Procalcitonin as a biomarker of infectious diseases

Article information

Korean J Intern Med. 2013;28(3):285-291

Publication date (electronic) : 2013 May 01

doi : https://doi.org/10.3904/kjim.2013.28.3.285

Division of Infectious Diseases, Department of Internal Medicine, Dong-A University Hospital, Busan, Korea.

Correspondence to Hyuck Lee, M.D. Division of Infectious Diseases, Department of Internal Medicine, Dong-A University Hospital, 26 Daesingongwon-ro, Seo-gu, Busan 602-715, Korea. Tel: +82-51-240-5047, Fax: +82-51-243-5047, hleeid@dau.ac.kr

Received 2013 February 05; Accepted 2013 March 07.

Abstract

Traditional biomarkers, including C-reactive protein, leukocytes, erythrocyte sedimentation rate, and clinical signs and symptoms, are not sufficiently sensitive or specific enough to guide treatment decisions in infectious febrile diseases. Procalcitonin (PCT) is synthesized by a large number of tissues and organs in response to invasion by pathogenic bacteria, fungi, and some parasites. A growing body of evidence supports the use of PCT as a marker to improve the diagnosis of bacterial infections and to guide antibiotic therapy. Clinically, PCT levels may help guide the need for empirical antibiotic therapy, source control for infections, and duration of antibiotic therapy. The aim of this review is to summarize the current evidence for PCT in different infections and clinical settings, and to discuss the reliability of this marker in order to provide physicians with an overview of the potential for PCT to guide antibiotic therapy.

Keywords: Biological markers; Procalcitonin; Antibiotic guidance; Sepsis

INTRODUCTION

Diagnostic biomarkers have been successfully implemented in several fields of medicine (e.g., D-dimers in pulmonary embolism, natriuretic peptides in acute heart failure, and troponin in myocardial infarction). However, the timely diagnosis of bacterial infections remains a challenge [1]. Reliable clinical and/or microbiological parameters from easy to obtain specimens that may be used to diagnose bacterial infections and rule out other infections are mostly lacking. The main disadvantages of many current microbiological methods are diagnostic delays, such as those that occur with culture methods, suboptimal sensitivity for samples like blood cultures, and low specificity due to contamination in samples like sputum cultures, whereas others, such as lung biopsies, are not amenable to routine diagnostics due to their invasive nature. Furthermore, inflammatory markers, including C-reactive protein (CRP) and white blood cells (WBC), lack specificity for bacterial infections [2].

Recent advances in biotechnology and the sequencing of the human genome offer unprecedented opportunities to increase our understanding of critical illness and injury [3]. The early detection of infection has both physiologic and clinical importance. The earlier an injurious process can be identified, the more timely additional preventive (i.e., removal of a stimulus for injury) and potential therapeutic measures can be initiated [4].

Procalcitonin (PCT) has emerged as a promising marker for the diagnosis of bacterial infections because higher levels of PCT are found in severe bacterial infections relative to viral infections and nonspecific inflammatory diseases. Hence, PCT may be used to support clinical decisions regarding the initiation or discontinuation of antibiotic therapy [5,6]. The clinical utility of serum PCT levels continues to evolve [7]. PCT is regarded as a promising candidate marker for making a diagnosis and antibiotic stewardship in patients with systemic infections [1].

Importantly, as with any diagnostic tool, PCT use should be embedded in clinical algorithms adapted to the type of infection and the clinical context and setting. While optimal PCT level cutoffs have been established for some types of infections and clinical settings and their safety and efficacy shown in randomized-controlled intervention trials, for other types of infection only observational studies are available. Thus, the clinical benefit and safety of using PCT remains undefined [8].

The aim of this review is to summarize the current evidence for PCT in different infections and clinical settings, to discuss the strengths and limitations of PCT, and to summarize the reliability of this marker when used with validated diagnostic algorithms.

PCT BIOLOGY

Although PCT is the prohormone for calcitonin, its biologic activities are distinctly different [9]. In the C cells of the thyroid gland and K cells of the lung, elevated serum calcium concentrations or neoplastic changes result in transcription of the PCT gene. Subsequently, ribosomal synthesis of the 116-amino-acid PCT molecule occurs, with subsequent cleavage of amino acids 60 to 91 yielding calcitonin. Calcitonin's only recognized biologic activity is to lower the serum calcium concentration by inhibiting bone resorption [7]. Hormones are exclusively produced in endocrine cells and act systemically. Cytokines are produced by multiple cells and have local effects.

