Data was used to create a transmission map that tracked the spread of infections among school athletes and helped public health officials determine where best to disrupt exposure
Genomic sequencing played a major role in tracking a SARS-CoV-2 outbreak in a Minnesota school system. Understanding how and where the coronavirus was spreading helped local officials implement restrictions to help keep the public safe. This episode demonstrates how clinical laboratories that can quickly sequence SARS-CoV-2 accurately and at a reasonable cost will give public health officials new tools to manage the COVID-19 pandemic.
Officials in Carver County, Minn., used the power of genomic epidemiology to map the COVID-19 outbreak, and, according to the Star Tribune, revealed how the B.1.1.7 variant of the SARS-CoV-2 coronavirus was spreading through their community.
“The resulting investigation of the Carver County outbreak produced one of the most detailed maps of COVID-19 transmission in the yearlong history of the pandemic—a chart that looks like a fireworks grand finale with infections producing cascading clusters of more infections,” the Star Tribune reported.
Using genetic sequencing, the Minnesota Department of Health produced the above map of the spread of the COVID-19 through Carver County’s schools. The animated graph includes epidemiological data from “10 high school teams, 10 club teams, 12 teams in a sports association, and three fitness/rec centers.” According to the Star Tribune, “The cluster shows a high ‘attack rate’ of infected people spreading the virus to multiple close contacts. Genomic sequencing found the more infectious B.1.1.7 variant of the virus in about a quarter of cases so far.” Click here to access the interactive version of the map. To see details about specific persons and locations, tap or hover over each dot. (Graphic copyright: Minnesota Department of Health/Star Tribune.)
Private Labs, Academic Labs, Public Health Labs Must Work Together
For gene sequencing to guide policy and decision making as well as it did in Carver County, coordination, cooperation, and standardization among public, private, and academic medical laboratories is required. Additionally, each institution must report the same information in similar formats for it to be the most useful.
“Maintain Policies That Slow Transmission: Variants will continue to emerge as the pandemic unfolds, but the best chance of minimizing their frequency and impact will be to continue public health measures that reduce transmission. This includes mask mandates, social distancing requirements, and limited gatherings.
“Prioritize Contact Tracing and Case Investigation for Data Collection: Cases of variants of concern should be prioritized for contact tracing and case investigation so that public health officials can observe how the new variant behaves compared to previously circulating versions.
“Develop a Genomic Surveillance Strategy: To guide the public health response, maximize resources, and ensure an equitable distribution of benefits, the US Department of Health and Human Services (HHS) should develop a national strategy for genomic surveillance to implement and direct a robust SARS-CoV-2 genomic surveillance program, drawing on resources and expertise from across the US government.
“Improve Coordination for Genomic Surveillance and Characterization: There are several factors in creating a successful genomic surveillance and characterization network. Clear leadership and coordination will be necessary.”
Practical Application of Genomic Sequencing
Genomic epidemiology uses the genetic sequence of a virus to better understand how and where a given virus is spreading, as well as how it may be mutating. Pathologists understand that this information can be used at multiple levels.
Locally, as was the case in Carver County, Minn., it helps school officials decide whether to halt sports for a time. Nationally, it helps scientists identify “hot spots” and locate mutations of the coronavirus. Using this data, vaccine manufacturers can adjust their vaccines or create boosters as needed.
“This is some of the most amazing epidemiology I’ve ever seen,” epidemiologist Michael Osterholm, PhD, Regents Professor, and Director of the Center for Infectious Disease Research and Policy (CIDRAP) at the University of Minnesota, told the Star Tribune, which reported that “A public health investigation linked 140 COVID-19 cases among more than 50 locations and groups, mostly schools and sports teams in Carver County. (Photo copyright: University of Minnesota.)
Will Cost Decreases Provide Opportunities for Clinical Laboratories?
Every year since genomic sequencing became available the cost has decreased. Experts expect that trend to continue. However, as of now, the cost may still be a barrier to clinical laboratories that lack financial resources.
“Purchasing laboratory equipment, computer resources, and staff training requires significant up-front investments. However, the cost per sequence is far less today than it was under earlier methods,” the GAO noted. This is good news for public and independent clinical laboratories. Like Carver County, a significant SARS-CoV-2 outbreak in the future may be averted thanks to genetic sequencing.
