI Appendix, Fig. S4F). KIR3DL2 and KIR3DS1, two killer cell immunoglobulin (Ig)-like receptors expressed by natural killer (NK) cells and subtypes of T cells, were strongly correlated with a subset of IFNs, most prominently IFNA6 (SI Appendix, Fig. S4C, compare IFNA6 to IFNA10 in SI Appendix, Fig. S4G). OLFM4 (Olfactomedin 4), a protein selectively expressed in inflamed colonic epithelium, was strongly associated with IFNA4/16, but not other IFNs (SI Appendix, Fig. S4C, compare IFNA4/16 versus IFNA10 in SI Appendix, Fig. S4H).

Altogether, these results reveal that circulating levels of different IFNs associate with proteomic signatures indicative of diverse pathophysiological processes, such as tissue-specific inflammation, complement activation, and endothelial damage.

Up to this point, our analyses indicate specialized IFN action in the context of SARS-CoV-2 infection, which could be explained by several nonmutually exclusive potential mechanisms, including tissue-specific expression of IFNs (22), variable timing of IFN production during the course of viral infection (23), self-amplification of certain IFNs via positive feedback (24, 25), differential turnover of IFNs in circulation (26), or blockade of specific IFN subtype production by SARS-CoV-2 proteins (27). Remarkably, this specialization was different when analyzing the transcriptome versus proteome. To investigate this phenomenon further, we stimulated peripheral blood mononuclear cells (PBMCs) from uninfected donors with IFNA2 and IFNB1, two type I subtypes that show distinct relationships with the transcriptome of COVID-19 patients, and analyzed their impact on the PBMC transcriptome at 18 h posttreatment (SI Appendix, SI Extended Methods) (28). We identified 2,179 RNAs significantly induced by at least one subtype, with 65.6% being induced by both IFNs (core ISGs), 7.4% of them being significantly induced by IFNA2 only (173 genes), and 26.7% by IFNB1 only (583 genes) (Fig. 3A). Examples of core ISGs are ISG15, IFIT1, and LAG3; examples of IFNA2-specific ISGs are AGX2, DLGAP5, and NDUFVP2; and examples of IFNB1-specific ISGs are GJA3, YPEL5P2, and CIB2 (Fig. 3B). Notably, 25% of all mRNAs induced in the whole-blood transcriptome of COVID-19 patients correspond to core ISGs identified in PBMCs (Fig. 3C) and, at the protein level, 17% of proteins elevated in COVID-19 patients are encoded by core ISGs (Fig. 3D). Thus, type I IFN is a major contributor to the transcriptome and proteome changes observed in COVID-19. However, analysis of correlations between circulating levels of the two subtypes indicates that only IFNA2 levels are significantly correlated with mRNA expression of core ISGs (Fig. 3E). Of the core ISG mRNAs detected in the whole-blood transcriptome, 45% have significant positive correlations with IFNA2, whereas none have significant correlations with IFNB1. In contrast, at the protein level, both subtypes display numerous significant correlations with proteins encoded by core ISGs (Fig. 3G).

The cellular action of IFNA2 and IFNB1 does not explain their differential biosignatures in COVID-19. (A) Scatter plot comparing fold-changes for IFNA2- and IFNB1-stimulated genes in PBMCs treated ex vivo. (B) Heatmap representing differential expression of selected genes from each class in A. Values displayed are fold-changes for stimulation with IFNA2/baseline and IFNB1/baseline; asterisks indicate significant differences over baseline (10% FDR); rows are grouped by hierarchical clustering. (C and D) Pie charts displaying the relative fraction of mRNAs (C) or proteins (D) up-regulated in COVID-19 patients in each class from A. Absolute numbers are indicated in legend. (E) Spearman correlation score (rho) distributions for core mRNAs against plasma levels of IFNA2 and IFNB1. Data are presented as a modified sina plot with boxes indicating median and interquartile range with number above bracket indicating the q-value for MannWhitney U test (Left) and scatter plots with points colored by density (Right). (F) Spearman correlation score (rho) distributions for core proteins detected by SOMAscan against plasma levels of IFNA2 and IFNB1. Data are presented as a modified sina plot with boxes indicating median and interquartile range with number above bracket indicating the q-value for MannWhitney U test (Left) and scatter plot with points colored by density (Right). n.s., not significant.