Hormokines can exhibit either classical hormonal expression, or, upon inflammatory stimulation, show more cytokine-like behavior [10,11]. Ubiquitous inflammatory release can be induced directly via microbial toxins (e.g., endotoxin), or indirectly via a humoral or cell-mediated host response (e.g., interleukin [IL]-1β, tumor necrosis factor [TNF]-α, and IL-6). Parenchymal cells, including liver cells, kidney cells, adipocytes, and muscle cells, provide the largest tissue mass and principal source of circulating hormokines in sepsis [11].

PCT is markedly elevated (up to 5,000-fold) within 2 to 4 hours in severe forms of systemic inflammation or in bacterial infections, and the level persists until recovery [7,12,13]. The biological half-life of PCT is 22 to 26 hours, an advantageous time point compared with CRP and other acute-phase reactants [14]. Distinct from CRP and other acute-phase reactants, existing data suggest that PCT levels rarely increase in response to viral infections, indicating that PCT may be useful for discrimination between bacterial and viral infections. The lack of viral response is postulated to result from the virus-stimulated synthesis of α-interferon by macrophages, which, in turn, inhibits TNF synthesis. The predictive value of PCT has been tested in several studies and in a recent prospective, multicenter study (Fig. 1) [15]. PCT is useful not only for monitoring bacterial infections but also for the differential diagnosis of systemic inflammatory response syndrome, which is a serious medical condition [15,16]. There are likely other biologic roles for PCT, beyond signaling bacterial invasion, which require further study [7,12].

Figure 1

Receiver operating characteristic curve analysis of the serum levels of procalcitonin (solid circles), C-reactive protein (open circles), interleukin (triangles), and lactate (open triangles).

PCT ASSAYS

Although it would be highly desirable, there is no research or clinical assay that exclusively detects the 116-kDa PCT peptide. Depending on the type of assay, all tests detect various portions of several computed tomography precursors (Table 1). Based on a highly sensitive research assay, the normal level of PCT in an uninfected individual is 0.033 ± 0.003 ng/mL. The first commercial PCT assay (LUMI test) has a functional lower limit of sensitivity of 0.5 ng/mL. The second-generation Food and Drug Administration (FDA)-approved PCT assay is technically a time-resolved cryptate emission immunoassay. The assay quantifies both PCT and part of the N-terminal end of the PCT molecule. The functional lower limit of sensitivity is 0.05 ng/mL, and the assay has reliable linear quantitation to 1,000 ng/mL. Either serum or plasma is used, and results are available in 1 hour or less [7,17].

Table 1

Principle causes of hyperprocalcitoninemia

CLINICAL USEFULNESS OF PCT IN INFECTIOUS DISEASES

The clinical evaluation of PCT levels continues. At present, there are four common uses of PCT levels. First, the current immunoassay was approved by the FDA for establishing the likelihood of mortality in critically ill septic patients [15]. Second, PCT levels have been used to guide empirical antibacterial therapy in patients with acute exacerbations of chronic bronchitis, community-acquired pneumonia (CAP), and sepsis [1,18]. Third, PCT levels, along with standard clinical parameters, can assist in determining whether the patient's empirical antibacterial therapy is effective [1]. Finally, the most useful application is the use of sequential PCT levels to determine when there is no longer a need for antibacterial therapy [7,19].

Correlation of PCT with the severity of sepsis

PCT has been demonstrated to be most useful clinically and superior to commonly obtained clinical variables and other laboratory tests in the diagnosis of sepsis, and it is correlated with the extent and severity of microbial invasion [20-22]. Unlike other diagnostic biomarkers, including CRP, there is strong evidence from animal studies that PCT plays a pathophysiological role in the development of severe sepsis and associated mortality [23]. PCT correlates with the extent and severity of infection and has prognostic implications, as the course of PCT predicts the risk of mortality in critically ill patients with infections and in patients with ventilator-associated pneumonia [16]. Furthermore, the production of PCT, in contrast to other biomarkers, including CRP, seems not to be significantly attenuated by nonsteroidal and steroidal anti-inflammatory drugs [24].

PCT for the guidance of antibiotic therapy in respiratory tract infections

As PCT levels increase upon bacterial infection and decrease upon recovery, they can be used to guide antibiotic therapy in individual patients as a surrogate biomarker [25,26]. Highly sensitive PCT assays are needed to reliably diagnose CAP and non-CAP lower respiratory tract infections (RTIs) [1,17]. Two low PCT measurements, over the first 4 to 6 hours of hospital admission, resulted in fewer patients started on empirical antibacterials. Low PCT levels over the first 4 hours of inpatient care have an excellent negative predictive value for bacterial infection [18].

