General Inflammation Testing - CAM 205HB

Description 

Inflammatory response can occur due to tissue injury and/or various disorders, including arthritis, lupus, and infection. Acute phase reactants, such as serum C-reactive protein (CRP), are released in the acute phase response during inflammation and can be used to monitor inflammation. Inflammation may also be measured using the simple laboratory technique of erythrocyte sedimentation rate (ESR) (Kushner, 2024).

For guidance on the use of CRP as a cardiac biomarker, please see policy CAM 193-Biomarkers for Myocardial Infarction and Chronic Heart Failure. For guidance on the use of CRP as a marker for acute pancreatitis, please see CAM 198-Pancreatic Enzyme Testing for Acute Pancreatitis.

Regulatory Status 
Testing of serum acute phase reactants and ESR is performed in laboratories meeting Clinical Laboratory Improvement Act (CLIA) quality standards. The FDA has approved multiple tests for human CRP, including assays for conventional CRP, high sensitivity CRP (hsCRP), and cardiac CRP (cCRP). On Sept. 22, 2005, the FDA issued guidelines concerning the assessment of CRP (FDA, 2005). A search of the FDA Medical Devices database (FDA, 2018) on June 12, 2018, shows that the FDA has approved ESR systems from multiple companies, including the ESR Control -M Hematology Erythrocyte Sedimentation system (K972172) and the ESR Control -HC Hematology Erythrocyte Sedimentation system (K972170) by R & D Systems, the Seditainer Erythrocyte Sedimentation Rate System (K953994) from Becton Dickinson Vacutainer Systems, the Westergren Dispette for ESR (K831195) by Ulster Scientific, and the Dade ESR Kit (K823368) from American Dade.

Policy  

Application of coverage criteria is dependent upon an individual’s benefit coverage at the time of the request. 

  1. Measurement of C-reactive protein (CRP) and/or erythrocyte sedimentation rate (ESR) is considered MEDICALLY NECESSARY for inflammatory conditions as specified in Note 1.
  2. For individuals without a diagnosed inflammatory condition, measurement of ESR is considered NOT MEDICALLY NECESSARY.
  3. Measurement of CRP and/or ESR during general exam without abnormal findings is considered NOT MEDICALLY NECESSARY.

 

NOTES:

Note 1: Coverage of CRP, ESR, CRP or ESR, or both CRP and ESR is designated based on the diagnosed or suspected inflammatory condition. Either conventional or high-sensitivity CRP testing are allowed methods of testing for CRP levels. When either CRP or ESR are allowed, CRP is the preferred biomarker.

Condition

Test Preference

Frequency of Testing

Acute and Chronic Urticaria

CRP or ESR

Not specified (NS)

Acute Hematogenous Osteomyelitis (AHO)

CRP

To confirm diagnosis; 2 to 3 days during the early therapeutic course; weekly until normalization (or a clear trend toward normalization is evident)

Acute Phase Inflammation

CRP

NS

Ankylosing Spondylitis

CRP or ESR

Regular interval use in patients with active symptoms

Arthritis

CRP and ESR

– 3 months initially; 6 – 12 months later

Castleman’s Disease

CRP

NS

General Inflammation

CRP

NS

Hodgkin Lymphoma

ESR

Every 3 to 6 months for 1 to 2 years; every 6 to 12 months for the next 3 years; annually thereafter

Irritable Bowel Syndrome

CRP and ESR

During initial assessment to exclude other diagnoses

Large Vessel Vasculitis (Giant Cell Arteritis, Takayasu Arteritis)

CRP and ESR

To confirm diagnosis; every 1 – 3 months during the first year; every 3 – 6 months thereafter

Nonradiographic axial spondyloarthritis

CRP or ESR

Regular interval use in patients with active symptoms

Polymyalgia Rheumatica

CRP or ESR

At initial diagnosis; every 3 months during long-term steroid therapy

Periprosthetic Joint Infections (PJI)

CRP and ESR

NS

Rheumatoid Arthritis

CRP or ESR

Prior to treatment; every 1 – 3 months during active disease; annually when disease is inactive

Systemic Lupus Erythematosus

CRP or ESR

At initial assessment; every 1 – 3 months during active disease; every 6 – 12 months during stable disease; during pregnancy

T-cell lymphomas

ESR

NS

TABLE OF TERMINOLOGY

Term

Definition

AAAAI

Academy of Allergy, Asthma & Immunology

AAFP 

American Academy of Family Physicians

AAOS

American Association of Orthopaedic Surgeons

AAOS

American Academy of Orthopaedic Surgeons

ABIM

American Board of Internal Medicine

ABVD

Adriamycin, bleomycin, vinblastine, dacarbazine

ACAAI

American College of Allergy, Asthma & Immunology

aCL

Anticardiolipin

ACPA

Anti-cyclic citrullinated peptide antibodies

ACR

American College of Rheumatology

ACR

American College of Radiology

ANA

Antinuclear antibodies

Anti-CCP

Anti-cyclic citrullinated peptides

Anti-dsDNA

Anti-double stranded DNA

Anti-β2-GPI

Anti-β2-glycoprotein I

aPL

Antiphospholipid antibodies

AS

Ankylosing spondylitis

ASCP

American Society for Clinical Pathology

ASCP

Anti-cyclic citrullinated peptide antibodies

AUC

Area under the curve

BHPR

British Health Professionals in Rheumatology

BSR 

British Society for Rheumatology

CBC

Complete blood count

cCRP

Cardiac C-reactive protein

CDAI

Clinical disease activity index

CHL

Classic Hodgkin lymphoma

CLIA

Clinical laboratory improvement act

CRA

Canadian Rheumatology Association

CRP

C-reactive protein

CTD

Connective tissue diseases

CVD

Cardiovascular disease

DAS

Disease activity score

DAS28

28-Joint disease activity score

DAS28-CRP

Disease activity score 28 C‐reactive protein

DAS28-ESR

Disease activity score with 28-joint counts - erythrocyte sedimentation rate

EDL

Essential In Vitro Diagnostics

EDTA

Ethylenediamine tetraacetic acid

eGFR

Estimated glomerular filtration rate

EIA

Enzyme immunoassay

ENA

Extractable nuclear antigens

ESR

Erythrocyte sedimentation rate

EULAR 

European League Against Rheumatism

FDA

Food and Drug Administration

GCA

Giant cell arteritis

HCSC

Health care service corporation

HL

Hodgkin lymphoma

hsCRP

High-sensitivity C-reactive protein

IBD

Inflammatory bowel disease

IBS

Irritable bowel syndrome

ICSH

International Council for Standardization in Hematology

ISRT

Involved-site radiation therapy

IVD

In vitro diagnostics

JTFPP

Joint Task Force on Practice Parameters

LAC

Lupus anticoagulant

LDH

Lactate dehydrogenase

MCD

Multicentric Castleman Disease

MSIS

Musculoskeletal Infection Society

NA

Not applicable

NASH

Nonalcoholic steatohepatitis

NCCN

National Comprehensive Cancer Network

NICE

National Institute for Health and Care Excellence

NPV

Negative predictive value

NS

Not specified

NSAID

Non-steroidal anti-inflammatory drugs

PAS

Patient activity scale

PJI

Periprosthetic joint infections

PMR

Polymyalgia rheumatica

PPV

Positive predictive value

RA

Rheumatoid arthritis

RACGP

Rheumatoid Arthritis Working Group of The Royal Australian College of General Practitioners

