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Economic Analysis of Intravenous Iron in Patients with Iron Deficiency Anemia Due to Inflammatory Bowel Disease: Considerations for Clinicians [Letter]

Authors Pollock RF , Dhar A , Johnson M

Received 22 February 2022

Accepted for publication 23 March 2022

Published 4 April 2022 Volume 2022:14 Pages 163—165

DOI https://doi.org/10.2147/CEOR.S363642

Checked for plagiarism Yes

Editor who approved publication: Prof. Dr. Dean Smith



Richard F Pollock,1 Anjan Dhar,2 Matthew Johnson3

1Health Economics and Outcomes Research, Covalence Research Ltd, London, UK; 2Department of Gastroenterology, County Durham & Darlington NHS Foundation Trust, Darlington, Co. Durham, UK; 3Department of Gastroenterology, Luton and Dunstable University Hospital NHS Foundation Trust, Luton, UK

Correspondence: Richard F Pollock, Health Economics and Outcomes Research, Covalence Research Ltd, London, UK, Tel +44 20 8638 6525, Email [email protected]

View the original paper by Dr Aksan and colleagues

Dear editor

We read, with interest, the recently published article by Aksan et al (2021),1 which presents the results of an economic analysis comparing the cost-effectiveness of intravenous (IV) iron products in the treatment of iron deficiency anemia (IDA) associated with inflammatory bowel disease (IBD), in the UK setting. The authors concluded that ferric carboxymaltose (FCM; Vifor Pharma, Glattbrugg, Switzerland) is likely to be the least costly, and most effective, IV iron therapy compared with ferric derisomaltose (FDI; previously known as iron isomaltoside; Pharmacosmos A/S, Holbæk, Denmark) and iron sucrose (IS; Vifor Pharma, Glattbrugg, Switzerland).1 We would like to share our experience of health economics in the field of IV iron therapy to present some important considerations for clinicians when interpreting these findings, to ensure rational and evidence-based treatment decisions.

Firstly, the clinical effectiveness inputs used in the Aksan et al (2021) analysis were based on the results of an earlier network meta-analysis (NMA) comparing the efficacy and tolerability of different IV iron products (including FDI, FCM, and IS) in patients with IDA due to IBD (published by Aksan et al in 2017).1,2 The NMA showed no statistically significant differences in efficacy (treatment response: hemoglobin [Hb] normalization or increase in Hb ≥2 g/dL) between FDI and FCM.2 The shortcomings of this NMA have been detailed in a previous communication,3 but the Aksan et al (2021) analysis does not seem to incorporate changes to overcome these short-falls.

Secondly, in the Aksan et al (2021) analysis, the authors acknowledge the weakness of using indirect evidence to obtain the data for the clinical effectiveness inputs, justifying this approach by the lack of direct evidence from head-to-head trials conducted in a relevant patient population.1 Indeed, Aksan et al (2021) did not include the data from the head-to-head PHOSPHARE-IDA trial showing comparable efficacy (iron and anemia parameters, assessed as secondary endpoints) between FCM and FDI, on the basis that the IDA was due to a gynecological condition, not to IBD.1,4 Evidence is now available from the head-to-head PHOSPHARE-IBD trial, which was conducted, specifically, in patients with IBD (n=96); equivalent doses of FCM and FDI (initial dose of 1000 mg at baseline followed by 500 mg or 1000 mg after 5 weeks) were compared, with assessment of Hb as a secondary endpoint.5 As shown in Table 1, the PHOSPHARE-IBD trial showed no statistically significant difference between FCM and FDI in the post-treatment Hb changes from baseline.5

Table 1 Mean Change from Baseline in Hb Following Treatment with FCM or FDI

The evidence from PHOSPHARE-IBD provides confirmation of equivalent hematological efficacy of FCM and FDI in an IBD population with IDA.5 Therefore, the suggestion that FCM is more effective than FDI (as was concluded for the Aksan et al (2017) NMA),2 is not completely borne out by published evidence.