PCT for antibiotic guidance in other infections

PCT has been proposed to be a promising marker for reliably distinguishing bacterial infections from other types of infections, including neutropenic fever, fungal infections, postoperative fever, arthritis, and suspected bloodstream infections [27-29]. Importantly, with the exception of RTIs, meningitis, and sepsis within the intensive care unit, all published studies were observational and it remains uncertain whether PCT can be safely used for antibiotic guidance in different settings [30,31]. For some infections, PCT may not be sensitive enough for routine clinical use. In patients with subacute endocarditis, PCT levels may remain low and cannot be used to discriminate infected from uninfected patients. Similarly, in patients with a Mycoplasma or viral infection, PCT levels may remain low, while with other atypical pathogens such as Legionella pneumophila PCT shows a prominent increase upon infection. Conversely, in patients with hypothermia after cardiac arrest, high initial levels of PCT were found independent of an underlying infection. This increase in PCT was nonspecific and mirrored an inflammatory reaction rather than true infection, limiting the diagnostic potential for early antibiotic stewardship in these high-risk patients [7,18].

Antibiotic stewardship with PCT

Antimicrobial resistance has emerged as a major factor affecting patient outcomes and overall resources. This calls for more stringent efforts to reduce antibiotic overuse [23]. A variety of cutoffs have been reported [32]. When PCT is used to guide diagnostic and therapeutic decisions in patients with infections in medical practice, two important issues need to be considered in order to optimize diagnostic accuracy and patient safety: the functional assay sensitivity and cutoff ranges. All published studies on antibiotic stewardship used similar clinical algorithms with recommendations for and against antibiotic treatment based on PCT cutoff ranges. The algorithms specified one of four antibiotic recommendations, ranging from 'strongly discourage' and 'discourage' to 'recommend' and 'strongly recommend,' respectively. The PCT cutoff ranges were derived from multilevel-likelihood ratio calculations obtained in observational studies and reflect the likelihood of a bacterial infection. The feasibility and safety of these algorithms was prospectively investigated and repetitively validated in multiple randomized control trials by independent groups (Table 2). In the intensive care unit at our institution, a fall in the level of PCT to ≤ 0.1 ng/mL is used to signify the end of bacterial invasion and that it is safe to discontinue antibiotic therapy [33]. Several studies have successfully adopted this approach, rather than an arbitrary one size fits all duration of therapy. Virtually every study to date in patients with sepsis or pneumonia has demonstrated substantive decreases in the duration of antibacterial therapy when it is guided by sequential PCT levels [34-36].

Table 2

Use of procalcitonin levels for antimicrobial stewardship of respiratory tract infections

OTHER POTENTIAL USES OF PCT

PCT levels may help resolve the etiology of fever in patients with fever of unknown origin (FUO) syndrome, in that PCT levels do not increase in some disease entities that cause FUO syndrome (e.g., Still's disease, systemic lupus erythematosus, and inflammatory bowel disease) [18,37,38].

Initial data indicate that PCT levels are unaffected by patient use of nonsteroidal anti-inflammatory agents or glucocorticoids. If so, PCT levels remain a valuable marker of the host inflammatory response even when nonsteroidal anti-inflammatory drugs and pharmacologic doses of corticosteroids have altered the patient's temperature curve, WBC count, and WBC differential [24].

LIMITATIONS OF PCT

A number of limitations exist in using PCT as a marker of infection and sepsis. Nonspecific elevations in PCT levels in the absence of a bacterial infection can occur in situations of massive stress, such as after severe trauma and surgery, or in patients with cardiac shock [1,17]. This is the reason why the power of PCT to discriminate between sepsis and sterile inflammation is better for medical than for surgical patients Also, various other causes of nonbacterial systemic inflammation have been reported, including birth stress in newborns, heat shock, and acute graft-versus-host disease, as well as different types of immunotherapy, such as granulocyte transfusions, the administration of antilymphocyte globulin or anti-CD3 antibodies, and therapy with cytokines or related antibodies (IL-2 or TNF-α) [39]. Some autoimmune diseases such as Kawasaki disease or different types of vasculitis and paraneoplastic syndromes are also associated with elevated PCT levels [24].

CONCLUSIONS

Among the numerous markers of sepsis and infection that have been proposed, PCT is by far the most widely evaluated. This marker may help physicians make a diagnosis earlier, differentiate infectious from sterile causes of severe systemic inflammation, and assess the severity of systemic inflammation caused by bacterial infections.