Altogether, these results indicate that the differential relationship between ISG expression in circulating blood cells and levels of IFNA2 and IFNB1 is not necessarily a function of their ability to induce transcription of core ISGs, but rather the consequence of other mechanisms acting at the organismal level.

Next, we analyzed correlations between the 12 IFNs and plasma proteins measured by our MS platform, which is complementary to the SOMAscan dataset as it detects many abundant proteins for which SOMAmer reagents are not available, including various Igs. Using linear regression, adjusting for age and sex, we identified 70 proteins differentially abundant in plasma of COVID-19 patients (SI Appendix, Fig. S5A and Dataset S11). Of the 28 significantly elevated proteins, 17 of them are Igs (labeled green in SI Appendix, Fig. S5A), potentially indicative of seroconversion in some patients. We then calculated Spearman correlations between IFNs and all proteins detected by MS (SI Appendix, Fig. S5B and Dataset S12) and visualized the top five positively and negatively correlated proteins for each IFN via unsupervised hierarchical clustering (SI Appendix, Fig. S6A). This analysis confirmed some observations made with the SOMAscan dataset, but also revealed several new associations. First, a subset of IFNs associates strongly with IFN-inducible proteins, such as B2M (compare IFNA7/17/21 to IFNA6 in Fig. 4A), and LGALS3BP (compare IFNA4/16 to IFNA6 in SI Appendix, Fig. S6B). Second, many of the same IFNs associate with elevated levels of complement subunits, such as C2 (compare IFNL1 to IFNA6 in Fig. 4B) and C9 (compare IFNA2 to IFNA6 in SI Appendix, Fig. S6C). Third, several key regulators of coagulation and fibrinolysis were significantly associated with specific IFNs. Salient examples include HABP2 (compare IFNA2 to IFNB1 in Fig. 4C), FGA (compare IFNL1 to IFNA16 in SI Appendix, Fig. S6D), F13B (compare IFNA10 to IFNA6 in SI Appendix, Fig. S6E), and PROZ (compare IFNW1 to IFNB1 in SI Appendix, Fig. S6F). Fourth, very distinctly, IFNB1and to a lesser degree IFNA6associate positively with markers of platelet degranulation, such as PF4, THBS1, PPBP, MMRN1, and SPARC (Fig. 4D, compare IFNB1 to IFNA10, and SI Appendix, Fig. S6A). Finally, IFNs have distinct relationships to a subset of Ig heavy- and light-chain variable domain peptides that were associated positively or negatively with the levels of specific IFNs (compare IFNA2 to IFNA6 in Fig. 4E and IFNA1 to IFNB1 in Fig. 4F). This result could be explained by varying levels of IFNs upon seroconversion (20).

Differential association of IFNs with seroconversion. (AF) Scatter plots comparing relationships between plasma proteins measured by MS proteomics and IFNs in COVID-19 patients. Points are colored by density; blue lines represent linear model fit with 95% confidence intervals in gray. (G) Heatmap representing correlations between IFNs and plasma levels of Igs measured by MS proteomics (Upper), or antibody reactivity against SARS-CoV-2 measured by immunoassays (Lower). Values displayed are Spearman correlation scores (rho); asterisks indicate significant correlations (10% FDR); columns and rows are grouped by hierarchical clustering. (H) Scatter plots comparing relationships between plasma antibody reactivity against SARS-CoV-2 S1 RBD region and IFNA2/B1 in COVID-19 patients. Points are colored by density; blue lines represent linear model fit with 95% confidence intervals in gray. See also SI Appendix, Figs. S5 and S6. n.s., not significant.

To investigate in detail the interplay between specific IFNs, Ig levels, and seroconversion, we examined correlations between the IFNs and all Ig variable domains detected by MS proteomics, as well as seroconversion assays used to detect IgGs against SARS-CoV-2 peptides (S1 full-length, spike; S1 N terminus; and S1 receptor binding domain [RBD]; nucleocapsid) (Fig. 4G). This analysis revealed that a subset of IFNs is strongly anticorrelated with seroconversion (e.g., compare IFNA2 to IFNB1 in Fig. 4H) and specific Ig variable domains that have been previously found enriched in the bloodstream of COVID-19 patients, such as IGHV1-24 and IGLV3-1 (29). This observation could be interpreted as early production of some IFNs with subsequent declines upon seroconversion (e.g., IFNA2, IFNG), followed by later production of other IFNs (e.g., IFNA6, IFNB1), potentially from sites where SARS-CoV-2 evades humoral neutralization. Overall, these results further support the notion of differential action of IFNs in COVID-19 pathophysiology, suggesting a temporal sequence of IFN production before and after seroconversion.

