Effect of iron therapy on platelet counts in patients with inflammatory bowel disease-associated anemia.

BACKGROUND AND AIMS: Secondary thrombocytosis is a clinical feature of unknown significance. In inflammatory bowel disease (IBD), thrombocytosis is considered a marker of active disease; however, iron deficiency itself may trigger platelet generation. In this study we tested the effect of iron therapy on platelet counts in patients with IBD-associated anemia.
METHODS: Platelet counts were analyzed before and after iron therapy from four prospective clinical trials. Further, changes in hemoglobin, transferrin saturation, ferritin, C-reactive protein, and leukocyte counts, before and after iron therapy were compared. In a subgroup the effect of erythropoietin treatment was tested. The results were confirmed in a large independent cohort (FERGIcor).
RESULTS: A total of 308 patient records were available for the initial analysis. A dose-depended drop in platelet counts (mean 425 G/L to 320 G/L; p<0.001) was found regardless of the type of iron preparation (iron sulphate, iron sucrose, or ferric carboxymaltose). Concomitant erythropoietin therapy as well as parameters of inflammation (leukocyte counts, C-reactive protein) had no effect on the change in platelet counts. This effect of iron therapy on platelets was confirmed in the FERGIcor study cohort (n=448, mean platelet counts before iron therapy: 383 G/L, after: 310 G/L, p<0.001).
CONCLUSION: Iron therapy normalizes elevated platelet counts in patients with IBD-associated anemia. Thus, iron deficiency is an important pathogenetic mechanism of secondary thrombocytosis in IBD.

Introduction

Platelets (thrombocytes) are small anuclear cell fragments that derive from mature megakaryocytes. Adult humans produce about 100 billion thrombocytes per day. The primary role of thrombocytes in mammalians is to ensure hemostasis by binding to von-Willebrand factor and fibrinogen. In addition, platelets are a source of pro-inflammatory and anti-microbial mediators [1]–[3]. An increase in the circulating number of platelets, i.e. thrombocytosis, may occur under certain circumstances such as neoplastic proliferative diseases (i.e. essential thrombocytosis) or secondary to other conditions such as hypo- or asplenism, but is also found with acute and chronic inflammation, malignant disease, blood loss or iron deficiency [4]. Except for hypo- or asplenism, the mechanism underlying secondary thrombocytosis and its clinical significance are not completely understood. Enhanced megakaryopoiesis may result from an increase of megakaryocytic growth factors such as thrombopoietin, interleukin (IL)-3, IL-6 or IL-11 [5]. However, the data on this are vague and further investigation of this topic is needed.

About one third of patients with inflammatory bowel disease (IBD) suffer from anemia [6]–[9]. IBD-associated anemia is caused by a combination of anemia of chronic disease and iron deficiency [10]. Accordingly, guidelines recommend iron replacement in combination with anti-inflammatory drugs and/or erythropoietin [11], [12]. Secondary thrombocytosis is another clinical feature of IBD that has been associated with active disease [13]. Some authors propose that activated platelets are involved in the pathogenesis of IBD [14], [15]. So far the relative importance of iron deficiency for IBD-associated thrombocytosis has not been elucidated. Here we tested the effect of iron therapy on changes in platelet counts in two large cohorts of patients with IBD-associated anemia.

Results

The initial cohort consisted of a total of 323 patients (40 from the Crohn study, 20 from the Colitis Study, 63 from the Predict Study, and 200 from the Ferric carboxymaltose Study, Figure 1). From 308 patients platelets data were available for analysis. Patients were further divided into “intravenous iron" (three dose groups: “800–1200 mg iron", “1201–2000 mg iron", “ 2001–3600 mg iron") and “oral iron" (200 mg per day). Overall, the mean (SD) platelet counts dropped from 425 (153) G/L at study entry to 320 (101) G/L after iron treatment (table 1, p<0.001). This effect was observed with both intravenous (iron sucrose or ferric carboxymaltose) and oral (iron sulphate) iron products (figure 2A) and was dose-dependent (figure 2B, p=0.002). Hemoglobin, transferrin saturation and ferritin improved as expected, C-reactive protein and leukocyte counts did not change (table 1).