There is a lot more to learn about PCT. The use of PCT, like any biomarker, should be considered within the context of the clinical workup and should take into account all patient related and therapy related factors that may interfere with the initial magnitude and course of this parameter.

Notes

No potential conflict of interest relevant to this article is reported.

References

1. Schuetz P, Albrich W, Mueller B. Procalcitonin for diagnosis of infection and guide to antibiotic decisions: past, present and future. BMC Med 2011;9:107. 21936959.

2. Muller B, Harbarth S, Stolz D, et al. Diagnostic and prognostic accuracy of clinical and laboratory parameters in community-acquired pneumonia. BMC Infect Dis 2007;7:10. 17335562.

3. Chung TP, Laramie JM, Province M, Cobb JP. Functional genomics of critical illness and injury. Crit Care Med 2002;30(1 Suppl):S51–S57.

4. Bagshaw SM, Bellomo R. Early diagnosis of acute kidney injury. Curr Opin Crit Care 2007;13:638–644. 17975383.

5. Schuetz P, Briel M, Christ-Crain M, et al. Procalcitonin to guide initiation and duration of antibiotic treatment in acute respiratory infections: an individual patient data meta-analysis. Clin Infect Dis 2012;55:651–662. 22573847.

6. Matthaiou DK, Ntani G, Kontogiorgi M, Poulakou G, Armaganidis A, Dimopoulos G. An ESICM systematic review and meta-analysis of procalcitonin-guided antibiotic therapy algorithms in adult critically ill patients. Intensive Care Med 2012;38:940–949. 22538461.

7. Gilbert DN. Use of plasma procalcitonin levels as an adjunct to clinical microbiology. J Clin Microbiol 2010;48:2325–2329. 20421436.

8. Schuetz P, Christ-Crain M, Muller B. Procalcitonin and other biomarkers to improve assessment and antibiotic stewardship in infections: hope for hype? Swiss Med Wkly 2009;139:318–326. 19529989.

9. Linscheid P, Seboek D, Nylen ES, et al. In vitro and in vivo calcitonin I gene expression in parenchymal cells: a novel product of human adipose tissue. Endocrinology 2003;144:5578–5584. 12960010.

10. Morgenthaler NG, Struck J, Fischer-Schulz C, Seidel-Mueller E, Beier W, Bergmann A. Detection of procalcitonin (PCT) in healthy controls and patients with local infection by a sensitive ILMA. Clin Lab 2002;48:263–270. 12071576.

11. Christ-Crain M, Muller B. Biomarkers in respiratory tract infections: diagnostic guides to antibiotic prescription, prognostic markers and mediators. Eur Respir J 2007;30:556–573. 17766633.

12. Pfafflin A, Schleicher E. Inflammation markers in point-of-care testing (POCT). Anal Bioanal Chem 2009;393:1473–1480. 19104782.

13. Brunkhorst FM, Heinz U, Forycki ZF. Kinetics of procalcitonin in iatrogenic sepsis. Intensive Care Med 1998;24:888–889. 9757936.

14. Limper M, de Kruif MD, Duits AJ, Brandjes DP, van Gorp EC. The diagnostic role of procalcitonin and other biomarkers in discriminating infectious from non-infectious fever. J Infect 2010;60:409–416. 20347867.

15. Muller B, Becker KL, Schachinger H, et al. Calcitonin precursors are reliable markers of sepsis in a medical intensive care unit. Crit Care Med 2000;28:977–983. 10809269.

16. Harbarth S, Holeckova K, Froidevaux C, et al. Diagnostic value of procalcitonin, interleukin-6, and interleukin-8 in critically ill patients admitted with suspected sepsis. Am J Respir Crit Care Med 2001;164:396–402. 11500339.

17. Aabenhus R, Jensen JU. Procalcitonin-guided antibiotic treatment of respiratory tract infections in a primary care setting: are we there yet? Prim Care Respir J 2011;20:360–367. 21808938.

18. Schuetz P, Albrich W, Christ-Crain M, Chastre J, Mueller B. Procalcitonin for guidance of antibiotic therapy. Expert Rev Anti Infect Ther 2010;8:575–587. 20455686.

19. Manian FA. Use of procalcitonin to guide duration of antimicrobial therapy in intensive care units: proceed with caution. Clin Infect Dis 2012;54:578. 22144546.

20. Tang BM, Eslick GD, Craig JC, McLean AS. Accuracy of procalcitonin for sepsis diagnosis in critically ill patients: systematic review and meta-analysis. Lancet Infect Dis 2007;7:210–217. 17317602.