Next, we investigated the relationship between plasma levels of IFNs and circulating immune cells analyzed by mass cytometry. First, we employed the unsupervised clustering algorithm PhenoGraph (30) to identify distinct subpopulations of immune cells, combined with t-stochastic neighbor embedding (t-SNE) dimensionality reduction to aid in visualization (31), resulting in identification of 30 clusters (Fig. 5A and SI Appendix, Fig. S7 A and B). We then identified clusters whose relative frequency among all live cells was significantly associated with varying IFN levels, using -regression, with adjustment for age and sex (Fig. 5A, SI Appendix, Fig. S7 C and D, and Dataset S13). This analysis revealed that multiple IFNs are significantly associated with increased abundance of clusters enriched for T cells and NK cells, while also displaying negative associations with clusters enriched for B cells (Fig. 5A and SI Appendix, Fig. S7 C and D). For example, IFNA1 is positively associated with clusters 9 (CD8+ T cells) and 30 (CD56+ NK cells) and negatively associated with cluster 15 (switched memory B cells) (SI Appendix, Fig. S7E).

Differential association of IFNs with immune cell signatures. (A) t-SNE plots of 69,000 cells analyzed by mass cytometry from 69 COVID-19 patients (1,000 cells each). Leftmost panel is colored by major cell lineages; all other panels have cells within each PhenoGraph cluster (as shown in SI Appendix, Fig. S7A) colored by the fold-change in cluster proportion among live cells per SD of abundance for the indicated IFN, as determined by -regression analysis, adjusting for age and sex; numbers indicate clusters with significant associations with IFN abundance (10% FDR). (B) Heatmap representing relationships between IFNs and gated subpopulation proportions among live cells, as determined by -regression analysis. Values displayed are fold-change in cluster proportion among live cells per SD of IFN abundance; asterisks indicate significant associations (10% FDR); columns and rows are grouped by hierarchical clustering. (CF) Scatter plots comparing relationships between gated subpopulation proportions among live cells and IFNs in COVID-19 patients. Points are colored by density; blue lines represent -regression model fit with 95% confidence intervals in gray. See also SI Appendix, Figs. S7 and S8. n.s., not significant.

To further these observations in relationship to known immune cell subpopulations, we analyzed associations between the IFNs and 50+ immune cell types defined by traditional gating based on marker expression (Fig. 5B, SI Appendix, Fig. S8A, and Datasets S14 and S15). This exercise confirmed specialized relationships between some IFNs and specific lymphoid cell subsets. For example, among CD4+ T cells, the T-helper 1 (Th1) subset displays significant positive associations only with IFNA1, IFNA2, IFNA7/17/21, IFNA10, IFNG, and IFNL3/2 (Fig. 5B, compare IFNA10 to IFNA16 in Fig. 5C). This pattern was also apparent for many, but certainly not all, T cell subsets (Fig. 5B). Similarly, NK CD56bright cells also showed differential positive relationships with IFNs, with an overall pattern similar to that of key T cell subsets (compare IFNA2 to IFNA16 in Fig. 5D). Notably, this analysis also revealed significant positive associations between specific IFNs and plasmacytoid dendritic cells (DCs), which are strong producers of IFNs during viral infections (compare IFNA10 to IFNA16 in Fig. 5E). Many IFNs positively associated with CD4+ T cell subsets were negatively associated with B cell subsets, while IFNA6 displays the opposite relationship (Fig. 5B, compare IFNA10 versus IFNA6 in Fig. 5F). These differential associations could be interpreted as a transition from T cell-driven responses prior to seroconversion, followed by B cell activation and differentiation toward antibody-producing plasmablasts during seroconversion, along with decreased production of a specific subset of IFNs.

Altogether, these results suggest a temporal sequence of IFN production in coordination with changes in the peripheral immune cell compartment. An overview of salient IFNs associations along the paths of T cell and B cell activation and differentiation is shown in SI Appendix, Fig. S8B.