Figure 1

Primary dataset analysis.

* FCM=ferric carboxymaltose. ** cumulative iron dose. Plt=platelets.

Table 1

Changes in laboratory parameters upon iron treatment (primary dataset n=307).

	Pre iron	Post iron	N	p value
Platelets G/L	425 (153)	320 (101)	308	<0.001
Hemoglobin g/dL	8.8 (1.4)	12.2 (1.7)	308	<0.001
Leukocytes G/L	8.9 (3.3)	8.7 (3.2)	121	0.577
C-reactive protein mg/dL*	0.8 (0–15.2)	0.7 (0–24)	303	0.735
Ferritin µg/L*	6 (0–407)	68 (1–1920)	301	<0.001
Transferrin saturation %*	3 (0.5–49)	16.1 (1–98)	302	<0.001

Continuous data given as mean (SD) or *median (range).

Figure 2

The changes in platelet counts upon iron therapy.

(A) Platelet counts pre and post iron replacement therapy according to iron preparation (black column – iron sucrose n=122, grey column – ferric carboxymaltose n=130, white column – iron sulphate n=56), p<0.001 pre vs. post for all iron preparations. (B) Mean drop in platelet counts upon intravenous iron replacement therapy according to the cumulative iron dose (p=0.002). Group 0–1200 mg n=97, group 1201–2000 mg n=103, group 2001–3600 mg n=52. Error bars represent standard deviation.

In the “Crohn study" patients had been randomized to erythropoietin or placebo treatment but all patients had received iron sucrose. To test whether erythropoietin may interfere with the drop in platelet counts, the two treatment groups were compared and serum erythropoietin levels were analyzed every week. Platelets dropped to a similar extent and speed in the erythropoietin and the placebo group (average change in platelet counts per week −3.7% [95% CI −2.5, −4.9] versus −4.0% [−3.0, −5.0]; p=0.703) despite different changes of serum erythropoietin levels (average change in erythropoietin levels per week −5.5% [95% CI 0.4, −11] versus −14% [−9.8, −18] p=0.021, figure 3). These data suggest that erythropoietin had no effect on the change in platelet levels upon iron therapy.

Figure 3

The changes of platelet counts and erythropoietin levels.

Continuous drop in platelet counts (A, p=0.703) and serum erythropoietin levels (B, p=0.021) in Crohn's patients receiving iron sucrose (200–400 mg/week) and erythropoietin (150 mg/KG 3 times per week; light column/line) or iron sucrose (200–400 mg/week) and placebo (dark column/line). N=20 for each group. Error bars represent standard deviation.

To confirm these unexpected findings we also analyzed a recent independent cohort of patients (from FERGIcor; [16]). From the total of 485 patients, platelet data were available from 448 patients pre and post iron therapy. 228 patients had received 500–1200 mg intravenous iron (50.9%) and 220 had received 1201–2000 mg (49.1%). Half of the patients were treated with ferric carboxymaltose (n=228, 50.9%), half with iron sucrose (n=220, 49.1%). In this cohort, the platelet counts dropped from mean 383 (SD 139) G/L at study entry to 310 (101) G/L after treatment (table 2, p<0.001) confirming the results from the initial analysis. The change in platelet counts was independent of the iron compound (figure 4A) and was dose-dependent (p<0.001, figure 4B). Similar to the initial cohort, hemoglobin and iron parameters improved but inflammation parameters did not change upon iron treatment (table 2).

Table 2

Changes in laboratory parameters upon iron treatment (confirmation dataset: FERGIcor, n=448).

	Pre iron	Post iron	N	p value
Platelets G/L	383 (139)	310 (101)	448	<0.001
Hemoglobin g/dL	10.2 (1.5)	12.8 (1.5)	427	<0.001
Leukocytes G/L	7.2 (2.6)	7.0 (2.5)	400	0.142
C-reactive protein mg/dL*	0.4 (0–6.0)	0.4 (0–5.8)	366	0.052
Ferritin µg/L*	8 (2–151)	72 (2–544)	420	<0.001
Transferrin saturation %*	5.6 (1.4–50)	19.1 (1.7–58)	402	<0.001

Continuous data given as mean (SD) or *median (range).