RAPID3

Routine assessment of patient index data 3

RD

Rheumatic disease

RDT

Rapid diagnostic test

RF

Rheumatoid factor

SAA

Spondylitis Association of America

SDAI

Simplified disease activity index

SIRS

Systemic inflammatory response syndrome

SLE

Systemic lupus erythematosus

TSH

Thyroid-stimulating hormone

VASDA

Visual analog scale disease activity

VASQOL

VAS quality of life

WHO

World Health Organization

Rationale  
Conditions Associated with Acute Inflammatory Responses
Diseases most associated with an acute inflammatory response measured by C-reactive protein (CRP) and/or erythrocyte sedimentation rate (ESR) include arthritis, especially rheumatoid arthritis (RA), polymyalgia rheumatica (PMR), giant cell arteritis (GCA), systemic lupus erythematosus (SLE), cardiovascular disease (CVD) (Kushner, 2024), and Hodgkin lymphoma (HL) (NCCN, 2024b). RA is a systemic polyarthritis that can lead to joint loss as well as tendon and ligament deformation to the point of affecting day-to-day living. The diagnosis of RA can be made in a patient “with inflammatory arthritis involving three or more joints, positive RF [rheumatoid factor] and/or anti-citrullinated peptide/protein antibody, disease duration of more than six weeks, and elevated CRP or ESR, but without evidence of diseases with similar clinical features” (Baker, 2024). PMR “is an inflammatory rheumatic condition characterized clinically by aching and morning stiffness about the shoulders, hip girdle, and neck” (Salvarani & Muratore, 2023a). PMR is frequently associated with GCA (also known as Horton disease), which is vasculitis of medium-to-large blood vessels and can include the aorta and cranial arteries. Cranial arteritis can lead to permanent vision loss. An estimated 40% 
– 50% of patients with GCA also suffer from PMR whereas 15% of all PMR patients are also diagnosed with GCA. Due to inflammation of the aorta and aortic branches, aortic aneurysm and aortic dissection can occur in patients with GCA (Salvarani & Muratore, 2023b). In both PMR and GCA, ESR and CRP levels are typically elevated. SLE “is a complex autoimmune disease with chronic relapsing-remitting course and variable manifestations leading a spectrum from mild mucocutaneous to devastating, life-threatening illness… Epigenetic modifications mediate the effect of the environment on immunologic responses, eventually leading to an inflammatory, autoimmune, multi-systemic disease characterized by autoantibody production and tissue injury” (Gergianaki & Bertsias, 2018). Since patients with SLE can be prone to infection, ESR and CRP may be used in monitoring inflammation (Kushner, 2024). CVD is a very common inflammatory disorder in the United States. Although serum CRP is a non-specific inflammatory marker and is not a causative agent of CVD, serum CRP can be used as a biomarker for CVD (Black et al., 2004; Kushner, 2024). Hodgkin lymphoma accounts for 10% of lymphomas and is characterized as a B-cell lymphoma “containing a minority of neoplastic cells (Reed-Sternberg cells and their variants) in an inflammatory background” (Aster & Pozdnyakova, 2022). ESR is elevated in HL, and an ESR ≥50 is considered as an “early-stage unfavorable factor” (NCCN, 2024b). 

Erythrocyte Sedimentation Rate (ESR)
Erythrocyte sedimentation rate (ESR) is a common laboratory method used to monitor general inflammation. ESR is used to analyze many different conditions, including RA, SLE, arteritis, PMR (Kushner, 2024; Wu et al., 2010). The simple Westergren method of ESR consists of measuring the distance a blood sample travels in a tube within one hour. The International Council for Standardization in Hematology (ICSH) established a calibration reference to this method using citrate-diluted samples. Automated ESR methods have been established; however, some of these analyzers use different dilution solutions, such as EDTA, rather than citrate. EDTA is commonly used as an anticoagulant in hematology measurements whereas the use of citrate is less prevalent. Horsti et al. (2010) compared blood samples from 200 patients using the traditional Westergren method versus an EDTA-based method. Their data has an R2 value of only 0.72 and 55 subjects had a difference of over 30%, clearly indicating that ESR is significantly affected by sample preparation methods (Horsti et al., 2010). ESR can also be affected by red blood cell morphology, ambient conditions (such as high room temperature or tilting of the ESR tube), anemia, renal disease, obesity, heart failure, and hypofibrinogenemia (Kushner, 2024; Taylor & Deleuran, 2024).

More, ESR may be affected by noninflammatory factors, thus reducing its specificity for inflammatory processes. Noninflammatory biological factors and environmental conditions can increase a sample’s observed ESR. If the serum sample contains elevated concentrations of ions or charged proteins, an elevated ESR may occur; for example, an increase in positively charged plasma proteins could result in agglutination of erythrocytes within a sample for rapid sedimentation (Hale et al., 2019).

The ICSH established a Working Group to investigate the ESR methodology used in laboratories; the findings of this working group were published in 2017. Data from over 6000 laboratories on four different continents was examined. Of the laboratories included in the study, only 28% used the “gold standard” Westergren method exclusively (i.e. the method with the established validation by the ICSH) “while 72% of sites used modified or alternate methods.” The data obtained from the new methodologies could deviate from the Westergren method by up to 142% and could differ “from each other of up to 42%.” The ICSH released recommendations based up the results of these studies. One such recommendation for labs using the non-Westergren method of ESR is to “consider adding an interpretative comment to every result stating that ‘This result was obtained with an ESR instrument that is not based on the standard Westergren method. The sensitivity and specificity of this method for various disease states may be different from the standard Westergren method’” (Kratz et al., 2017).

Besides the Westergren method, other methods have been developed to measure ESR including the Zeta sedimentation ratio, Wintrobe’s method, and micro-ESR. In a validation study, Shaikh discussed the use of the Ves-Matic Cube 30 analyzer to address the drawbacks of the Westergren method such as contamination risk, the significant blood volume required, and increased duration of analysis. A strong positive correlation was observed between Westergren and Ves-Matic methods with Spearman’s coefficient of 0.97. The study concluded that Ves-Matic Cube 30 analyzer can be used in high workload clinical settings for ESR measurement as the generated results were in concordance with those from the Westergren method. 

C-reactive Protein (CRP)
C-reactive protein (CRP) was first discovered in the early twentieth century when it was isolated in a co-precipitation reaction with the pneumococcal C polysaccharide. The polysaccharide component bound by CRP later was identified to be phosphocholine. Since then, studies have shown that CRP can bind ligands other than bacterial cell wall components. During an acute inflammatory response, hepatocytes can upregulate CRP synthesis more than 1,000-fold. The increase in serum CRP “after tissue injury or infection suggests that it contributes to host defense and that it is part of the innate immune response” (Black et al., 2004). Determining CRP concentration and fluctuations in plasma CRP can be useful in monitoring inflammatory response; however, what dictates “normal” CRP levels is of debate since CRP concentrations can vary considerably between individuals, people groups, and laboratory testing methodology. The units used to denote CRP concentrations also vary between laboratories (Kushner, 2024).

Clinical Validity and Utility of CRP and ESR in Measuring Inflammatory Processes
Both CRP and ESR have been used to monitor RA. Elevated CRP and ESR does correlate to observed radiologic damage in RA. Unlike ESR, CRP can be evaluated in stored serum. This could be advantageous due to the time constraints of ESR testing (Taylor & Deleuran, 2024). A 2009 study by Crowson et al. (2009) show that the use of both ESR and CRP testing in the case of RA is not warranted. Data from three randomized trials of 1,247 RA patients was examined. “Where available, the CRP alone may be preferred for disease activity assessment as a simple, validated, reproducible, non age-dependent test” (Crowson et al., 2009). Since both ESR and CRP have been incorporated into composite scoring for RA, the elimination of one or the other will not hinder the quantitative evaluation of the patient using a composite scoring system such as DAS (Disease Activity Score) or SDAI (Simplified Disease Activity Index). A 2015 Danish study clearly shows that the data obtained in DAS using either ESR or CRP “are interchangeable when assessing RA patients and the two versions of DAS28 are comparable” (Nielung et al., 2015). This study compared the baseline data and one-year follow-up of 109 different patients with RA using the DAS28-ESR and DAS28-CRP. Using the EULAR (European League Against Rheumatism) response criteria, only 14 patients show a divergence between using the ESR and CRP methods. Of those 14, “12 showed a better response (in terms of responder category) using DAS28-CRP, while two patients showed a better response using DAS28-ESR.” However, a 2006 study by Fransen and van Riel (2006) show that it is still possible for a patient to have a high number of swollen joints and yet receive a low DAS28-ESR score within the remission range due to a low ESR value since ESR has a significant weight on the DAS28-ESR algorithm (Fransen & van Riel, 2006). This study did not include CRP measurements to compare its validity to that of the DAS28-ESR. Another study released in 2010 (Hensor et al., 2010) shows that the DAS28-CRP could also underestimate RA remission rates since those values are usually lower than the corresponding DAS28-ESR values, but the discrepancy is not significant if age and gender are added as factors into the DAS28-CRP methodology. To confound issues, “newer biologic agents that target specific inflammatory cytokines are differentially reflected in the ESR and CRP and may therefore disproportionately deflate the composite score” (Anderson et al., 2012).

