HFrEF subphenotypes based on 4210 repeatedly measured circulating proteins are driven by different biological mechanisms.

Teun B Petersen Marie de Bakker Folkert W Asselbergs Magdalena Harakalova K Martijn Akkerhuis Jasper J Brugts Jan van Ramshorst R Thomas Lumbers Rachel M Ostroff Peter D Katsikis Peter J van der Spek Victor A Umans Eric Boersma Dimitris Rizopoulos Isabella Kardys

EBioMedicine

Department of Cardiology, Erasmus MC, University Medical Center Rotterdam, Doctor Molewaterplein 40, Rotterdam, the Netherlands. Electronic address:

Published: July 2023

The study investigated heart failure with reduced ejection fraction (HFrEF) by analyzing 4210 circulating proteins to identify distinct subphenotypes and understand their biological mechanisms.
Researchers followed 382 patients over approximately 2.1 years, using multiple blood samples and advanced proteomic techniques to cluster patients based on their protein markers.
Four unique subphenotypes were found, each with differing clinical characteristics and prognoses, highlighting the potential for personalized treatment strategies based on protein profiles.

Background: HFrEF is a heterogenous condition with high mortality. We used serial assessments of 4210 circulating proteins to identify distinct novel protein-based HFrEF subphenotypes and to investigate underlying dynamic biological mechanisms. Herewith we aimed to gain pathophysiological insights and fuel opportunities for personalised treatment.

Methods: In 382 patients, we performed trimonthly blood sampling during a median follow-up of 2.1 [IQR:1.1-2.6] years. We selected all baseline samples and two samples closest to the primary endpoint (PEP; composite of cardiovascular mortality, HF hospitalization, LVAD implantation, and heart transplantation) or censoring, and applied an aptamer-based multiplex proteomic approach. Using unsupervised machine learning methods, we derived clusters from 4210 repeatedly measured proteomic biomarkers. Sets of proteins that drove cluster allocation were analysed via an enrichment analysis. Differences in clinical characteristics and PEP occurrence were evaluated.

Findings: We identified four subphenotypes with different protein profiles, prognosis and clinical characteristics, including age (median [IQR] for subphenotypes 1-4, respectively:70 [64, 76], 68 [60, 79], 57 [47, 65], 59 [56, 66]years), EF (30 [26, 36], 26 [20, 38], 26 [22, 32], 33 [28, 37]%), and chronic renal failure (45%, 65%, 36%, 37%). Subphenotype allocation was driven by subsets of proteins associated with various biological functions, such as oxidative stress, inflammation and extracellular matrix organisation. Clinical characteristics of the subphenotypes were aligned with these associations. Subphenotypes 2 and 3 had the worst prognosis compared to subphenotype 1 (adjHR (95%CI):3.43 (1.76-6.69), and 2.88 (1.37-6.03), respectively).

Interpretation: Four circulating-protein based subphenotypes are present in HFrEF, which are driven by varying combinations of protein subsets, and have different clinical characteristics and prognosis.

Clinical Trial Registration: ClinicalTrials.gov Identifier: NCT01851538https://clinicaltrials.gov/ct2/show/NCT01851538.

Funding: EU/EFPIA IMI2JU BigData@Heart grant n°116074, Jaap Schouten Foundation and Noordwest Academie.

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http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10279550	PMC
http://dx.doi.org/10.1016/j.ebiom.2023.104655	DOI Listing

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