Thirdly, the Aksan et al (2021) analysis acknowledged that the impact of safety issues on cost and clinical outcomes was not considered, and that such information should be captured in future cost-effectiveness studies.1 This is, indeed, an important reflection given that the Pharmacovigilance Risk Assessment Committee of the European Medicines Agency considers there to be a possible causal relationship between hypophosphatemic osteomalacia and FCM, specifically6 – it is not a class effect for all IV iron products. In November 2020, the regulatory authorities in the UK published an update to the product information for FCM to include a requirement for serum phosphate monitoring in patients who receive multiple administrations of FCM at higher doses, or long-term FCM treatment (and in those with existing risk factors for hypophosphatemia, including IBD).7 The cost of this additional monitoring is particularly relevant to the Aksan et al (2021) analysis, given that it was focused on a population of IBD patients in the UK.1

We hope that the issues highlighted in this letter will give a broader perspective to the findings of the Aksan et al (2021) economic analysis for prescribing clinicians and decision-makers in the UK. Of particular importance for real-world clinical practice are the recent changes to the FCM product label, which translate into an additional economic impact of FCM treatment in the management of IDA due to IBD.

Funding

This letter was funded by Pharmacosmos A/S. Writing and editorial assistance was provided by 'Cambridge – a Prime Global agency'.

Disclosure

RFP is a director and shareholder in Covalence Research Ltd, which has received consultancy fees from Pharmacosmos A/S (the marketing authorization holder for Monofer) and Pharmacosmos UK Limited, a wholly-owned subsidiary of Pharmacosmos A/S. RFP has also received personal honoraria from Pharmacosmos UK Limited. AD has received speaker fees from Pharmacosmos, Pfizer, Takeda, Tillotts UK, and Janssen, advisory honoraria from Takeda, Tillotts UK, Dr Falk Pharma, Pfizer, and conference support from Pharmacosmos, Tillotts, Takeda, Janssen, Dr Falk Pharma, and Cook Medical. MJ has received conference support from Pharmacosmos, Janssen, Dr Falk Pharma, Cook Medical, Pfizer, AbbVie, Amgen Ltd, Ferring Pharmaceuticals, Norgine Pharmaceuticals, Allergen, Aquilant Endoscopy, FujiFilm, MSD, Hospira, NAPP, Warner Chilcott, Sucampo Pharmaceuticals, Regenerus Laboratories, Takeda UK, Tillotts Pharma UK, Mylan, Vifor Pharma, Shield Therapeutics, Kyowa Kirin, and Viatris. The authors report no other conflicts of interest in this communication.

References

1. Aksan A, Beales ILP, Baxter G, et al. Evaluation of the cost-effectiveness of iron formulations for the treatment of iron deficiency anaemia in patients with inflammatory bowel disease in the UK. Clinicoecon Outcomes Res. 2021;13:541–552. doi:10.2147/CEOR.S306823

2. Aksan A, Işık H, Radeke HH, Dignass A, Stein J. Systematic review with network meta-analysis: comparative efficacy and tolerability of different intravenous iron formulations for the treatment of iron deficiency anaemia in patients with inflammatory bowel disease. Aliment Pharmacol Ther. 2017;45(10):1303–1318. doi:10.1111/apt.14043

3. Pollock RF, Muduma G. Response: an economic evaluation of iron isomaltoside 1000 versus ferric carboxymaltose in patients with inflammatory bowel disease and iron deficiency anemia in Denmark. Adv Ther. 2019;36(8):1821–1825. doi:10.1007/s12325-019-00993-8

4. Wolf M, Rubin J, Achebe M, et al. Effects of iron isomaltoside vs ferric carboxymaltose on hypophosphatemia in iron-deficiency anemia: two randomized clinical trials. JAMA. 2020;323(5):432–443. doi:10.1001/jama.2019.22450

5. EU Clinical Trials Register. Clinical Trial Results: a randomized, double-blinded, comparative trial comparing the incidence of hypophosphatemia in relation to repeated treatment courses of iron isomaltoside and ferric carboxymaltose in subjects with iron deficiency anaemia due to inflammatory bowel disease. EudraCT number: 2017-002452-87. Available from: https://www.clinicaltrialsregister.eu/ctr-search/trial/2017-002452-87/results. Accessed September 25, 2021.

6. European Medicines Agency. Scientific conclusions and grounds for the variation to the terms of the Marketing Authorisation(s). Available from: https://www.ema.europa.eu/en/documents/psusa/iron-parenteral-preparations-except-iron-dextran-cmdh-scientific-conclusions-grounds-variation/00010236/202001_en.pdf. Accessed November 3, 2021.

7. GOV.UK. Drug Safety Update. Ferric carboxymaltose (Ferinject▼): risk of symptomatic hypophosphataemia leading to osteomalacia and fractures; 2020. https://www.gov.uk/drug-safety-update/ferric-carboxymaltose-ferinject-risk-of-symptomatic-hypophosphataemia-leading-to-osteomalacia-and-fractures. Accessed November 3, 2021.

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