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NF-kB pathway serves as a unifying hub for molecular and clinical phenotypes in post-acute infection syndromeNew research identifies shared biological markers for chronic fatigue conditions

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Key Takeaway
Note that the NF-kB pathway serves as a unifying hub for molecular and clinical phenotypes in post-acute infection syndrome.

This systematic literature review synthesized 142 studies to identify laboratory and omics biomarkers for post-acute infection syndrome (PAIS), including post-acute COVID syndrome (PACS) and myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS). The scope included evaluating metabolic pathways, microbiome status, and mitochondrial stress as potential indicators of these conditions.

The review identified that amino acid, energy, and lipid metabolism, along with the microbiome, mitochondrial stress, and miRNA networks are affected in PAIS. A key finding is that the NF-kB pathway serves as a unifying hub connecting molecular, cellular, and clinical phenotypes. The authors noted that PAIS is driven by dysregulated host responses rather than active viral infection.

Limitations include heterogeneous approaches across the reviewed studies and analytical methods that often focused on only a subset of molecules. While several biomarkers were identified, the review emphasizes that these require further validation in larger cohorts and longitudinal designs. These findings may support a shift toward mechanism-based classification in clinical practice.

Living with persistent exhaustion after an infection can feel like a mystery. For people dealing with post-acute COVID syndrome or myalgic encephalomyelitis (ME/CFS), finding out why their bodies won't 'switch back on' is a major hurdle. New research looked at 142 different studies to find common biological markers for these conditions.

The review found that several systems are affected, including how the body processes energy and fats, as well as issues with mitochondria (the powerhouses of your cells) and the microbiome. Most importantly, researchers identified a specific pathway called NF-kB as a unifying hub. This pathway connects the different ways these illnesses show up in patients.

While these findings provide a roadmap for moving from treating symptoms to targeting actual biological mechanisms, there is still work to do. Because the original studies used many different methods and focused on only small groups of molecules, many of these markers need more testing in larger groups before they can be used in daily clinical practice.

What this means for you:
A specific pathway called NF-kB may link several types of chronic fatigue following an infection.

Common questions

What is the main cause of these symptoms?

The research notes that post-acute infection syndrome (PAIS) is driven by a dysregulated host response from your own body. It is not caused by an active viral infection, but rather by how the body reacts after the initial infection has passed.

What specific biological systems are affected?

The study found that several areas are impacted in patients with these conditions. These include amino acid, energy, and lipid metabolism, as well as the microbiome, mitochondrial stress, and miRNA networks.

How does this research help doctors treat patients?

By identifying a unifying hub called the NF-kB pathway, this research helps move medical practice away from just treating symptoms. It provides a foundation for future treatments that target the specific biological mechanisms causing the illness.

Study Details

Study typeSystematic review
EvidenceLevel 1
PublishedJun 2026
View Original Abstract ↓
Post-acute infection syndrome (PAIS) remained underrecognized before the COVID-19 pandemic, which further increased exposure by introducing a novel global cause. The global burden of post-acute COVID syndrome (PACS) and myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) alone is estimated at several tens of millions affected worldwide. Biomarker discovery is central to improving PAIS diagnosis and may provide therapeutic targets. This review summarizes current knowledge on biomarkers for PAIS, including PACS and ME/CFS. A systematic literature search was conducted in PubMed and Web of Science. Inclusion criteria were: (1) studies including PAIS patients; (2) reporting laboratory or omics biomarkers; and (3) investigating biomarkers or pathomechanisms of PAIS. Although Guillain-Barré syndrome (GBS) is not PAIS, we have included it as a separate mechanistic comparator due to its prevalence in search results and its clinical and immunological similarities to PAIS. A total of 142 studies analyzing PAIS biomarkers were included. GBS was analyzed separately and later compared with the other results. Overall, the reviewed studies employed heterogeneous approaches. While similar types of data were frequently investigated, analytical methods varied and often focused only on a subset of molecules. The results indicate that amino acid, energy, and lipid metabolism, microbiome, mitochondrial stress, and miRNA networks are affected. All pathways are connected via NF-κB. PAIS is a multisystem disorder rooted in persistent immune activation, metabolic reprogramming, and systemic inflammation, driven not by active viral infection, but by dysregulated host responses. The NF-κB pathway serves as a unifying hub, connecting molecular, cellular, and clinical phenotypes. Our framework enables a shift from symptom-based to mechanism-based classification, paving the way for biologically grounded interventions. This review synthesizes a broad spectrum of biomarkers in PAIS, integrating findings across pathogens and molecular levels rather than restricting to individual conditions or symptom clusters. This study highlights the differences and commonalities among pathogens and diseases that lead to post-acute sequelae, fills a critical knowledge gap, and provides a foundation for future research and clinical practice. Future studies incorporating multi-omics approaches, longitudinal designs, and larger patient cohorts are needed to validate specific biomarkers and advance the understanding of PAIS.
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