Erythrocyte sedimentation rate cannot be used to predict RA as a screening method. Suarez-Almazor and colleagues investigated the predictive value of ESR for connective tissue diseases (CTD) and RA. Their review of 711 records by more than 300 different primary care physicians in Alberta show that ESR positively predicted 35% for CTD and only 17% for cases of RA. For SLE, the positive predictive value for ESR was even lower at only 3 percent. CRP testing was not included in this study. The authors note that “most tests were negative, and were often requested in patients without CTD, resulting in low positive predictive values and questionable clinical utility” (Suarez-Almazor et al., 1998). A study by Keenan et al. (2008) compared the utilization of ESR and CRP in RA, SLE, and osteoarthritis. The data showed that for the 188 patients with RA, the number of patients with both ESR and CRP elevated were statistically the same as those with normal test levels or those with only one test elevated. Conclusions stated “that another look at the role of ESR and CRP as markers of inflammation in RA patients seen in routine care may be in order” (Keenan et al., 2008). 

Bitik et al. (2015) researched the use of elevated ESR and CRP levels in distinguishing the definitive diagnosis of a rheumatic disorder from patients with nonspecific inflammation. In their study of 112 patients, 47 had a previously diagnosed rheumatic disorder and 65 had no history of a rheumatism. Of the 65 patients with no history of a rheumatic disorder, 52.3% were diagnosed with a new rheumatic disorder with PMR/GCA comprising 38.2%, while 47.7% had a non-rheumatic diagnosis. Within this latter group, only the “CRP levels were significantly higher in infections when compared with new onset RD (rheumatic disease) or malignancies (p < 0.05)” (Bitik et al., 2015). The ESR levels between the three groups were statistically insignificant. This indicates that CRP is more sensitive to acute infections than ESR. The authors state that “although ESR and CRP levels have a very low specificity in differentiating between these conditions, in cases of unusually high levels of CRP (especially above 200), more consideration should be given to infections or malignancies.”

A 2014 study of 60 different PMR patients compared the efficacy of ESR and CRP in assessing disease activity versus patient-reported outcomes and plasma fibrinogen. In this study, the VASDA (Visual analog scale disease activity) and VASQOL (VAS quality of life), two patient-reported outcome methods, were the most responsive to changes in disease activity. Of the serum biomarkers, fibrinogen, ESR, and CRP, fibrinogen was the most accurate with a correlation coefficient of 1.63 whereas 1.2 and 1.05 were the correlation coefficients of ESR and CRP, respectively. These data suggest that plasma fibrinogen would be a more sensitive measure of PMR disease activity as compared to either ESR or CRP (McCarthy et al., 2014).

A two-year retrospective study released in 2010 (Ernst et al., 2010) researched the validity of using either ESR and/or CRP in assessing septic joints. This study consisted of 163 patients and included both genders as well as patients with alcohol or drug histories. The mean ESR value for the 119 control non-septic joints was 46 while the septic joint mean ESR value was 57, which was however, the mean CRP value was 13 in the septic joints and 8.5 in the non-septic joints. The conclusion of the authors is that “CRP is helpful in determining the presence of a septic joint; ESR is not” (Ernst et al., 2010).

Erythrocyte sedimentation rate is used in determining the algorithm to follow in the treatment of Hodgkin lymphoma (CHL). For example, in stage 1A CHL, a patient with an ESR <50 would follow either the NCCN HODG-3 or HODG-4 algorithm with an initial 2-3 cycles of ABVD (Adriamycin, bleomycin, vinblastine, dacarbazine) most likely whereas a stage 1A patient with an ESR ≥ 50 would follow the NCCN HODG-6 algorithm with a possible involved-site radiation therapy (ISRT) initially along with the chemotherapy since an ESR ≥50 is considered an “unfavorable factor” (NCCN, 2024b). 

C-reactive Protein elevation is associated with a number of inflammatory disorders (including RA), tissue damage (such as after a myocardial infarction), as well as bacterial infections; however, CRP levels in SLE do not mirror disease progression (Kushner, 2024). Even during cases of severe disease phenotypes, CRP levels can be normal to modestly increased. One possible reason is CRP suppression by type I interferons, which are increased in SLE. Another possibility is that low concentrations of wildtype CRP play a role in lupus. “Three lines of investigation have raised the possibility that low plasma levels of CRP may be related to the pathogenesis of SLE: 1) an association between SLE and several CRP genetic polymorphisms, at least one of which is associated with low CRP levels, 2) the possibility that low CRP levels may contribute to defective clearance of autoantigens during apoptosis, and 3) the therapeutic efficacy of CRP in mouse models of SLE” (Gaitonde et al., 2008). Also, CRP and anti-CRP may form large complexes in patients with SLE, which could also decrease the serum concentrations of free CRP (Gordon et al., 2018). A study by O’Neill and colleagues in 2010 show that anti-CRP levels are directly proportional in an increase to disease activity (32.6, 24.8, and 16.8 AU, respectively, for high activity, low activity, and control groups) and that anti-CRP levels were above the upper limit of normal in 26.3% of the high activity cases versus only 12.8% for the low activity cases (O'Neill et al., 2010). Patients with SLE usually have elevated ESR, but this elevation may be due to persistent polyclonal hypergammaglobulinemia (increased production of several different immunoglobulins) (Gordon et al., 2018).

Periprosthetic joint infections (PJI) may also benefit from testing of CRP and ESR. Joint arthroplasties (replacements) are typically performed in response to joint damage or destruction and commonly involve areas such as the hip, knee, or shoulder. Up to 2% of total knee replacements may become infected. Common signs of infection are present in PJI such as joint pain or warmth at the incision site, and microbiological cultures may be performed to confirm the diagnosis. CRP and ESR have been suggested as supportive biomarkers in cases where a definitive diagnosis cannot be made. CRP and ESR are considered minor clinical diagnostic criteria in some definitions of PJI, but due to the ubiquity of these markers, their levels are usually interpreted cautiously (Baddour & Chen, 2023).

Berbari et al. (2010) performed a meta-analysis of inflammatory markers in prosthetic joint infection. A total of 30 studies including 3,909 revision total hip or knee replacements were assessed, and of the 3,909 operations, 1,270 infections occurred. CRP was included in 23 of 30 studies, and its diagnostic odds ratio was found to be 13.1. ESR was included in 25 of 30 studies, and its diagnostic odds ratio was calculated to be 7.2. Interleukin-6 was found to be the best marker of all markers addressed, albeit with only three studies (Berbari et al., 2010).

Perez-Prieto et al. (2017) examined the performance of CRP and ESR for PJI diagnosis. A total of 73 patients were included in the study. Preoperative CRP levels were found to be normal in 23 patients, and of those 23 patients, 17 patients also had normal ESR levels. Further, 16 patients with normal CRP levels were found to have “low-virulence” organisms (such as Propionibacterium acnes and coagulase-negative staphylococci) present. Overall, the authors found that 23% of the patients included in this study would not have been diagnosed with PJI according to the American Association of Orthopaedic Surgeons (AAOS) guidelines or the Musculoskeletal Infection Society definition (Perez-Prieto et al., 2017).

Kheir et al. (2018) evaluated the accuracy of inflammatory markers in diagnosis periprosthetic joint infections (PJI). A total of “549 periprosthetic joint infection cases and 653 aseptic total joint arthroplasty revisions” were reviewed. The sensitivity of ESR to diagnose PJI was 0.85 and 0.88 for CRP. ESR was also elevated in antibiotic-resistant strains of bacteria compared to culture-negative cases. For CRP, gram-negative species had higher levels of CRP than culture-negative cases. Overall, the authors concluded that both ESR and CRP had higher false-negative levels than previously reported (Kheir et al., 2018).