Next, we investigated metabolic signatures associated with varying levels of IFNs, calculating Spearman correlations for detected metabolites in plasma and RBC samples against each of the IFNs (SI Appendix, Fig. S9 and Datasets S16 and S17). In plasma, significant positive correlations were observed between the tryptophan/indole pathway metabolites kynurenine and 5-hydroxyindoleacetate and IFNG, but not other IFNs (Fig. 6A, compare IFNG to IFNA16 in Fig. 6B). In RBCs, kynurenine pathway metabolites showed a strong positive association with IFNG, as well as IFNA7/17/21 (SI Appendix, Fig. S10 A and B). Activation of the kynurenine pathway has documented in COVID-19 (32), and kynurenine production can be stimulated by induction of IDO1, an ISG downstream of all three major types of IFN signaling (33). Therefore, it is interesting that this pathway is preferentially associated with IFNG in COVID-19.

Differential metabolic signatures associated with IFNs. (A) Heatmap representing correlations between IFNs and plasma metabolites. Values displayed are Spearman correlation scores (rho); asterisks indicate significant correlations (10% FDR); columns and rows are grouped by hierarchical clustering. (BE) Scatter plots comparing relationships between select metabolites and IFNs in COVID-19 patients. Points are colored by density; blue lines represent linear model fit with 95% confidence intervals in gray. See also SI Appendix, Figs. S9 and S10. n.s., not significant.

Plasma levels of IFNA2 showed significant positive correlations with the markers of oxidative stress glutathione disulfide and 5-oxoproline, a byproduct of the -glutamyl cycle (Fig. 6A, compare IFNA2 to IFNW1 in SI Appendix, Fig. S10C), and negatively associated with markers of endothelial dysfunction and nitric oxide signaling (arginine, citrulline) (Fig. 6A; compare IFNA2 to IFNW1 in SI Appendix, Fig. S10D). In RBCs, IFNA2 once again had strong positive correlations with several markers of oxidative stress (5-oxoproline) or pentose phosphate pathway activation (sedoheptulose phosphate) (SI Appendix, Fig. S10 A and E), which is required in RBCs to generate reducing equivalent (NADPH) for recycling oxidized glutathione and other NADPH-dependent antioxidant enzymes. IFNA2 levels also positively correlated with fatty acid mobilization in RBCs (SI Appendix, Fig. S10A), likely a result of the activity of peroxiredoxin 6 or phospholipase A2 activity on complex lipids to fuel fatty acid release in the bloodstream to sustain viral capsid formation (34). Of note, among the positive correlates to IFNA2 levels in the fatty acid compartment, we observed only saturated (octanoic, dodecanoic, hexadecanoic, octadecanoic) or monounsaturated fatty acids (tetradecenoic, hexadecenoic, octadecenoic) (compare IFNA2 to IFNB1 in SI Appendix, Fig. S10F), suggestive of limited fatty acid desaturase activation despite the stress induced by the viral infection (35). Several ATP precursors/breakdown products (AMP and adenine) positively correlated with IFNA2 in RBCs, as did pyruvate, phosphate and diphosphate, all suggestive of altered glycolysis and overall energetics associated with IFNA2 signaling (SI Appendix, Fig. S10A). IFNA2 also negatively correlated with several amino acids in RBCs, including the antioxidants taurine, arginine, threonine and methionine, critical for RBC redox damage repair in the face of the incapacity to synthesize new proteins (SI Appendix, Fig. S10A) (36).

Plasma IFNL1 significantly correlated with several glycolytic metabolites (e.g., pyruvate) (compare IFNL1 to IFNA1 in Fig. 6C), as well as short-chain fatty acids hexanoate and heptanoate, potentially indicative of dysregulation of mitochondrial metabolism in patients with high IFNL1. In RBCs, IFNL1 levels showed positive correlations with the levels of inosine diphosphate (IDP) (compare IFNL1 to IFNA6 in SI Appendix, Fig. S10G) and negative correlations with carnitine and acetylcarnitine, potentially suggestive of RBC deformability issues (37) as a function of IFNL1 signaling.

Plasma IFNA7 and IFNA10 (and to a lesser extent IFNA1 and IFNA2) were positively associated with a cluster of acylcarnitines (including octenoyl, dodecanoyl, dodecenoyl, hexadecenoyl-carnitine) (compare IFNA10 to IFNA6 in Fig. 6D), suggesting an association between these IFNs and altered fatty acid oxidation. These data are relevant in light of the role of acylcarnitines in coagulation and the dysregulation of coagulation cascades in COVID-19 (38).

