Ferroptosis contributes to endothelial dysfunction, macrophage foam cell death, and necrotic core expansion in atherosclerosisFerroptosis May Drive Damage in Arterial Atherosclerosis

Frontiers in Medicine Published June 24, 2026 DOI ↗ Editorial oversight: Dr. Amelia Tan, PhD · Internal Medicine & Chronic Disease

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Key Takeaway

Note that while ferroptosis contributes to atherosclerotic hallmarks, specific clinical translation requires further validation.

This systematic review synthesizes current knowledge regarding ferroptosis mechanisms within arterial atherosclerosis. The scope includes core pathway dynamics such as iron homeostasis, polyunsaturated phospholipid metabolism, and lipid peroxide detoxification. The authors identify how the atherosclerotic plaque provides a permissive microenvironment—characterized by oxidized lipids, redox-active iron, inflammatory mediators, and hypoxia—that may contribute to endothelial dysfunction, macrophage foam cell death, vascular smooth muscle cell loss, and necrotic core expansion.

The review highlights several limitations in current research, including inconsistencies in operational definitions and a heavy reliance on non-specific oxidative stress markers. Furthermore, the authors note that there is currently insufficient validation of these mechanisms specifically within human plaques.

Clinical translation remains limited by the need to delineate ferroptosis-specific signatures. The authors suggest that establishing causality through cell-targeted interventions is essential for moving from theoretical pathways to actionable risk assessment and management in patients with atherosclerosis.

How this fits prior evidence

This systematic review addresses a gap in understanding the specific cellular mechanisms of plaque progression. While prior evidence identified vascular smooth muscle cell immune interactions as emerging mechanistic targets, this review focuses on the role of ferroptosis in those same cells and other components like macrophages and endothelial cells to explain necrotic core expansion.

Researchers reviewed current knowledge on ferroptosis, a specific form of cell death involving iron and lipid metabolism. They looked at how this process affects atherosclerosis, which is the buildup of plaque in the arteries. The review focused on how factors like oxidized lipids and iron levels might create an environment that harms blood vessel cells.

The findings suggest that these conditions may lead to several issues, including the loss of smooth muscle cells and the expansion of necrotic cores within plaques. These changes can cause the lining of blood vessels to function poorly. The study highlights specific areas where cell death impacts different types of cells in the artery wall.

Because this was a systematic review of existing data, it is important to note that these findings are not yet ready for clinical use. There are still limitations, such as inconsistent definitions and a lack of enough testing in human plaques. More research is needed to confirm exactly how these pathways work before they can be used to develop new treatments.

What this means for you:

Ferroptosis may play a role in artery damage, but more research is needed to turn these findings into clinical treatments.

Common questions

What is ferroptosis and how does it affect arteries?

Ferroptosis is a specific type of cell death involving iron and lipid metabolism. In the context of atherosclerosis, it may create an environment that leads to endothelial dysfunction, the loss of smooth muscle cells, and the expansion of necrotic cores within arterial plaques.

Is ferroptosis a proven target for new heart medications?

While the review identifies ferroptosis as a potential pathway for future research, it is not yet a proven clinical target. More studies are needed to establish clear causality and test specific treatments before they can be used in medical practice.

What are the limitations of this current research?

The findings currently face some hurdles, including inconsistent definitions and a reliance on non-specific markers. Additionally, there is not enough validation specifically in human plaques to confirm these findings for clinical use at this time.

Study Details

Study typeSystematic review

EvidenceLevel 1

PublishedJun 2026

View Original Abstract ↓

Despite significant progress in lipid-lowering and anti-thrombotic therapies, atherosclerosis remains a leading cause of myocardial infarctions and ischemic strokes. Residual risk persists, often linked to sustained vascular inflammation, oxidative stress, and plaque instability—processes that converge on lipid peroxidation pathways within the arterial wall. Ferroptosis, an iron-dependent form of regulated cell death, occurs when antioxidant defenses fail, leading to toxic accumulation of phospholipid peroxides. Atherosclerotic plaques provide a permissive microenvironment rich in oxidized lipids, redox-active iron, inflammatory mediators, and hypoxia, suggesting ferroptosis may contribute to endothelial barrier dysfunction, macrophage foam cell death, vascular smooth muscle cell loss, and necrotic core expansion. However, current understanding is constrained by operational definition inconsistencies, reliance on non-specific oxidative stress markers, and insufficient validation in human plaques. This review systematically synthesizes knowledge on ferroptosis in arterial atherosclerosis, incorporating core pathway dynamics—iron homeostasis, polyunsaturated phospholipid metabolism, and lipid peroxide detoxification via systems like Xc–GPX4—alongside parallel protective axes. It evaluates cell-type-specific vulnerabilities across disease stages, highlighting how disturbed flow, dyslipidemia, metabolic disorders, and innate immune signaling modulate ferroptosis susceptibility and plaque phenotype. The analysis extends to candidate biomarkers, tissue-level signatures, and therapeutic strategies targeting iron availability, lipid peroxidation, or key regulatory proteins, while addressing safety concerns and experimental gaps. Ultimately, delineating ferroptosis-specific signatures in human tissues and establishing causality through cell-targeted interventions are vital for translating this pathway into clinically actionable risk assessment and management strategies.

Ferroptosis contributes to endothelial dysfunction, macrophage foam cell death, and necrotic core expansion in atherosclerosisFerroptosis May Drive Damage in Arterial Atherosclerosis

How this fits prior evidence

Common questions

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Ferroptosis contributes to endothelial dysfunction, macrophage foam cell death, and necrotic core expansion in atherosclerosisFerroptosis May Drive Damage in Arterial Atherosclerosis

How this fits prior evidence

Common questions

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Study Details

Budesonide-glycopyrronium-formoterol fumarate dihydrate improved lung function and reduced severe exacerbations versus budesonide-formoterol in inadequately controlled asthma

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