“The first piece of the cluster was spotted in a private K-8 school, which served as an incubator of sorts because its students live in different towns and play on different club teams,” the Star Tribune reported.
Finding such clusters may provide opportunities to halt the outbreak. “We can try to cut it off at the knees or maybe get ahead of it,” epidemiologist Susan Klammer with Minnesota Public Health and for childcare and schools, told the Star Tribune.
This story is a good example of how genomic sequencing and surveillance tracking—along with cooperation between public health agencies and clinical laboratories—are critical elements in slowing and eventually halting the spread of COVID-19.
On top of everything else during this pandemic, drug-resistant infections are threatening the most vulnerable patients in COVID-19 ICUs
New study by researchers at the University of Minnesota highlights the continuing need for microbiologists and clinical laboratories to stay alert for COVID-19 patients with drug-resistant infections. In their study, researchers highlighted CDC statistics about the number of Candida auris (C. auris) infections reported in the United States during 2020, for example.
In a paper, titled, “Three Cases of Worrisome Pan-Resistant C Auris Found in New York,” the Center for Infectious Disease Research and Policy (CIDRAP) at the University of Minnesota reported that “As of Dec 11, the CDC said 941 confirmed and probable C. auris cases have been reported in 13 states, and an additional 1,830 patients have been found to be colonized with the multidrug-resistant fungus. Most of the cases have been detected in the New York City area, New Jersey, and the Chicago area.”
Candida auris is a particularly nasty fungus. It spreads easily, is difficult to remove from surfaces, and can kill. Worst of all, modern drugs designed to combat this potentially deadly fungus are becoming less effective at eradicating it, and COVID-19 ICU patients appear especially vulnerable to C. auris infections.
COVID-19 and C. auris a Potentially Devastating Combination
Hospitals in many areas are at a critical capacity. Thus, hospital-acquired infections such as sepsis can be particularly dangerous for COVID-19 patients. Adding to the problem, C. auris requires special equipment to identify, and standard medical laboratory methods are not always enough. Misidentification is possible, even probable.
A paper in the Journal of Global Antimicrobial Resistance (JGAR), titled, “The Lurking Scourge of Multidrug Resistant Candida Auris in Times of COVID-19 Pandemic,” notes that “A particularly disturbing feature of COVID-19 patients is their tendency to develop acute respiratory distress syndrome that requires ICU admission, mechanical ventilation, and/or extracorporeal membrane oxygenation. … This haunting facet of COVID-19 pandemic has severely challenged even the most advanced hospital settings. Yet one potential confounder, not in the immediate attention of most healthcare professionals, is the secondary transmission of multidrug resistant organisms like the fungus Candida auris in COVID-19 ICUs. … C. auris outbreaks occur in critically ill hospitalized patients and can result in mortalities rates ranging from 30% to 72%. … Both C. auris and SARS-CoV-2 have been found on hospital surfaces including on bedrails, IV poles, beds, air conditioner ducts, windows and hospital floors. Therefore, the standard COVID-19 critical care of mechanical ventilation and protracted ventilator-assisted management makes these patients potentially susceptible to colonization and infections by C. auris.”
One study mentioned in the JGAR paper conducted in New Delhi, India, looked at 596 cases where patients were admitted to the ICU with COVID-19. Fifteen of them had infections caused by C. auris. Eight of those patients died. “Of note, four patients who died experienced persistent fungemia and despite five days of micafungin therapy, C. auris again grew in blood culture,” according to reporting on the study in Infection Control Today (ICT).
Some C. auris mortality rates are as high as 72%. And patients with weakened immune systems are at particular risk, “making it an even more serious concern when 8% to 9% of roughly 530,000 ICU patients in the United States have COVID-19,” ICT reported.
Apparently, the COVID-19 pandemic has created circumstances that are particularly suited for C. auris to spread. “Given the nosocomial transmission of SARS-CoV-2 by those infected, many hospital environments may serve as venues for C. auris transmission as it is a known environmental colonizer of ICUs,” wrote the JGAR paper authors.
