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Bacterial infections quickly can be distinguished from viral infections in febrile children using a novel real-time polymerase chain reaction (PCR) assay assessing RNA expression of a single patient gene, according to a proof-of-concept study presented by Ruth Barral-Arca at the annual meeting of the European Society for Paediatric Infectious Diseases.

Bruce Jancin/MDedge News
Ruth Barral-Arca

The gene of interest– IFI44L– is entwined in a child’s response to infection. It’s upregulated in the presence of viral infection and suppressed in bacterial infection, explained Ms. Barral-Arca, a PhD student at the University of Santiago de Compostela (Spain).

This investigational real-time PCR assay could provide a major advance over current routine practice, which is to admit a sick febrile child to the hospital, order bacterial cultures, and start parenteral antibiotics presumptively while awaiting the culture results, which usually don’t come back for more than 24 hours. This practice is a step backwards in terms of antibiotic stewardship, because the majority of febrile children have a self-resolving viral infection.

“This is a big problem because a lot of children with viral infections are inappropriately given antibiotics, leading to antimicrobial resistance,” she noted.

Also, misleadingly false-negative bacterial cultures can occur if the causative pathogen wasn’t included in the test, the infection is in a nonaccessible site, or the child has recently been on antibiotics.

All of these shortcomings have led to a new diagnostic strategy based upon measuring the pattern of key host genes upregulated or suppressed during the inflammatory response.

“We’ve seen that, instead of analyzing the bugs, analyzing the host transcriptome response during infection is proving to be a promising tool for disease biomarker identification. And it’s faster. An early differentiation between viral and bacterial patients will help improve triage in emergency departments, decrease the misuse of antibiotics, and guide clinics to a more precise diagnosis. A lot of big hospitals are already doing PCR. They could quickly adopt this kind of analysis,” Ms. Barral-Arca continued.

IPGGutenbergUKLtd/Thinkstock

She presented a pilot study in which the assay was put to the test using multiple blood samples from 14 febrile infants and children up to 6 years of age with microbiologically confirmed bacterial infection, 11 febrile children with confirmed viral infection, and 10 healthy controls.

 

 


“I know the numbers seem small, but we did a sample-size power calculation and it’s just fine,” according to the researcher.

The initial study goal was to confirm earlier promising findings from a study of 370 febrile children in the United Kingdom, Spain, and the United States, conducted by the Immunopathology of Respiratory, Inflammatory and Infectious Disease Study (IRIS) Consortium, a study in which several of Ms. Barral-Arca’s senior coinvestigators participated. The IRIS investigators demonstrated that the combined expression pattern of two genes– IFI44L and FAM89A– distinguished the bacterial from viral infections with impressive sensitivity and specificity (JAMA. 2016 Aug 23-30;316[8]:835-45).

The two-gene signature performed similarly well in Ms. Barral-Arca’s study. However, when she and her coinvestigators tested the discriminatory power of the two genes individually, they got a surprise: The real-time PCR analysis assessing expression of IFI44L alone performed even better than the two-gene combination, discriminating viral from bacterial infections with 91% sensitivity, 93% specificity, and an area under the curve of 94%. In contrast, the two-gene signature based upon IFI44L and FAM89A had a sensitivity of 91%, a specificity of 86%, and an area under the curve of 92%. While those differences in performance are small, a single-gene assay saves time, work, and cost, according to Ms. Barral-Arca.

Her group then validated their findings regarding the performance of the IFI44L single-gene signature in two independent cohorts: stored blood samples from the children in the earlier IRIS study, and a group of children with diarrhea of viral or bacterial etiology.

“One gene seems to be enough,” she said. “We have demonstrated in a real-life scenario that host gene expression microarray data can be successfully translated into a fast, highly accurate, and relatively inexpensive in vitro assay that could be implemented in the clinical routine.”

Planned future work includes investigation of how the gene expression evolves over time from fever onset, the possible utility of the assay in noninfectious febrile illnesses such as rheumatoid arthritis, and whether the test discriminates viral from bacterial infection in adults.

Ms. Barral-Arca reported having no financial conflicts regarding her study, supported by institutional funding.

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Bacterial infections quickly can be distinguished from viral infections in febrile children using a novel real-time polymerase chain reaction (PCR) assay assessing RNA expression of a single patient gene, according to a proof-of-concept study presented by Ruth Barral-Arca at the annual meeting of the European Society for Paediatric Infectious Diseases.

