Distinct Cerebrospinal Fluid Proteomes Differentiate Post-Treatment Lyme Disease from Chronic Fatigue Syndrome

Neurologic Post Treatment Lyme disease (nPTLS) and Chronic Fatigue (CFS) are syndromes of unknown etiology. They share features of fatigue and cognitive dysfunction, making it difficult to differentiate them. Unresolved is whether nPTLS is a subset of CFS. Methods and Principal Findings: Pooled cerebrospinal fluid (CSF) samples from nPTLS patients, CFS patients, and healthy volunteers were comprehensively analyzed using high-resolution mass spectrometry (MS), coupled with immunoaffinity depletion methods to reduce protein-masking by abundant proteins. Individual patient and healthy control CSF samples were analyzed directly employing a MS-based label-free quantitative proteomics approach. We found that both groups, and individuals within the groups, could be distinguished from each other and normals based on their specific CSF proteins (p&0.01). CFS (n = 43) had 2,783 non-redundant proteins, nPTLS (n = 25) contained 2,768 proteins, and healthy normals had 2,630 proteins. Preliminary pathway analysis demonstrated that the data could be useful for hypothesis generation on the pathogenetic mechanisms underlying these two related syndromes. Conclusions: nPTLS and CFS have distinguishing CSF protein complements. Each condition has a number of CSF proteins that can be useful in providing candidates for future validation studies and insights on the respective mechanisms of pathogenesis. Distinguishing nPTLS and CFS permits more focused study of each condition, and can lead to novel diagnostics and therapeutic interventions

PET Imaging of Microglia Activation and Infection in Neuropsychiatric Disorders with Potential Infectious Origin

The central nervous system (CNS) is an immunoprivileged location for the possible sequestration of latent infections. The presence of pathogens may be involved in the etiology of neuropsychiatric diseases by inducing classical inflammatory responses, hypersensitivity, cellular toxicity, or direct alteration of cellular processes. Infection, persistence, and activation of microbes in the brain are not easy to assess in vivo, and the relation with clinical disease is very difficult to prove. An elegant way to determine an inflammatory response in the brain in vivo is by molecular imaging of microglia activation with [11C]PK11195 and other radiopharmaceuticals that target the translocator protein (TSPO). In this chapter, we summarize the neuroimaging studies that target the TSPO in patients with neuropsychiatric diseases, and we propose positron emission tomography (PET) imaging with radiopharmaceuticals that target the metabolism of infectious agents directly.</p