Hamann et al. (2019) compared the DAS28-ESR and DAS28-CRP to determine the impact on disease activity stratification in RA. A total of 31,074 paired data sets were included in this study and were obtained from the British Society for Rheumatology Biologics Register for RA. Results showed that “DAS28-CRP scores were ∼0.3 lower than DAS28-ESR overall, with greatest differences for women (-0.35) and patients over 50 years old (-0.34). Mean male DAS28-CRP scores were 0.15 less than corresponding DAS28-ESR scores” (Hamann et al., 2019). When DAS28-CRP data is adjusted by gender, significant agreement (P<0.001) is seen with DAS28-CRP and DAS28-ESR scores.

Bingham et al. (2019) measured the specificity and sensitivity of ESR and CRP when screening for a PJI infection using the standard MSIS cutoff of 30 mm/h and 10 mg/L, respectively. The researchers also hoped to determine the optimal CRP and ESR cutoff to achieve a ≥ 95% sensitivity. Data from a total of 81 PJI patients and 83 noninfected arthroplasty patients was analyzed for this study. Results showed that “The ESR cutoff that resulted in a sensitivity ≥ to 95% (95% CI: 85.2% – 97.6%) was 10 mm/h, and the CRP cutoff that resulted in a sensitivity ≥ to 95% (95% CI: 87.1% – 98.4%) was 5 mg/L. The sensitivity and specificity with a combined ESR and CRP of 10 mm/h and 5 mg/L was 100%” (Bingham et al., 2019). The authors note that the accepted cutoff of 30 mm/h and 10 mg/L leads to a high number of false positives and low sensitivity; these thresholds therefore need to be reevaluated.

In a prospective cohort study, Watson et al. (2019) compared the diagnostic value of CRP and ESR and evaluated whether measuring two inflammatory markers increases accuracy. For each test, sensitivity, specificity, PPV, NPV, and AUC were calculated. A total of 136,961 patients with inflammatory testing were measured of which 61.2% had a single marker measured and 38.8% had multiple markers measured. CRP and ESR were broadly similar in terms of sensitivity, specificity, PPV, and NPV. However, CRP had the highest overall AUC of 0.682 while the AUC for ESR was 0.589. Adding a second test did little improvement in AUC. When CRP and ESR were both tested for, the AUC increased from 0.682 to 0.688. Overall, the authors conclude that "Testing multiple inflammatory markers simultaneously does not increase ability to rule out disease and should generally be avoided. CRP has marginally superior diagnostic accuracy for infections, and is equivalent for autoimmune conditions and cancers, so should generally be the first-line test” (Watson et al., 2019).

In a cross-sectional study, Sherkatolabbasieh et al. (2020) investigated platelet count, ESR, and CRP levels in pediatric patients with inflammatory disease. A total of 150 children (75 male and 75 female) with diagnosis of infectious and inflammatory diseases were included in the study. Platelet count, ESR, and CRP levels were measured at the time of hospitalization and at discharge. At time of hospitalization, all 150 children had abnormal ESR levels, 73.3% had abnormal CRP levels, and 8% had abnormal platelet levels. At time of discharge, only one patient recovered to normal ESR levels, 88% had normal CRP, and 93.3% had normal platelet count. The Fisher exact test showed a significant relationship between platelet count and CRP levels at the time of discharge (p < 0.0002) and admission (p <0.007), especially in the female patients. CRP levels were significantly higher in the female patients and changes in platelet count were more prevalent. No relation between platelet count and ESR was observed at admission and discharge. This study found that there are differences in inflammatory markers between the two sexes. The authors conclude that this study showed significant correlation between CRP and platelet levels in girls and CRP level measurement is useful in treatment follow up (Sherkatolabbasieh et al., 2020).

Alende-Castro et al. (2021) studied the use of CRP vs ESR in 1472 patients with no inflammatory conditions. All participants were measured for ESR, CRP and IL-6 concentrations. A total of 74.9% of participants showed normal CRP and ESR values, 4.6% showed high ESR and CRP values, and 13.8% showed high CRP but normal ESR values. Participants with high ESR/CRP values also were of older age, and reported high alcohol consumption, low physical activity, high BMI, and the presence of metabolic syndrome. In those patients who had high CRP but normal ESR, BMI seemed to be the main determinant of CRP concentrations. The authors concluded that "In this general adult population with no overt inflammatory disease, the discordant pattern of high ESR and normal CRP was associated with greater age, whereas the pattern of high CRP and normal ESR was associated with higher BMI” (Alende-Castro et al., 2021). 

In a retrospective study, Christopher studied the use of ESR/CRP ratio to differentiate acute vs chronic periprosthetic joint infections. A total of 147 patients (81 acute and 66 chronic) were measured for ESR and CRP concentrations. The mean ESR / CRP ratio in acute patients was 0.48 compared to 2.87 in chronic patients. The ideal cutoff value was 0.96 for ESR / CRP to predict a chronic (> 0.96) vs. acute (< 0.96) PJI. The sensitivity at this value was 0.74 and the specificity was 0.90. The authors conclude that "The ESR / CRP ratio may help determine the duration of PJI in uncertain cases. This metric may give arthroplasty surgeons more confidence in defining the duration of the PJI and therefore aid in treatment selection” (Christopher et al., 2021). 

Dhudasia et al. (2022) conducted a retrospective cohort study to determine the clinical utility of CRP in diagnosing early-onset sepsis and assessing patient outcomes. The patient sample included over 10,000 infants admitted to the neonatal intensive care units from 2009 – 2014, when CRP was used routinely. The cutoff utilized as ≥ 10 mg/L for diagnosis of “culture-confirmed early-onset sepsis.” Based on when the CRP was obtained from the blood culture, which was taken at three days of birth, the results yielded varying specificities and sensitivities. If the CRP was obtained at ± four hours, the sensitivity was 41.7%, specificity 89.9%, and positive likelihood ratio was 4.12. When obtained 24 – 72 hours later, the sensitivity became 89.5%, but specificity decreased to 55.7% and positive likelihood ratio to 2.02. During this time of routine CRP testing, there were higher rates of early-onset sepsis evaluation, antibiotic initiation, and antibiotic prolongation “in the absence of early-onset sepsis,” but no difference in time to detection and in-hospital mortality with a period of non-routine CRP testing. The researchers ultimately concluded that the diagnostic performance of CRP in diagnosing early-onset sepsis was insufficient to warrant routine testing, as patient outcomes were not significantly affected with the elimination of routine CRP testing. Other factors with higher sensitivities, specificities, and positive likelihood ratios need to be included in the evaluation (Dhudasia et al., 2022). 

While the search for the optimal biomarker in inflammatory bowel disease (IBD) continues, the most widely available biomarkers in current clinical practice include serum testing with CRP and ESR (Clough et al., 2024; Muresan & Slevin, 2024). CRP is frequently used by primary care clinicians to differentiate between IBD and irritable bowel syndrome (IBS). According to Clough et al. (2024), “CRP is limited as a biomarker in IBD by its lack of specificity, with its expression upregulated in numerous infective and inflammatory pathologies, thus limiting its usefulness in distinguishing between IBD and other differential diagnoses. Its utility in IBD is largely as an adjunct to clinical and endoscopic findings.” However, exclusion of IBD should not be made based solely on a normal CRP but in combination with clinical assessment and other markers with better sensitivity (Clough et al., 2024).

World Health Organization (WHO) 
On May 16, 2018, the WHO released their first edition of the Model List of Essential In Vitro Diagnostics (EDL) “to advance universal health coverage, address health emergencies, and promote healthier populations.” This list of in vitro diagnostics (IVD) is to be used as a reference of the essential diagnostic tools for laboratories to complement their Model List of Essential Medicines. With respect to the diagnostic tool “to detect inflammation as an indicator of various conditions,” the WHO recommends CRP either in an EIA (enzyme immunoassay) or RDT (rapid diagnostic test) assay format. The specimen type can be venous whole blood, serum, or plasma.
In 2019, the WHO released the Second WHO Model List of Essential In Vitro Diagnostics. In a table titled General IVDs for Use in Clinical Laboratories, CRP is once again listed. The WHO now recommends CRP in an RDT, latex agglutination assay or immunoassay format (WHO, 2019).