Bruce Jancin/MDedge News
Ruth Barral-Arca

The gene of interest– IFI44L– is entwined in a child’s response to infection. It’s upregulated in the presence of viral infection and suppressed in bacterial infection, explained Ms. Barral-Arca, a PhD student at the University of Santiago de Compostela (Spain).

This investigational real-time PCR assay could provide a major advance over current routine practice, which is to admit a sick febrile child to the hospital, order bacterial cultures, and start parenteral antibiotics presumptively while awaiting the culture results, which usually don’t come back for more than 24 hours. This practice is a step backwards in terms of antibiotic stewardship, because the majority of febrile children have a self-resolving viral infection.

“This is a big problem because a lot of children with viral infections are inappropriately given antibiotics, leading to antimicrobial resistance,” she noted.

Also, misleadingly false-negative bacterial cultures can occur if the causative pathogen wasn’t included in the test, the infection is in a nonaccessible site, or the child has recently been on antibiotics.

All of these shortcomings have led to a new diagnostic strategy based upon measuring the pattern of key host genes upregulated or suppressed during the inflammatory response.

“We’ve seen that, instead of analyzing the bugs, analyzing the host transcriptome response during infection is proving to be a promising tool for disease biomarker identification. And it’s faster. An early differentiation between viral and bacterial patients will help improve triage in emergency departments, decrease the misuse of antibiotics, and guide clinics to a more precise diagnosis. A lot of big hospitals are already doing PCR. They could quickly adopt this kind of analysis,” Ms. Barral-Arca continued.

IPGGutenbergUKLtd/Thinkstock

She presented a pilot study in which the assay was put to the test using multiple blood samples from 14 febrile infants and children up to 6 years of age with microbiologically confirmed bacterial infection, 11 febrile children with confirmed viral infection, and 10 healthy controls.

 

 


“I know the numbers seem small, but we did a sample-size power calculation and it’s just fine,” according to the researcher.

The initial study goal was to confirm earlier promising findings from a study of 370 febrile children in the United Kingdom, Spain, and the United States, conducted by the Immunopathology of Respiratory, Inflammatory and Infectious Disease Study (IRIS) Consortium, a study in which several of Ms. Barral-Arca’s senior coinvestigators participated. The IRIS investigators demonstrated that the combined expression pattern of two genes– IFI44L and FAM89A– distinguished the bacterial from viral infections with impressive sensitivity and specificity (JAMA. 2016 Aug 23-30;316[8]:835-45).

The two-gene signature performed similarly well in Ms. Barral-Arca’s study. However, when she and her coinvestigators tested the discriminatory power of the two genes individually, they got a surprise: The real-time PCR analysis assessing expression of IFI44L alone performed even better than the two-gene combination, discriminating viral from bacterial infections with 91% sensitivity, 93% specificity, and an area under the curve of 94%. In contrast, the two-gene signature based upon IFI44L and FAM89A had a sensitivity of 91%, a specificity of 86%, and an area under the curve of 92%. While those differences in performance are small, a single-gene assay saves time, work, and cost, according to Ms. Barral-Arca.

Her group then validated their findings regarding the performance of the IFI44L single-gene signature in two independent cohorts: stored blood samples from the children in the earlier IRIS study, and a group of children with diarrhea of viral or bacterial etiology.

“One gene seems to be enough,” she said. “We have demonstrated in a real-life scenario that host gene expression microarray data can be successfully translated into a fast, highly accurate, and relatively inexpensive in vitro assay that could be implemented in the clinical routine.”

Planned future work includes investigation of how the gene expression evolves over time from fever onset, the possible utility of the assay in noninfectious febrile illnesses such as rheumatoid arthritis, and whether the test discriminates viral from bacterial infection in adults.

Ms. Barral-Arca reported having no financial conflicts regarding her study, supported by institutional funding.

 

Bacterial infections quickly can be distinguished from viral infections in febrile children using a novel real-time polymerase chain reaction (PCR) assay assessing RNA expression of a single patient gene, according to a proof-of-concept study presented by Ruth Barral-Arca at the annual meeting of the European Society for Paediatric Infectious Diseases.