21. Uzzan B, Cohen R, Nicolas P, Cucherat M, Perret GY. Procalcitonin as a diagnostic test for sepsis in critically ill adults and after surgery or trauma: a systematic review and meta-analysis. Crit Care Med 2006;34:1996–2003. 16715031.

22. Meisner M, Tschaikowsky K, Palmaers T, Schmidt J. Comparison of procalcitonin (PCT) and C-reactive protein (CRP) plasma concentrations at different SOFA scores during the course of sepsis and MODS. Crit Care 1999;3:45–50. 11056723.

23. Reinhart K, Meisner M. Biomarkers in the critically ill patient: procalcitonin. Crit Care Clin 2011;27:253–263. 21440200.

24. Reinhart K, Bauer M, Riedemann NC, Hartog CS. New approaches to sepsis: molecular diagnostics and biomarkers. Clin Microbiol Rev 2012;25:609–634. 23034322.

25. Li H, Luo YF, Blackwell TS, Xie CM. Meta-analysis and systematic review of procalcitonin-guided therapy in respiratory tract infections. Antimicrob Agents Chemother 2011;55:5900–5906. 21947386.

26. Schuetz P, Christ-Crain M, Thomann R, et al. Effect of procalcitonin-based guidelines vs standard guidelines on antibiotic use in lower respiratory tract infections: the ProHOSP randomized controlled trial. JAMA 2009;302:1059–1066. 19738090.

27. Gac AC, Parienti JJ, Chantepie S, et al. Dynamics of procalcitonin and bacteremia in neutropenic adults with acute myeloid leukemia. Leuk Res 2011;35:1294–1296. 21831426.

28. Perrakis A, Yedibela S, Schellerer V, Hohenberger W, Muller V. Procalcitonin in the setting of complicated postoperative course after liver transplantation. Transplant Proc 2010;42:4187–4190. 21168660.

29. Sakr Y, Sponholz C, Tuche F, Brunkhorst F, Reinhart K. The role of procalcitonin in febrile neutropenic patients: review of the literature. Infection 2008;36:396–407. 18759057.

30. Jereb M, Muzlovic I, Hojker S, Strle F. Predictive value of serum and cerebrospinal fluid procalcitonin levels for the diagnosis of bacterial meningitis. Infection 2001;29:209–212. 11545482.

31. Schwarz S, Bertram M, Schwab S, Andrassy K, Hacke W. Serum procalcitonin levels in bacterial and abacterial meningitis. Crit Care Med 2000;28:1828–1832. 10890628.

32. Bouadma L, Luyt CE, Tubach F, et al. Use of procalcitonin to reduce patients' exposure to antibiotics in intensive care units (PRORATA trial): a multicentre randomised controlled trial. Lancet 2010;375:463–474. 20097417.

33. Kopterides P, Siempos II, Tsangaris I, Tsantes A, Armaganidis A. Procalcitonin-guided algorithms of antibiotic therapy in the intensive care unit: a systematic review and meta-analysis of randomized controlled trials. Crit Care Med 2010;38:2229–2241. 20729729.

34. Stolz D, Smyrnios N, Eggimann P, et al. Procalcitonin for reduced antibiotic exposure in ventilator-associated pneumonia: a randomised study. Eur Respir J 2009;34:1364–1375. 19797133.

35. Nobre V, Harbarth S, Graf JD, Rohner P, Pugin J. Use of procalcitonin to shorten antibiotic treatment duration in septic patients: a randomized trial. Am J Respir Crit Care Med 2008;177:498–505. 18096708.

36. Riedel S. Procalcitonin and antibiotic therapy: can we improve antimicrobial stewardship in the intensive care setting? Crit Care Med 2012;40:2499–2500. 22809920.

37. Kim HA, Jeon JY, An JM, Koh BR, Suh CH. C-reactive protein is a more sensitive and specific marker for diagnosing bacterial infections in systemic lupus erythematosus compared to S100A8/A9 and procalcitonin. J Rheumatol 2012;39:728–734. 22337236.

38. Hunziker S, Hugle T, Schuchardt K, et al. The value of serum procalcitonin level for differentiation of infectious from noninfectious causes of fever after orthopaedic surgery. J Bone Joint Surg Am 2010;92:138–148. 20048106.

39. Becker KL, Snider R, Nylen ES. Procalcitonin assay in systemic inflammation, infection, and sepsis: clinical utility and limitations. Crit Care Med 2008;36:941–952. 18431284.

Article information Continued

(open-access, http://creativecommons.org/licenses/by-nc/3.0/) :

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.