In 2020, the WHO released the selection and use of essential in vitro diagnostics, which included the third WHO model list. In the section on “General IVDs for community settings and health facilities without laboratories,” the WHO performed an evaluation of utilizing ESR “to aid diagnosis and monitoring of certain infections and immune diseases; and as an alternative to a C-reactive protein (CRP) test where this is not available.” In their table, they recommend using the Westergren assay format with sampling from venous whole blood. The WHO ultimately concluded that despite several guidelines recommending ESR to aid in diagnosing several inflammatory diseases, “there is no strong evidence supporting ESR as an essential test” since there are also high rates of false positives and false negatives. They conclude that CRP “should remain the preferred choice of test,” except in cases of systemic lupus erythematosus and low-grade bone and joint infections since “there is evidence that the condition elevates ESR without causing a raise in CRP.” As of this meeting, CRP now has the purpose “to monitor response to treatment” in addition to “detect inflammation as an indicator of various response conditions,” and can be assayed as RDT, latex agglutination assay, and immunoassay with sampling venous whole blood, serum, and plasma (WHO, 2020). 

National Comprehensive Cancer Network (NCCN) 
The NCCN guidelines concerning Hodgkin Lymphoma uses ESR as a diagnostic tool in characterizing the stage/risk classification of Classic Hodgkin Lymphoma (CHL) as well as the primary treatment of the disease. In the diagnosis/workup of Hodgkin Lymphoma in adults (age ≥18 years) (recommendation 2A), they list erythrocyte sedimentation rate (ESR) as “essential” and that ESR should be tested within six months of diagnosis. 

In the guidelines concerning follow-up after completion of treatment up to five years, the NCCN (2024b) recommends obtaining an interim history and physical “every 3 – 6 [months] for 1 – 2 [years], then every 6 – 12 [months] until year 3, then annually,” as well as laboratory studies, which included a “[complete blood count], platelets, chemistry profile, and ESR if elevated at time of initial diagnosis” with the same timeline. ESR is also used in determining the dosage of involved-site radiation therapy (ISRT). “A dose of 20 Gy following ABVD X 2 is sufficient if the patient has non-bulky stage I-IIA disease with an ESR < 50, no extralymphatic lesions, and only one or two lymph node regions involved.” An ESR ≥50 is considered as an “unfavorable risk factor” for stages I and II Hodgkin Lymphoma along with B symptoms. Please note that the NCCN guidelines concerning Hodgkin Lymphoma do not contain any information concerning the use of CRP as a diagnostic or prognostic tool (NCCN, 2024b). 

In the NCCN guidelines concerning Castleman Disease, the NCCN recommend regarding diagnostic criteria for idiopathic MCD (Multicentric Castleman Disease), minor diagnostic criteria include elevated CRP (> 10 mg/L) or ESR (> 15 mm/h) where an “Evaluation of CRP is mandatory and tracking CRP levels is highly recommended, but ESR will be accepted if CRP is not available” (NCCN, 2024a).

In the NCCN guidelines concerning the T-cell lymphomas, they state that the “evaluation of serologic markers such as rheumatoid factor (RF), antinuclear antibodies (ANA), and erythrocyte sedimentation rate (ESR) is useful in patients with autoimmune disease” (NCCN, 2024c). The guidelines concerning T-cell lymphomas do not mention the diagnostic or prognostic use of CRP.

American Society for Clinical Pathology (ASCP) 
In the Choosing Wisely site of the ABIM Foundation, the ASCP released the recommendation to not “order an erythrocyte sedimentation rate (ESR) to look for inflammation in patients with undiagnosed conditions. Order a C-reactive protein (CRP) to detect acute phase inflammation” due to the higher sensitivity and specificity of CRP for acute phase of inflammation. “In the first 24 hours of a disease process, the CRP will be elevated, while the ESR may be normal. If the source of inflammation is removed, the CRP will return to normal within a day or so, while the ESR will remain elevated for several days until excess fibrinogen is removed from the serum” (ASCP, 2020).

European League Against Rheumatism (EULAR) 
In 2009, EULAR issued their recommendations concerning the management of large vessel vasculitis, which is comprised of two distinct conditions: giant cell arteritis and Takayasu arteritis. With a “Level of Evidence 3, Strength of recommendation C”, they recommend “monitoring of therapy for large vessel vasculitis should be clinical and supported by measurement of inflammatory markers. … For patients with giant cell arteritis, a relapse is usually associated with a rise in ESR and CRP” (Mukhtyar et al., 2009). In this paper, no mention of the frequency of ESR and/or CRP testing is mentioned.

In the 2018 update of the EULAR recommendations for the management of large vessel vasculitis, the guidelines state that regular follow-up and monitoring of disease activity is recommended in patients with large vessel vasculitis, primarily based on symptoms, clinical findings and ESR/CRP levels. “Visits should include clinical monitoring and measurement of ESR and CRP.” These routine follow-up visits could be scheduled every 1 – 3 months during the first year and in 3 – 6 months intervals afterwards (Hellmich et al., 2020).

In 2013 in EULAR recommendations for the use of imaging of the joints in the clinical management of rheumatoid arthritis (Colebatch et al., 2013), they state that “baseline inflammatory disease measured by scintigraphy appears to be associated with radiographic progression. In addition, multiple regression analysis has demonstrated that progression of radiographic joint destruction was primarily predicted by 99mTc-IgG scintigraphy; joint swelling, ESR and IgM RF (Rheumatoid Factor) were not predictive. This suggests that scintigraphy may be superior to conventional clinical and laboratory measurements in the prediction of joint destruction.” This set of guidelines did not include any mention concerning CRP or the frequency of ESR testing.

In 2015, EULAR and the American College of Rheumatology (ACR) issued joint recommendations concerning the management of polymyalgia rheumatica (PMR) (Dejaco et al., 2015). Within their recommendations, they list assessments that “every case of PMR should have … prior to the prescription of therapy (primary or secondary care).” They include a basic laboratory workup “to exclude mimicking conditions and establish a baseline for monitoring of therapy”, and they state that this includes “rheumatoid factor and/or anti-cyclic citrullinated peptide antibodies (ACPA), C-reactive protein and/or erythrocyte sedimentation rate (ESR), blood count, glucose, creatinine, liver function tests, bone profile (including calcium, alkaline phosphatase) and dipstick urinalysis.” They do not state a specific preference of either CRP or ESR nor do they state the frequency of testing.

EULAR in 2016 updated their 2007 recommendations concerning the management of early arthritis (Combe et al., 2017). The 2016 updates included the following recommendation: “Monitoring of disease activity should include tender and swollen joint counts, patient and physician global assessments, ESR and CRP, usually by applying a composite measure. Arthritis activity should be assessed at 1-month to 3-month intervals until the treatment target has been reached.” The recommendation concerning including both ESR and CRP did not change between the 2016 and 2007 recommendations. Within the discussion of the recommendations, they state, “In every patient with active arthritis, closely monitoring disease activity is now considered of particular importance in the therapeutic strategy to provide a good outcome. ... Monitoring disease activity should be as frequent as the level of disease activity mandates, usually every 1 – 3 months, then potentially less frequently (such as every 6 – 12 months) once the treatment target has been achieved. Nevertheless, three changes were proposed to this item. …. First, a composite measure was recommended as the method of choice to monitor disease activity; second, a specific time frame for monitoring structural damage was deliberately left out and third, patient-reported outcomes were expanded beyond functional assessments” (Combe et al., 2017). 

In 2018, EULAR issued EULAR recommendations for the use of imaging in large vessel vasculitis in clinical practice (Dejaco et al., 2018). They make no recommendation concerning the preference of ESR or CRP nor do they state the frequency of testing; they do state “in patients with a high clinical suspicion of GCA (> 50%), for example, in case of new-onset headache, visual symptoms, jaw claudication and elevated erythrocyte sedimentation rate (ESR) and C reactive protein, a positive ultrasound would result in a post-test probability of > 95%.”