Bruce Jancin/MDedge News
Ruth Barral-Arca

The gene of interest– IFI44L– is entwined in a child’s response to infection. It’s upregulated in the presence of viral infection and suppressed in bacterial infection, explained Ms. Barral-Arca, a PhD student at the University of Santiago de Compostela (Spain).

This investigational real-time PCR assay could provide a major advance over current routine practice, which is to admit a sick febrile child to the hospital, order bacterial cultures, and start parenteral antibiotics presumptively while awaiting the culture results, which usually don’t come back for more than 24 hours. This practice is a step backwards in terms of antibiotic stewardship, because the majority of febrile children have a self-resolving viral infection.

“This is a big problem because a lot of children with viral infections are inappropriately given antibiotics, leading to antimicrobial resistance,” she noted.

Also, misleadingly false-negative bacterial cultures can occur if the causative pathogen wasn’t included in the test, the infection is in a nonaccessible site, or the child has recently been on antibiotics.

All of these shortcomings have led to a new diagnostic strategy based upon measuring the pattern of key host genes upregulated or suppressed during the inflammatory response.

“We’ve seen that, instead of analyzing the bugs, analyzing the host transcriptome response during infection is proving to be a promising tool for disease biomarker identification. And it’s faster. An early differentiation between viral and bacterial patients will help improve triage in emergency departments, decrease the misuse of antibiotics, and guide clinics to a more precise diagnosis. A lot of big hospitals are already doing PCR. They could quickly adopt this kind of analysis,” Ms. Barral-Arca continued.

IPGGutenbergUKLtd/Thinkstock

She presented a pilot study in which the assay was put to the test using multiple blood samples from 14 febrile infants and children up to 6 years of age with microbiologically confirmed bacterial infection, 11 febrile children with confirmed viral infection, and 10 healthy controls.

 

 


“I know the numbers seem small, but we did a sample-size power calculation and it’s just fine,” according to the researcher.

The initial study goal was to confirm earlier promising findings from a study of 370 febrile children in the United Kingdom, Spain, and the United States, conducted by the Immunopathology of Respiratory, Inflammatory and Infectious Disease Study (IRIS) Consortium, a study in which several of Ms. Barral-Arca’s senior coinvestigators participated. The IRIS investigators demonstrated that the combined expression pattern of two genes– IFI44L and FAM89A– distinguished the bacterial from viral infections with impressive sensitivity and specificity (JAMA. 2016 Aug 23-30;316[8]:835-45).

The two-gene signature performed similarly well in Ms. Barral-Arca’s study. However, when she and her coinvestigators tested the discriminatory power of the two genes individually, they got a surprise: The real-time PCR analysis assessing expression of IFI44L alone performed even better than the two-gene combination, discriminating viral from bacterial infections with 91% sensitivity, 93% specificity, and an area under the curve of 94%. In contrast, the two-gene signature based upon IFI44L and FAM89A had a sensitivity of 91%, a specificity of 86%, and an area under the curve of 92%. While those differences in performance are small, a single-gene assay saves time, work, and cost, according to Ms. Barral-Arca.

Her group then validated their findings regarding the performance of the IFI44L single-gene signature in two independent cohorts: stored blood samples from the children in the earlier IRIS study, and a group of children with diarrhea of viral or bacterial etiology.

“One gene seems to be enough,” she said. “We have demonstrated in a real-life scenario that host gene expression microarray data can be successfully translated into a fast, highly accurate, and relatively inexpensive in vitro assay that could be implemented in the clinical routine.”

Planned future work includes investigation of how the gene expression evolves over time from fever onset, the possible utility of the assay in noninfectious febrile illnesses such as rheumatoid arthritis, and whether the test discriminates viral from bacterial infection in adults.

Ms. Barral-Arca reported having no financial conflicts regarding her study, supported by institutional funding.

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Key clinical point: A novel real-time single-gene–expression PCR test quickly distinguishes viral from bacterial infection in febrile children.

Major finding: The expression signature of the IFI44L gene rapidly distinguished bacterial from viral infection in febrile children with 91% sensitivity and 93% specificity.

Study details: This translational study included 25 febrile children with definite bacterial or viral infections and 10 healthy controls.

Disclosures: The presenter reported having no financial conflicts regarding her study, supported by institutional funding.

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