Plasma levels of IFNB1 showed a strong negative correlation with metabolites tied to the nitric oxide pathway (citrulline), as well as other amine group donors (glutamine, serine) or oxidant stress-related metabolites (carnosine, cystine). On the other hand, IFNB1 positively correlated with the plasma levels of glutathione and spermidine (antioxidant metabolites), succinate (marker of mitochondrial dysfunction), and purinergic agonists involved in vasodilatory/hypoxic responses (ADP and AMP), perhaps produced by hemolytic events (compare IFNB1 to IFNA10 in Fig. 6E and SI Appendix, Fig. S10 H and I).

Altogether, these results not only confirm metabolic signatures previously associated with IFN signaling (e.g., activation of the kynurenine pathway), but also reveal unexpected associations between specific IFNs and diverse metabolic processes dysregulated in COVID-19.

Next, we aimed to define the relationship between IFNs and available clinical variables, using linear regression with adjustment for age and sex. Among COVID-19 patients, none of the IFNs was significantly different by age or sex (Fig. 7A and Dataset S18). Although all samples in this study were collected when patients were presenting mild-to-moderate symptomology, some patients were subsequently admitted to an intensive care unit (ICU) or required higher O2 supplementation. None of the IFNs was significantly different by ICU status (i.e., never ICU vs. ever ICU) or O2 requirement (high vs. low) (Methods). However, seven IFNs showed significant decreases with increasing time between hospital admission and research blood draw (Fig. 7 A and B), all of which were negatively correlated with seroconversion values (Fig. 4B). This indicates that whereas specific IFNs are produced earlier in the course of symptomology, prior to seroconversion, others are produced later in the course of the disease, a notion supported by longitudinal analyses (3, 8, 39, 40).

Differential association of IFNs with clinical variables and markers of prognosis in COVID-19. (A) Heatmaps summarizing linear regression analysis of plasma IFNs abundance against age (continuous), sex (males/females), ICU status (ever ICU/never ICU), O2 group (high/low), or days since admission (continuous, limited to 14 d) for COVID-19+ samples, adjusted for age and/or sex as appropriate; asterisks indicate significant associations (10% FDR). (B) Scatter plots comparing relationships between days since admission and IFNs in COVID-19 patients. Points are colored by density; blue lines represent linear model fit with 95% confidence intervals in gray. (C) Heatmap representing correlations between clinical laboratory measurements and plasma levels of each IFN. Values displayed are Spearman correlation coefficients (rho); asterisks indicate significant correlations (10% FDR). (D) Scatter plots comparing relationships between clinical laboratory measurements and the indicated IFNs in COVID-19 patients. (E) Heatmap representing correlations between selected immune factors associated with poor prognosis in COVID-19 measured in plasma by MSD assays and plasma levels of IFNs. Values displayed are Spearman correlation coefficients (rho); asterisks indicate significant correlations (10% FDR). (F) Scatter plots comparing relationships between immune factors and IFNs in COVID-19 patients.

Next, we investigated correlations between IFNs and clinical laboratory values closest in time to the research blood draw, which revealed several significant associations (Fig. 7C and Dataset S19). For example, IFNG and IFNA4/16 were the most positively correlated with levels of C-reactive protein (CRP), a well-recognized biomarker of poor prognosis at the time of hospitalization (Fig. 7 C and D) (41). In contrast, IFNB1 and IFNA6 were significantly correlated with the neutrophil/lymphocyte ratio (N/L ratio), a marker of severe COVID-19 pathology (42) (Fig. 7 C and D). Several IFNs were significantly associated with depletion of white blood cells, lymphocytes, and platelets (Fig. 7C), most of which also showed decreased levels with time since hospitalization (Fig. 7 A and B), supporting the notion that cytopenias occur earlier in the course of COVID-19, prior to seroconversion (20). Notably, IFNB1 (and to a lesser degree IFNA6) showed positive correlations with platelet numbers, suggesting that platelet recovery later in the pathological cascade co-occurs with increased levels of these IFNs (Fig. 7C).

Next, we investigated more deeply the interplay between IFNs and immune markers whose elevation in circulation has been associated with poor prognosis in COVID-19, including interlelukin (IL)-22, SAA, IL-10, IP-10, IL-6, IL-8, MIP-3, IL-1RA, MIP-1, TNF-, MCP-1, and MCP-4 (Fig. 7E and Dataset S20) (39, 40, 4345). This analysis highlighted IFNG as the IFN with the highest number of positive associations with these immune markers of poor prognosis (Fig. 7 E and F). Overall, each IFN has its unique profile of association with these markers, as clearly evidenced by IFNB1, which is strongly positively associated only with IL-22, or IFNW1, which has negative correlations with CRP and IL1-RA (Fig. 7 E and F).