American College of Rheumatology (ACR) 
In 2012, ACR released their recommendations concerning the clinical practice of using disease activity measures of rheumatoid arthritis (RA) (Anderson et al., 2012). The recommend using the Disease Activity Score with 28-joint counts (DAS28), the Clinical Disease Activity Index, the Patient Activity Scale (PAS), the PAS-II, the Simplified Disease Activity Index (SDAI), and Routine Assessment of Patient Index Data with three measures. The DAS28 is a composite test that can use either CRP or ESR data. The ACR states that both the CRP or ESR used in the DAS28 have been validated in RA. Of the six activity measures recommended by the ACR, only DAS28 received “excellent” recommendations for all three psychometric properties — reliability, validity, and responsiveness. Within the guidelines, the ACR also issued the scores corresponding to remission, low/minimal, moderate, and high/severe RA for all the disease activity measures, including the DAS28, as well as the mathematical formula using either CRP or ESR data to determine the DAS28. CRP is also used in the SDAI; however, the SDAI is rated as “good” for reliability because they state that “test-retest reliability for composite has not been evaluated” for the SDAI. No mention of frequency of testing is made. They do note that the “inclusion of acute-phase reactants in the DAS28 and SDAI complicates the logistics and timing using these measures in point-of-care clinical decision making. Although these measures have traditionally been used in clinical trials, academic medical centers, and large multispecialty clinics, logistical barriers have likely delayed their widespread adoption in smaller practice settings” (Anderson et al., 2012).

The ACR in 2015 (Singh et al., 2015) issued guidelines for the treatment of RA. While not specifying a preference of either CRP or ESR in diagnosing or predicting the prognosis of RA, they do state in their “Key provisos and principles” that “functional status assessment using a standardized, validated measure should be performed routinely for RA patients, at least once per year, but more frequently if disease is active.” They also state that disease activity be measured using ACR-validated scales, including the DAS28 and/or SDAI. Moreover, they define RA remission as “a tender joint count, swollen joint count, C-reactive protein level (mg/dl), and patient global assessment of ≤ 1 each or a Simplified DAS of ≤ 3.3, 1 of 6 ACR-endorsed disease activity measures”.

Also, in 2015 (but published in 2016), the ACR and the Spondylitis Association of America (SAA) issued their joint recommendations concerning the treatment of ankylosing spondylitis (AS) and nonradiographic axial spondyloarthritis (Ward et al., 2016). Regarding “the treatment of patients with either active or stable AS … we conditionally recommend regular-interval use and monitoring of the CRP concentrations or erythrocyte sedimentation rate (ESR) over usual care without regular CRP or ESR monitoring.” This received a “very low-quality evidence; vote 100% agreement” rating. They do make note that as of the time of publication “no studies addressed the effect of routine monitoring of a disease activity measure” but that “the panel thought that monitoring would be most helpful in patients with active symptoms as a guide to treatment.” Testing is not required for every clinic visit. The two organizations reaffirm the same recommendations in their 2019 update (Ward et al., 2019).

In 2019, updated recommendations by the RA disease activity measures working group were published by England et al. (2019). Recommended tests include the Clinical Disease Activity Index (CDAI), the Simplified Disease Activity Index (SDAI), the Routine Assessment of Patient Index Data 3 (RAPID3), and the 28-Joint Disease Activity Score (DAS28). As noted above, the DAS28 is a composite test that can use either CRP or ESR data. The ACR states that both the CRP or ESR used in the DAS28 have been validated in RA. Updates to the management of rheumatoid arthritis were released by the ACR in 2022, but no mention of CRP or ESR were made (Arnold, 2022).

In 2021, the ACR published a guideline to provide evidence-based recommendations and expert guidance for the management of giant cell arteritis (GCA). They present 22 recommendations and two ungraded position statements for GCA and note that all but one of the recommendations are conditional due to very low- to low-quality evidence. They break these recommendations down into categories, including diagnostic testing, medical management, surgical intervention, and clinical/laboratory monitoring. All diagnostic recommendations involve biopsy or imaging- they do not recommend the use of CRP or ESR for diagnosis of GCA. However, they do recommend inflammation marker monitoring as part of clinical/laboratory monitoring. They define clinical monitoring as “assessing for clinical signs and symptoms of active disease, obtaining 4 extremity blood pressures, and obtaining clinical laboratory results, including inflammation marker levels”, with inflammation markers further defined as being CRP and ESR:

“Recommendation: For patients with GCA in apparent clinical remission, we strongly recommend long-term clinical monitoring over no clinical monitoring: The optimal frequency and length of monitoring are not well established and depend on factors including the duration of remission, site of involvement, risk of disease progression, whether the patient is receiving immunosuppressive therapy, and reliability of the patient to report new signs or symptoms. Clinical monitoring may include history taking, examinations, and laboratory and imaging studies. This is a strong recommendation given the minimal risks and potential catastrophic outcomes if monitoring is not performed.

Recommendation: For patients with GCA who have an increase in levels of inflammation markers alone, we conditionally recommend clinical observation and monitoring without escalation of immunosuppressive therapy. Increases in levels of inflammation markers such as erythrocyte sedimentation rate and C-reactive protein can be nonspecific (69). Therefore, increasing immunosuppressive therapy is not warranted in the setting of increased levels of inflammation markers in the absence of other signs of disease activity. However, these increased levels may warrant more frequent clinical and/or radiographic assessments for active disease” (Maz et al., 2021)

American Academy of Family Physicians (AAFP) 
In 2013, the AAFP released Recognition and Management of Polymyalgia Rheumatica and Giant Cell Arteritis. For polymyalgia rheumatica (PMR), they note that “a normal ESR is found in 6% to 20% of persons with [PMR], although in those cases C-reactive protein level is elevated. ESR predicts relapse more reliably, but C-reactive protein is more sensitive, and is less affected by age and other factors.” For giant cell arteritis (GCA), ESR is elevated in up to 89% of patients, but the sensitivity and specificity increase to 99% and 97%, respectively, if both ESR and CRP are tested. Regardless of using either ESR or CRP testing, the AAFP recommends that either ESR or CRP is tested at each clinic visit for patients with either PMR or GCA (Caylor & Perkins, 2013).

American College of Radiology (ACR) 
The ACR released their updated guidelines concerning the follow-up of Hodgkin lymphoma in 2014. They state that “limited data are available on the role of routine blood work in detecting relapses.” ESR is listed as one of the tests conducted as routine blood work in follow-up of Hodgkin lymphoma. They summarize their findings as the following: “In general a majority of recurrences can be detected initially by history and physical examination rather than by routine imaging studies or blood tests such as ESR, CBC, and chemistry” (Ha et al., 2014). Four of the five variants they reviewed had ESR tests conducted one to two times per year, and the ACR rated the use of ESR as a 3, 5, 5, and 7 in these four variants where a “3” indicates “usually not appropriate,” a “5” is “may be appropriate”, and a “7” falls in the “usually appropriate” category.

The ACR released guidelines concerning management of multi-system inflammatory syndrome in children and devised a two-tier algorithm for diagnosis. ACR recommends routine lab tests as tier one testing, including complete blood count with manual differential, comprehensive metabolic panel, erythrocyte sedimentation rate [ESR], CRP measurement, and testing for SARS-CoV-2 by polymerase chain reaction or serology. If tier one lab results include CRP ≥ 5 or ESR ≥ 40 and one suggestive lab feature such as neutrophilia, lymphopenia, thrombocytopenia, hyponatremia, or hypoalbuminemia, the child should undergo tier two testing, which involves EKG and echocardiogram (Henderson et al., 2020; Henderson et al., 2021).

The British Society for Rheumatology (BSR) & British Health Professionals in Rheumatology (BHPR) 
In 2010, BSR and BHPR issued joint guidelines concerning the management of giant cell arteritis (GCA) (Dasgupta, 2010; Dasgupta, Borg, Hassan, Alexander, et al., 2010). They recommend “early recognition and diagnosis of GCA is paramount. Particular attention should be paid to the predictive features of ischaemic neuro-ophthalmic complications.” As part of this diagnostic recommendation, they specifically list laboratory tests that should be included — “full blood count, urea and electrolytes, liver function tests, CRP, ESR.” They note that, although elevated ESR and CRP levels are hallmarks of GCA, “GCA can occur in the face of lower levels of inflammatory markers, if the clinical picture is typical.” Another specific recommendation states, “Monitoring of therapy should be clinical and supported by the measurement of inflammatory markers (C; this is a consensus statement)” and that at each visit “full blood count, ESR/CRP, urea and electrolytes, [and] glucose” lab tests be performed.