Figure 4

The changes in platelet counts in the FERGIcor trial.

(A) Platelet counts pre and post iron therapy according to the iron preparation (black column – ferric carboxymaltose n=228, grey column – iron sucrose n=220), p<0.001 pre vs. post for both iron preparations. (B) Mean drop in platelets upon iron therapy according to the cumulative iron dose (p<0.001). Group 800–1200 mg n=228, group 1201–2000 mg n=220. Error bars represent standard deviation.

Discussion

The relative importance of iron deficiency for IBD-associated anemia has been demonstrated in several studies. Here we addressed the hypothesis that iron deficiency is also relevant for IBD-associated thrombocytosis, a frequent finding in active IBD. In both cohorts iron therapy was associated with a dose-dependent normalization of elevated platelet counts. The decrease in platelets was observed upon oral iron sulphate as well as intravenous iron sucrose or ferric carboxymaltose treatment, and was independent of erythropoietin. As inflammation parameters were low and did not change during iron treatment we may conclude that IBD-associated thrombocytosis in our cohorts is a result of iron deficiency rather than systemic inflammation.

So far, the origin, the mechanism and consequences of thrombocytosis in IBD have been unknown. This study is the first to underline the relevance of iron deficiency in this setting. It is important to state that iron therapy did not lower platelet counts below physiological levels, indicating a regulatory rather than a toxic effect. Also the effect was seen with different iron preparations, which excludes a potential effect of the sugar carrier molecule (i.e. sucrose, carboxymaltose). As platelet counts decreased continuously, we surmise that iron therapy reduced the dynamics of megakaryopoiesis rather than changed the platelet half-life. Interestingly, concomitant erythropoietin treatment did not alter platelet dynamics though erythropoietin has been considered to stimulate megakaryopoiesis [17]. In vitro, erythropoietin has no effect on megakaryocytes and previous in vivo observations in patients with chronic renal failure were also considered a consequence of iron deficiency [18], [19]. We may speculate that iron deficiency has a direct effect on megakaryopoiesis to stimulate platelet production for counteracting chronic bleeding.

Iron deficiency is one of the world's most common and potentially treatable health problems, nevertheless little is known about its association with thrombocytosis. A Medline search performed in February 2012 with “thrombocytosis" and “iron deficiency" as search terms (limit English-language) identified 88 publications, mainly case reports. The first observations were reported in 1904 [20] when the effect of severe hemorrhage on the number of platelets was tested in rabbits. Several case reports linked thrombosis, thrombocytosis and iron deficiency [21]–[27]. More recently, this association was also discussed in patients with renal failure [19], [28]. However, this is the first study to demonstrate an effect of iron therapy on platelets counts in humans. A second Medline search performed in July 2011 with “thrombocytosis" and “IBD" as search terms identified 65 publications (limit English-language). Again, several case reports about thrombosis or thrombocytosis and IBD were identified [29]–[35]. Three studies [36]–[38] showed a correlation with high disease activity, one study in children found thrombocytosis only in endoscopically confirmed severe colitis [39]. In the study of Okun et al [40] the preoperative thrombocytosis was a risk factor for postoperative chronic pouchitis, however, in the study of Lian et al [41] it was not. Higher levels of thrombopoietin were found [42] in patients with active disease compared to inactive disease or healthy controls, however, thrombopoietin levels did not correlate with platelet levels. Thrombocytosis was shown to be a risk factor for steroid-dependency in IBD [43] or lack of response to cyclosporine [44]. None of these studies evaluated iron parameters in the context of thrombocytosis again underlining the originality of our study.

