For adult rheumatology practitioners, it is hard to fathom how little of a role laboratory biomarkers play in the clinical practice of pediatric rheumatologists. Adult practitioners can use ESR and especially CRP routinely as a fairly reliable marker of disease activity, where both parameters can regularly be expected to correlate with disease activity and fall after initiation of treatment (5, 14, 15). In RA, both ESR and CRP have been validated in the context of the DAS28 against radiographic progression and physical function (16).
In pediatric rheumatology, laboratory testing in oligo- and polyarticular JIA, which comprise approximately two thirds of all JIA cases, so far plays only a minor role in evaluating disease activity (17). In textbooks, changes in inflammatory parameters seen in these categories are described as “mild to moderate elevation of the erythrocyte sedimentation rate (ESR) and elevation of C-reactive protein levels may occur” (18). ESR especially is described as variable in both oligo- and polyarthritis, with further differentiation of polyarthritis into subsets with possibly low or high ESR levels attempted by some authors to explain the observed variabilities (17). Even in early studies, CRP and ESR were found to be consistently elevated only in sJIA, with uneven results in polyarthritis where they mostly correlate with each other rather than with disease activity, and more recent results demonstrate the dubious value of CRP and ESR as a marker of long-term outcome (19–22). For the various forms of the proposed disease activity index JADAS, which has been modeled after the DAS28 in RA, ESR or CRP has initially been included as an activity marker (11, 23). However, the correlation of ESR to the other parameters of the JADAS have been described as moderate at best – slightly better in the case of sJIA – and exclusion of laboratory parameters in the cJADAS has been proven beneficial, not only improving feasibility in the clinical setting but also maintaining sensitivity and specificity of the index (8, 9, 12). The JADAS ‘overall did not improve by adding the erythrocyte sedimentation rate (9).’
In this study, we show that in the oligoarthritis categories of JIA, the α2-fraction of serum electrophoresis, especially when corrected by total serum protein, shows a markedly higher correlation to disease activity as measured by cJADAS27, compared to the traditional biomarkers of acute phase reaction. Even more striking, haptoglobin as a component of the α2-fraction demonstrates a significantly higher correlation to cJADAS27 than both CRP and ESR in all three subgroups. Considering pseudo R squared of the model, α2-fraction and haptoglobin also represent a higher proportion of the variability than ESR or CRP, with the proportion of the variability explained by haptoglobin as a predictor being three times as high than in CRP. The ROC analysis demonstrated a better utility as a biomarker for both haptoglobin and CA2F, compared to ESR and especially CRP. Using the traditional ranking system for the AUC in the ROC (0.9–1.0 = excellent, 0.8 – ≤0.9 = good, 0.7 – ≤0.8 = fair, 0.6 – ≤0.7 = poor, 0.5 – ≤0.6 = fail), only haptoglobin falls under the ‘fair’ category, while all other parameters can be considered ‘poor’.
Protein electrophoresis, especially in the more modern form of capillary serum electrophoresis, provides information about the status of protein components that are present in large quantities in the body (24). It is an inexpensive test, and widely available in hospitals by virtue of its common use to monitor patients with multiple myeloma. The alpha-fractions are considered a typical, if unspecific, biomarker for the acute-phase reaction (25). Children and elderly people can show higher levels of α2 -macroglobulin
and may therefore demonstrate a slightly more pronounced α2-fraction (26). While immunoglobulins and beta globulins have been studied in juvenile arthritis, alterations in the alpha-fractions have not yet been investigated (27).
Haptoglobin is an acute phase protein which binds free hemoglobin and has anti-inflammatory properties, but may have proinflammatory effects on the joint; its synthesis is induced by various cytokines including IL-1 and IL-6 (28). It appears to play a role in the inflammatory process of bone destruction via bradykinin and thrombin stimulation of prostaglandin E2 formation, leading to bone resorption (29). It has also been shown that haptoglobin modulates Th1 versus Th2 balance in macrophages by promoting a Th1 cellular response according to genotype (30).
Haptoglobin has been demonstrated to be a normal constituent of synovial fluid, with a hemoglobin-binding capacity of approximately 40% of that in serum (31). Almost 40 years ago, it has been demonstrated that for RA, CRP shows significantly higher correlation with disease activity than haptoglobin, and haptoglobin has generally been disregarded as a possible biomarker for rheumatology ever since (32). In addition, when studying the genetic subtypes of haptoglobin in the synovial fluid in patients with rheumatoid arthritis, no obvious correlation was found with elevated levels in all three haptoglobin types studied (33).
Still, the relationship of haptoglobin to inflammation is well described, with haptoglobin mRNA found to be expressed locally in the joints of arthritic rats (34). Haptoglobin has also been shown to restore homeostasis after inflammatory processes, and to bind to activated macrophages, therefore inhibiting TNFα production (35, 36). In fact, elevation of the two α-chains of haptoglobin has been correlated to response to TNF inhibitors in RA (37).
For JIA, Rosenkranz et al. have examined the synovial fluid proteome of various categories; a comparison between the different subtypes revealed 24 significantly differentially expressed proteins of which haptoglobin was the most prominent differentiator (38). Levels of haptoglobin were markedly elevated in both systemic JIA and polyarticular JIA, with the former demonstrating the greatest overall expression. They also demonstrated by PCR that haptoglobin is produced locally in the inflamed joint, similar to mice (34). Gibson et al., who demonstrated differential proteome profiles in synovial fluid of untreated polyarticular, persistent and extended oligoarticular JIA patients, showed similar results (39). Here, they described increases of haptoglobin in all groups, with 2.3- to 4.3-fold overexpression in polyarticular patients when contrasted with the whole group of oligoarticular patients. These findings indicate that elevation of haptoglobin appears to be the direct result of local inflammation in the joint. CRP represents an acute phase protein following IL-6 secretion by macrophages and T cells, and IL-6 has been found in elevated levels in the synovial fluid, but it is produced mainly in the liver (40). ESR represents the change in the net negative charge of red blood cells, causing them to fall more rapidly in suspension in the presence of acute phase reactants (41). It has been shown previously, and in this study, to correlate more closely with disease activity and flares in JIA than CRP (42). However, it is also affected by a large variety of factors beyond the acute phase reaction. A biomarker such as haptoglobin offers the chance of not only accurately depicting the acute phase reaction but also to represent a biomarker originating from the local site of inflammation.
A variety of other conditions may also increase the alpha2-fraction of serum electrophoresis, including corticosteroid therapy and adrenal insufficiency, and levels of haptoglobin, most notably hemolytic anemia. Haptoglobin has also been described as elevated in inflammatory, non-immune mediated disease, most notably osteoarthritis and Perthes disease, and was found locally expressed in oncological tissue (34, 43, 44). Further studies will have to closely examine the specificity of this biomarker. Disease duration as well as differences in medication are also possible confounding factors and may alter the profiles of inflammatory proteins. In this analysis, fractions of serum electrophoresis were not corrected for age; however, all patients were above the age of 1 year where distribution of the different fractions of electrophoresis show only minimal changes (25). Interestingly, in this study correlation between all biomarkers, not only haptoglobin, were lower in the extended oligoarthritis category with a longer disease duration, pointing at a possibly limited utility of laboratory biomarkers in JIA in the long term.