Also, in 2010, BSR and BHPR issued joint guidelines concerning the management of polymyalgia rheumatica (PMR) (Dasgupta, Borg, Hassan, Barraclough, et al., 2010). For PMR, they recommend initial lab testing for diagnosis to include either ESR and/or CRP prior to initiating long-term steroid therapy. Also, during such therapy, they recommend monitoring either ESR or CRP every three months. This is a portion of the recommendation (B) of “vigilant monitoring of patients for response to treatment and disease activity.” In the 2024 update, the guidelines readdress that “the diagnosis of PMR is based on symptoms, signs and laboratory markers with a directed search for other conditions that can mimic PMR” these laboratory markers include acute phase reactants including C-reactive protein, erythrocyte sedimentation rate and plasma viscosity. “The evidence base for monitoring and follow-up for people with PMR is lacking. The current recommendations are consensus-based and guided by expert opinion. Some guidelines suggest that follow-up frequency could be as frequent as 1 – 4 weeks until disease remission, while other guidelines suggest every 1 – 4 months in the first year of diagnosis” (Toyoda et al., 2024). 

The British Society for Rheumatology (BSR) 
The BSR alone issued their guidelines for the management of systemic lupus erythematosus (SLE) in 2018 (Gordon et al., 2018). For the statement “CRP low or normal unless infection,” the BSR gives an overall level of evidence of 2++ with a B grade of recommendation whereas they grade the statement “ESR correlates with active lupus” a 2+ and only a C grade of recommendation. “ESR is often raised in active SLE, but can also reflect persistent polyclonal hypergammaglobulinaemia, and is not a reliable marker of disease activity. … A significantly raised CRP is more likely to indicate infection, and patients with raised CRP will need therefore to be thoroughly screened for infection, given that infection is the commonest cause of death in lupus patients. In contrast, a raised ESR does not discriminate between active lupus and infection.” They recommend that CRP is tested at initial diagnosis and then every 1 
– 3 months during active disease states. Once stabilized, then testing frequency can be every 6 – 12 months. They also state that CRP testing should be conducted on mothers with SLE during pregnancy, but they do not state the frequency of the testing during pregnancy. This guideline is currently in revision.

The BSR has also published guidelines on the diagnosis and treatment of giant cell arteritis (GCA). Regarding which evaluations should be performed when starting treatment, the BSR states that “When starting glucocorticoids for suspected GCA, diagnostically relevant symptoms and signs should be documented. Blood should be taken for full blood count, CRP and ESR before or immediately after commencing high-dose glucocorticoids. If GCA is strongly suspected, the first dose of glucocorticoid can be given without waiting for laboratory results” (Mackie et al., 2020). Further, the BSR provides a list of clinical assessments which should be carried out at or near a GCA diagnosis. These lists include “Measures of activity of GCA: laboratory markers of inflammation (CRP for all patients, plus either ESR or plasma viscosity) and full blood count (platelet count may be elevated in GCA).” Finally, regarding follow-up visits, “Each follow-up visit should include at least a full history, targeted physical examination and measurement of at least a full blood count, ESR and/or CRP, plus follow-up of any abnormalities relevant to the individual patient as well as drug-specific screening for toxicity” (Mackie et al., 2020). Revision for this guideline will be considered in 2024.

Canadian Rheumatology Association (CRA) 
The 2012 guidelines by the CRA titled “Canadian Rheumatology Association Recommendations for Pharmacological Management of Rheumatoid Arthritis with Traditional and Biologic Disease-modifying Antirheumatic Drugs” recommends (with Level II and Strength B) “the presence of the following poor prognostic features should be assessed at baseline and considered when making treatment decisions: RF positivity, anti-CCP positivity, functional limitation, high number of swollen and tender joints, early erosions, extraarticular features, high ESR or CRP.” They also recommend (with Level I and Strength A) “RA care providers should monitor disease activity as frequently as every 1 to 3 months in patients with active RA.” The disease activity should be monitored by a validated method, such as DAS28 or SDAI. The most recent updated “living guidelines” for this statement does not include prognostic features or make recommendations for factors included in treatment decisions (Hazlewood et al., 2022). 

In 2018, CRA released guidelines on assessment and monitoring of Systemic Lupus Erythematosus. Regarding diagnosis, CRA recommends that best clinical practice includes a complete history and physical examination at baseline with laboratory monitoring which could possibly include (but is not limited to) the following tests: “complete blood count (CBC), liver enzymes, creatine kinase, creatinine and estimated glomerular filtration rate (eGFR), urine routine/microscopic (urinalysis), urine protein-creatinine ratio, C-reactive protein (CRP), erythrocyte sedimentation rate (ESR), complements (C3, C4), anti-dsDNA, antinuclear antibodies, antibodies to extractable nuclear antigens, antiphospholipid antibodies (aPL), lupus anticoagulant (LAC), anticardiolipin (aCL), anti-β2-glycoprotein I (anti-β2-GPI), and lipid profile. Follow up laboratory monitoring will depend on the patient’s clinical status and may include CBC, eGFR, urinalysis, urine protein-creatinine ratio, CRP, and/or ESR, C3, C4, and anti-dsDNA antibodies” (Keeling et al., 2018).

Joint Task Force on Practice Parameters (JTFPP) of the Academy of Allergy, Asthma & Immunology (AAAAI); the American College of Allergy, Asthma & Immunology (ACAAI); and the Joint Council of Allergy, Asthma & Immunology 
The JTFPP within their guidelines concerning the diagnosis and management of acute and chronic urticaria state, “Targeted laboratory testing based on history or physical examination findings is appropriate, and limited laboratory testing can be obtained. Limited laboratory testing includes a CBC with differential, sedimentation rate, and/or C-reactive protein, liver enzyme, and thyroid-stimulating hormone (TSH) measurement. … Targeted laboratory testing based on history and/or physical examination (eg, obtaining TSH in a patient with weight gain, heat/cold intolerance, and thyromegaly) is recommended” (Bernstein et al., 2014).

National Institute for Health and Care Excellence (NICE) 
The NICE first issued the guidelines concerning irritable bowel syndrome (IBS) in 2008 with updates in 2015 and 2017. In individuals who meet the IBS diagnostic criteria, they recommend ESR and CRP along with full blood count and antibody testing for celiac disease or tissue transglutaminase to exclude other possible diagnoses. They do not state anything concerning follow-up testing of either ESR or CRP (NICE, 2017).

In 2020, NICE issues guidelines concerning management of rheumatoid arthritis (RA). In adults with active RA, they recommend measuring CRP and disease activity monthly in specialist care until remission or low disease activity is achieved (NICE, 2020). 

American Gastroenterological Association
In a 2019 guideline, the AGA provides recommendations on the use of ESR and CRP in patients presenting with chronic diarrhea:

  • “Recommendation 2: In patients presenting with chronic diarrhea, the AGA suggests against the use of erythrocyte sedimentation rate or C-reactive protein to screen for IBD. Conditional recommendation: low-quality evidence” (Smalley et al., 2019).

The AGA notes that while there are “few settings where ESR should be considered as an appropriate screening test for IBD, there are some settings where the use of CRP might be a rational option. For example, if testing for fecal lactoferrin or calprotectin are either not available or not covered by insurance, the use of CRP might be considered to be a reasonable option to screen for IBD” (Smalley et al., 2019).

American Academy of Orthopaedic Surgeons (AAOS)
The AAOS notes that “Strong evidence supports the use of [ESR and CRP] to aid in the preoperative diagnosis of prosthetic joint infection (PJI).” However, the AAOS remarks that neither biomarker is perfectly accurate for PJI diagnosis and should not be used as sole tests for diagnosis. Critically, neither marker informs clinicians of the microbiology of the PJI.