As to the retrospective nature of this study certain shortcomings have to be considered. It is necessary to note that all patients had anemia and IBD, a diagnostic combination that selected for the presence of iron deficiency. Inclusion criteria and treatment regimen (iron preparation and dosage) varied between studies which might have had an impact on the outcome. Another shortcoming is the absence of non-iron treatment control group. Unfortunately, none of the studies from which the databases were made available had such a control group. However, all iron compounds (both oral and intravenous) showed a similar effect indicating that it is a true iron rather than carrier effect. In addition in all studies IBD medications were restricted by the inclusion criteria and had to be stable before and during the respective clinical trials. When testing leukocyte counts and C-reactive protein no change was found. This indicates that the drop in platelets is rather not caused by changes in inflammation but by iron therapy itself. To strengthen our findings from the initial cohort and to better control for these shortcomings the data were confirmed in a second recently published cohort (FERGIcor) from 88 centers in 14 European countries. In this second cohort the absolute platelet counts before iron treatment were not as high as in the initial cohort; however, anemia and, accordingly, iron deficiency were also not as severe. Post iron therapy platelet counts in both cohorts were comparable.

In summary, iron therapy normalizes elevated platelet counts in patients with IBD-associated anemia. Thus, our study provides initial evidence for a direct association between iron deficiency and secondary thrombocytosis in IBD-associated anemia. In cancer patients thrombocytosis is an independent risk factor for thromboembolic events [45]. In IBD, predictive laboratory parameters for thromboembolic events have not been evaluated. It will be important to assess platelet activity and clot formation in this setting. Further the role of secondary thrombocytosis in IBD patients without iron deficiency needs clarification. It is tempting to speculate that thrombocytosis in chronic disease arises on the basis of an iron-deficient megakaryopoiesis, when iron is kept in the monocyte-macrophage-system and thus is unavailable to the bone marrow. Interventional studies in non-anemic IBD and cancer patients are under way. If our hypothesis is true and iron deficiency is causatively linked to thromboembolic events our work has strong impact on medical practice in various fields including orthopedic surgery, cancer, and chronic disease.

Methods

Study cohorts

The primary analysis was conducted at the Medical University of Vienna between June and September 2008. The local ethics committee had approved the protocol for the retrospective analysis (ethic committee of the Medical University of Vienna). Laboratory parameters before and after iron therapy (platelets, hemoglobin, leukocytes, C-reactive protein, ferritin, transferrin saturation) were obtained from four prospective clinical trials that had tested iron therapy with and without erythropoietin in IBD:

In the “Crohn study"[46], 40 patients with anemia and Crohn's disease receiving total dosages of up to 3600 mg iron sucrose over 16 weeks were randomized to erythropoietin treatment or placebo. Erythropoietin levels were measured in serum samples (stored at −20°C) using a commercial radioimmunoassay (Bio-Merieux, Nörtingen, Germany).

In the “Colitis study" [47], 20 patients with anemia and ulcerative colitis were treated with a total amount of 2000 mg iron sucrose over eight weeks. Non-responders to iron received additionally erythropoietin.

In the “Predict study" [48], 63 patients with anemia and IBD were treated with a total amount of 1200 mg iron sucrose over four weeks.

In the “Ferric carboxymaltose study" [49], 200 patients with anemia and IBD were randomized 2∶1 to ferric carboxymaltose (total median amount 1400 mg iron, n=137) or oral iron sulphate (200 mg/day, n=63). The endpoints were evaluated at week 12.

A second database from a recently published multicenter clinical trial (FERGIcor; [16]) was made available in October 2011 and used as confirmation cohort. This trial was conducted between October 2008 and December 2009. In the “FERGIcor study", 485 patients with IBD-associated anemia were randomized 1∶1 to ferric carboxymaltose (total mean amount 1380 mg iron, n=244) or iron sucrose (total mean amount 1160 mg iron, n=241). The endpoints were tested after 12 weeks. The study was registered at: ClinicalTrials.gov (NCT00810030).

All five prospective studies were approved by the local ethic committees as stated in the publications [16], [46]–[49], for the prospective studies written informed consent was obtained before the screening visit.

Statistical analysis

Data were analyzed for distribution. Paired sample t-test or Wilcoxon test for paired samples were used to compare values before and after iron therapy as appropriate. Changes in platelet counts according to iron dose were analyzed by analysis of variance. Comparison of erythropoietin levels and platelet counts over time was performed after a log-transformation because of skewed distribution. The repeated weekly measurements were summarized per patient by computing the slopes from individual patient's linear regression analyses. The slopes were compared between groups by an independent samples t-test.