CDC Reports and Recommendations
Along with being especially dangerous for people with weakened immune systems, C. auris infections also produce symptoms similar to those of COVID-19, “including fever, cough, and shortness of breath,” according to the CDC’s website. People admitted to ICUs with COVID-19 are especially vulnerable to bacterial and fungal co-infections. “These fungal co-infections are reported with increasing frequency and can be associated with severe illness and death,” says the CDC.
C. auris outbreaks in the United States have mostly been in long-term care facilities, but the pandemic seems to be changing that and more outbreaks have been detected in acute care facilities, the CDC reported. The lack of appropriate personal protective equipment (PPE), changes in infection control routines, and other factors could be to blame for the increase.
Just as community spread is an issue with COVID-19 variants, so too is it a concern with C. auris infections. “New C. auris cases without links to known cases or healthcare abroad have been identified recently in multiple states, suggesting an increase in undetected transmission,” the CDC noted.
As of January 19, 2021, according to the CDC the case count of C. auris infections in the US was 1,625, with California, Florida, Illinois, New Jersey, and New York having more than 100 cases each.
According to a CDC report, “Candida auris (C. auris) is an emerging multidrug-resistant yeast (a type of fungus). It can cause severe infections and spreads easily between hospitalized patients and nursing home residents.” The graphic above, taken from the report, illustrates how “C. auris began spreading in the United States in 2015. Reported cases increased 318% in 2018 when compared to the average number of cases reported in 2015 to 2017.” (Graphic copyright: Centers for Disease Control and Prevention.)
Using Clinical Laboratory Tests to Identify C. Auris
One of the big concerns about C. auris is that it is so difficult to detect, and that medical laboratories in some countries simply do not have the technology and resources to identify and tackle the infection.
“As C. auris diagnostics in resource-limited countries is yet another challenge, we feel that alerting the global medical community about the potential of C. auris as a confounding factor in COVID-19 is a necessity,” wrote the authors of the paper published in the Journal of Global Antimicrobial Resistance.
As if the COVID-19 pandemic has not been enough, drug resistant bacteria, viruses, and deadly fungi are threatening to wreak havoc among SARS-CoV-2 infected patients. Microbiologists and medical laboratory scientists know that testing for all types of infections is vitally important, but especially when it comes to infections caused by antibiotic-resistant bacteria (ARB) and other dangerous organisms that demonstrate antimicrobial resistance (AMR).
Microbiologists and clinical laboratory professionals will want to stay informed about the number of C. auris cases identified in the US and the locations and settings where the fungus was detected. They will want to be on the alert within their hospitals and health networks, as well as with the doctor’s offices served by their labs.
One idea proving attractive to health policymakers is putting a hybrid model into rural towns that includes a freestanding emergency department and primary care
Times are tough for rural hospitals and officials in many states are looking at new models for healthcare delivery in rural areas. Anatomic pathology groups with contracts to serve rural hospitals will be affected by any changes in how rural hospitals are funded and operated.
One suggested approach to replace the existing community hospital model for rural area is called a hybrid model. It is based on freestanding emergency departments (FSED) that have links to primary care providers. Such a care model would challenge clinical laboratories in the region to provide necessary medical laboratory testing to the freestanding EDs in rural communities.
Rural Hospital Closures Could Jeopardize Local Access to Emergency Care
This problem is linked to the deteriorating finances of many rural hospitals. (more…)
Research breakthrough heralded as key insight that can lead to more accurate clinical laboratory tests and more effective antibiotics for treating E. Coli infections
Antibiotic-resistant strains of bacteria are one of healthcare’s biggest threats to patient safety and improved patient outcomes. Now advanced gene sequencing has given researchers a startling new understanding of how Escherichia coli (E. coli) has developed resistance to antibiotics.
This discovery may have a major impact on microbiology labs in hospitals, because they do so much of the medical laboratory testing to detect and identify infections. These new research findings also demonstrate to pathologists how quickly genome analysis can generate new knowledge about diseases and their causes. (more…)
Department of Laboratory Medicine and Pathology at the University of Minnesota is anticipating new clinical and operational needs of physicians practicing in ACOs and medical homes
MINNEAPOLIS, MINNESOTA—Academic pathology departments are facing a host of challenges as a direct result of the rapid pace of change happening today in the U.S. healthcare system. Some challenges are financial because of reduced funding. Other challenges are clinical or due to the formation of ACOs and similar types of integrated-care delivery organizations. (more…)