Altogether, these observations reveal differential relationships between different IFNs and clinical variables in COVID-19, with some IFNs being associated with the hyperinflammatory stage of the disease (e.g., IFNG), whereas others associate with markers of late severe disease, such as increased N/L ratio (e.g., IFNB1).

IFN signaling is a critical component of the innate immune response and a main driver of the antiviral defense. In the context of viral infections, deficiencies in IFN signaling cause profound susceptibility in humans, as demonstrated by various inborn errors of immunity affecting IFN signaling (46). Despite these protective effects, exacerbated IFN signaling can also contribute to diverse pathologies, as exemplified by type I interferonopathies (47). In the context of COVID-19, the role of IFN signaling has been the subject of much study and debate, with both protective and deleterious effects being documented in different experimental systems and clinical settings (46, 8, 9, 1113, 19, 40). Within this framework, we completed a comprehensive analysis of multiomics signatures associated with production of multiple IFNs in hospitalized COVID-19 patients, revealing a high degree of diversity, even among closely related subtypes.

During vertebrate evolution, the IFN gene family has undergone significant expansion through tandem gene duplication and retrotransposition events, likely contributing to increased regulatory diversity and functional specialization (1). Although modest, our current understanding of IFN specialization is increasing. Functional specialization between major type I, II, and III IFNs has been revealed by analyzing genetic mutations affecting specific receptors or downstream kinases and transcription factors in both humans and mice (1, 46). For example, it is accepted that deficiencies in type I/III signaling confer susceptibility to viral infections, whereas deficiencies in IFNG signaling are associated with mycobacterial disease (46). IFN specialization is also evident in the clinical use of recombinant subtypes, with IFNB1 being the most effective for the treatment of multiple sclerosis, whereas IFNA2 preparations are preferred for the treatment of chronic viral infections and some malignancies (48). Notably, type I subtypes display vastly different potencies to impede HIV replication ex vivo (49, 50), and SARS-CoV-2 replication invitro (51), with different constellations of subtypes being the most effective to control each virus. Despite these advances, little is known about the mechanisms behind these differential effects (52). In this context, our work provides a valuable resource for future mechanistic research.

Although our multiomics analysis is descriptive in nature and based largely on statistically significant associations that should not be interpreted as causeeffect relationships, its value is confirmed by the many associations observed for which mechanisms have already been established. For example, our unbiased analysis of the transcriptome confirmed that 8 of the 12 IFNs tested are indeed significantly associated with a transcriptional program highly enriched for ISGs. Likewise, the association between IFNG and metabolites in the kynurenine pathway can be explained by induction of IDO1, a known ISG, during the inflammatory response elicited by SARS-CoV-2 (32, 33). Therefore, using these confirmatory observations as reference points, we propose that the datasets described here will help the field elucidate many novel causeeffect relationships explaining IFN specialization.

The specialized biosignatures of IFN action could be due to several nonmutually exclusive mechanisms, such as action through different receptors (1), differences in affinity or allosteric regulation for the same receptors (1, 52), differences in the location and timing of IFN production (23), differential turnover in circulation of various IFNs (26), differential self-amplification of IFNs (24, 25), or uneven antagonism of IFN production by SARS-CoV-2 proteins (27). One limitation of our study is that all measurements were performed from peripheral blood, which can only inform about a subset of the pathophysiological processes modulated by various IFNs. However, other studies have documented differences in IFN action and regulation at different sites during SARS-CoV-2 infection, even along the upper and lower respiratory tract (8, 53), or when comparing mucosal versus systemic immune responses (54). It is also possible that the specialized biosignatures observed are driven in part by SARS-CoV-2 itself. Like other members of the coronavirus family, SARS-CoV-2 has evolved diverse strategies to evade the antiviral effects of IFN signaling, and it is likely that these escape mechanisms do not affect all IFNs equally (27).