These guidelines were endorsed by IDSA, the American College of Radiology, and the Society of Nuclear Medicine and Molecular Imaging (AAOS, 2019).

Pediatric Infectious Diseases Society and the Infectious Diseases Society of America 
In 2021, a guideline was released on the diagnosis and management of Acute Hematogenous Osteomyelitis (AHO) in pediatrics. In children with suspected AHO, they recommend performing a serum C-reactive protein (CRP) on initial evaluation. "Serum CRP has a low accuracy to establish the diagnosis of AHO, but in situations where AHO is confirmed, the serum CRP performed on initial evaluation can serve as the baseline value for sequential monitoring." They recommend against using serum PCT. In terms of ESR, they comment that the ESR is no longer used routinely to diagnose AHO in children. "ESR combined with CRP may slightly improve sensitivity and negative predictive value for the diagnosis of AHO, but specific thresholds and the overall clinical utility of using both CRP and ESR for diagnostic purposes remain uncertain” (Woods et al., 2021). 

“There are no data to support a particular frequency of CRP monitoring during the course of AHO in children. Measurement every 2 to 3 days during the early therapeutic course, rather than daily, followed by weekly or other periodic measurement until normalization (or a clear trend toward normalization is evident) is an acceptable approach” (Woods et al., 2021).

Government of British Columbia 
The government of British Columbia provides practitioner and professional guidelines, including a guideline on CRP and ESR. Within this guideline, they provide key recommendations:

  • “CRP is the preferred first test to support a diagnosis of inflammatory or infectious conditions, rather than ESR. There is no indication for ordering ESR when CRP is elevated.
  • According to the British Columbia Laboratory Services Outpatient Payment Schedule, ESR will be performed only if a written indication is provided on the requisition. If CRP and ESR are ordered together, most outpatient laboratories will only perform CRP because only CRP is payable.
  • Clinical features that together may prompt a requisition for CRP are:
    • unexplained symptoms or a deterioration of health status; and
    • an inflammatory or infectious disease is suspected; and
    • a specific diagnosis is not made effectively by other means.
  • Repeat testing for CRP depends on the clinical status of the patient. It may be used in routine monitoring of patients with inflammatory arthritis and other rheumatic conditions. For most infections, repeat CRP is not indicated and assessment should be made on clinical grounds (e.g., when following treatment of cellulitis,2 pneumonia or urinary tract infections).
  • The only indication for CRP assessment in asymptomatic individuals is in the stratification of cardiovascular risk. High sensitivity (hs) CRP is one of several tools which may be used in patients at intermediate cardiovascular risk to help decide whether a statin should be started. If hsCRP is desired, it should be specifically requested on the laboratory requisition” (Government of British Columbia, 2023)

References

  1. AAOS. (2019). Diagnosis and Prevention of Periprosthetic Joint Infections Clinical Practice Guideline. https://www.aaos.org/globalassets/quality-and-practice-resources/pji/pji-clinical-practice-guideline-final-2-17-21.pdf 
  2. Alende-Castro, V., Alonso-Sampedro, M., Fernández-Merino, C., Sánchez-Castro, J., Sopeña, B., Gude, F., & Gonzalez-Quintela, A. (2021). C-Reactive Protein versus Erythrocyte Sedimentation Rate: Implications Among Patients with No Known Inflammatory Conditions. J Am Board Fam Med, 34(5), 974-983. https://doi.org/10.3122/jabfm.2021.05.210072 
  3. Anderson, J., Caplan, L., Yazdany, J., Robbins Mark, L., Neogi, T., Michaud, K., Saag Kenneth, G., O'Dell James, R., & Kazi, S. (2012). Rheumatoid arthritis disease activity measures: American College of Rheumatology recommendations for use in clinical practice. Arthritis Care & Research, 64(5), 640-647. https://doi.org/10.1002/acr.21649 
  4. Arnold, M. J. (2022). Management of Rheumatoid Arthritis: Update From ACR. Am Fam Physician, 106(3), 340-342. 
  5. ASCP. (2020, September 1). Don't order an erythrocyte sedimentation rate (ESR) to look for inflammation in patients with undiagnosed conditions. ABIM Foundation. Retrieved 06/12/2018 from https://www.ascp.org/content/docs/default-source/get-involved-pdfs/istp_choosingwisely/ascp-35-things-list_2020_final.pdf
  6. Aster, J. C., & Pozdnyakova, O. (2022, January 31). Epidemiology, pathologic features, and diagnosis of classic Hodgkin lymphoma. Wolters Kluwer. https://www.uptodate.com/contents/epidemiology-pathologic-features-and-diagnosis-of-classic-hodgkin-lymphoma
  7. Baddour, L., & Chen, A. (2023, August 14). Prosthetic joint infection: Epidemiology, microbiology, clinical manifestations, and diagnosis. https://www.uptodate.com/contents/prosthetic-joint-infection-epidemiology-microbiology-clinical-manifestations-and-diagnosis
  8. Baker, J. F. (2024, March 21). Diagnosis and differential diagnosis of rheumatoid arthritis. Wolters Kluwer. https://www.uptodate.com/contents/diagnosis-and-differential-diagnosis-of-rheumatoid-arthritis
  9. Berbari, E., Mabry, T., Tsaras, G., Spangehl, M., Erwin, P. J., Murad, M. H., Steckelberg, J., & Osmon, D. (2010). Inflammatory blood laboratory levels as markers of prosthetic joint infection: a systematic review and meta-analysis. J Bone Joint Surg Am, 92(11), 2102-2109. https://doi.org/10.2106/jbjs.I.01199 
  10. Bernstein, J. A., Lang, D. M., Khan, D. A., Craig, T., Dreyfus, D., Hsieh, F., Sheikh, J., Weldon, D., Zuraw, B., Bernstein, D. I., Blessing-Moore, J., Cox, L., Nicklas, R. A., Oppenheimer, J., Portnoy, J. M., Randolph, C. R., Schuller, D. E., Spector, S. L., Tilles, S. A., & Wallace, D. (2014). The diagnosis and management of acute and chronic urticaria: 2014 update. J Allergy Clin Immunol, 133(5), 1270-1277. https://doi.org/10.1016/j.jaci.2014.02.036 
  11. Bingham, J. S., Hassebrock, J. D., Christensen, A. L., Beauchamp, C. P., Clarke, H. D., & Spangehl, M. J. (2019). Screening for Periprosthetic Joint Infections With ESR and CRP: The Ideal Cutoffs. J Arthroplasty. https://doi.org/10.1016/j.arth.2019.11.040 
  12. Bitik, B., Mercan, R., Tufan, A., Tezcan, E., Küçük, H., İlhan, M., Öztürk, M. A., Haznedaroğlu, S., & Göker, B. (2015). Differential diagnosis of elevated erythrocyte sedimentation rate and C-reactive protein levels: a rheumatology perspective. European Journal of Rheumatology, 2(4), 131-134. https://doi.org/10.5152/eurjrheum.2015.0113 
  13. Black, S., Kushner, I., & Samols, D. (2004). C-reactive Protein. J Biol Chem, 279(47), 48487-48490. https://doi.org/10.1074/jbc.R400025200 
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Coding Section

CPT 85651 Sedimentation rate, erythrocyte; non-automated
  85652 Sedimentation rate, erythrocyte; automated
  86140 C-reactive protein
  86141 C-reactive protein; High Sensitivity (HSCRP)

Procedure and diagnosis codes on Medical Policy documents are included only as a general reference tool for each policy. They may not be all-inclusive. 

This medical policy was developed through consideration of peer-reviewed medical literature generally recognized by the relevant medical community, U.S. FDA approval status, nationally accepted standards of medical practice and accepted standards of medical practice in this community, Blue Cross Blue Shield Association technology assessment program (TEC) and other nonaffiliated technology evaluation centers, reference to federal regulations, other plan medical policies, and accredited national guidelines.

"Current Procedural Terminology © American Medical Association. All Rights Reserved" 

History From 2024 Forward     

10/25/2024 Annual review, updating note 1 which addresses which testing aligns with specific diagnoses. Also updating table of terminology, rationale and references.
07/29/2024 Changing the Review date to 10/01/2024
01/01/2024 New Policy
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