Despite these limitations, key observations produced by our study include the differential relationship between IFNs and the antiviral transcriptional program in circulating immune cells, the specialized relationship between seroconversion, immune cell-type abundance and IFN levels, distinct metabolic signatures associated with each IFN, and their differential relationship with clinical metadata and biomarkers of poor prognosis and severity. Throughout the study, the contrast between IFNA2 and IFNA6 exemplifies these points. Both IFNA2 and IFNA6 are significantly up-regulated in the COVID-19+ cohort. However, whereas IFNA2 is strongly associated with the IFN transcriptional program in immune cells, IFNA6 is not. IFNA2 proteomic signatures are enriched for cytokines and chemokines previously linked to IFN signaling, whereas IFNA6 proteomic signatures, similarly to those of IFNB1, are enriched for markers of platelet degranulation. IFNA2 levels decrease with seroconversion and time since hospitalization; IFNA6 levels do not. Accordingly, IFNA2 abundance associates with increased frequency of various T cell subsets involved in the early antiviral response, while IFNA6 levels correlate with B cell maturation. While IFNA2 has the highest number of significant associations in the RBC metabolome, IFNA6 has none. Lastly, only IFNA2 levels correlate with many immune markers of poor prognosis. Therefore, a detailed comparative study of these two IFNA subtypes is warranted, including studies in human cell preparations and animal models.

In sum, our analyses and datasets provide a rich resource to advance understanding of the IFN family in humans. To accelerate the use of these datasets, they are made readily available through the COVIDome Explorer Researcher Portal (21), where users can recreate the cross-omics correlations described here, investigate any other cross-omics correlations of choice, and download all data for further analysis.

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Specialized interferon action in COVID-19 - pnas.org

Legislators push bills on COVID-19 testing, vaccination, and misinformation – State of Reform – State of Reform

February 26, 2022

Sen. Richard Pan (D Sacramento), along with members of the recently-formed legislative Vaccine Work Group, recently introduced key bills to address shortages in COVID-19 testing infrastructure and misinformation related to COVID-19.

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The work group aims to facilitate coordinated action to promote vaccines and science-based public health policy in the legislature this year, and founding members include Pan, Sens. Scott Wiener (D San Francisco) and Josh Newman (D Fullerton), as well as Asms. Akilah Weber (D San Diego), Buffy Wicks (D Oakland), Cecilia Aguiar-Curry (D Winters), and Evan Low (D Campbell).

On Tuesday, Pan and the work group introduced Senate Bill 1479, which would require the California Department of Public Health (CDPH) to collaborate with each school district, county office of education, and charter school to create a robust, responsive, and flexible COVID-19 testing plan, which would include preschools, child care centers, and after-school programs.

The bill, contingent on a state or federal appropriation, would require CDPH to use these funds to ensure school districts have adequate resources to implement their COVID-19 testing plans for teachers, staff, and pupils to help schools reopen and keep schools operating safely for in-person learning.

Pan noted the importance of a robust COVID-19 testing infrastructure in the bills announcement.

COVID testing plans are essential to parents and schools and child care sites being confident in staying open and keeping children safe from COVID, he said. Funded school testing plans provide vital information to protect students and teachers through COVID variants and surges.

The bill has not been referred to a committee yet.

With the support of the work group, Pan also introduced SB 1018. This bill would require online platforms utilizing algorithms to publicly and transparently disclose how their algorithms rank and score content, and requires the sharing of this data with researchers.

Pan emphasized the timeliness of this bill and how important it is to address the amplification of misinformation and disinformation related to COVID-19 on online platforms.

Ultimately, we shouldnt have to wait for whistleblowers to understand how platforms have been negatively influencing our lives, including our ability to stop this pandemic that has not only killed nearly 1 million Americans, but has disabled so many people as well, he said. Transparency will allow the public to make informed decisions, and lawmakers and researchers need this necessary information so we can hold online platforms accountable and also set standards.

The bill was referred to the Senate Rules Committee on Wednesday.

Pan and members of the Vaccine Work Group have also recently introduced several pieces of legislation related to COVID-19 vaccinations.

SB 871, introduced in late January, would require any student at a public or private elementary or secondary school, child care center, day nursery, nursery school, family day care home, or development center to be fully immunized against COVID-19 prior to their admission. The bill would also remove the personal belief exemption for this immunization requirement.

The bill was referred to the Senate Health and Education Committees on Wednesday.

SB 866 would authorize a minor aged 12 years or older to consent to vaccines that meet specified federal agency criteria without the consent of a parent or guardian.

The bill passed the Senate Rules Committee in a 31-6 vote, and was referred to the Senate Judiciary Committee on Wednesday.

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Legislators push bills on COVID-19 testing, vaccination, and misinformation - State of Reform - State of Reform

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