Author: John Murphy, President, COVID-19 Long-haul Foundation

Abstract

Long COVID, or post-acute sequelae of SARS-CoV-2 infection (PASC), has emerged as a chronic multisystem condition affecting millions globally. Among its most compelling pathophysiological features is the presence of fibrinaloid microclots—small, amyloid-like aggregates resistant to fibrinolysis. These clots impair oxygen delivery, promote systemic inflammation, and contribute to neurovascular symptoms such as fatigue, brain fog, and autonomic instability. This article synthesizes current evidence on microclot formation, platelet hyperactivation, and resistance to plasmin-mediated breakdown. We examine the roles of von Willebrand factor (vWF), fibrinogen, and plasminogen activator inhibitor-1 (PAI-1), and review visualization techniques including fluorescence microscopy and thromboelastography. These findings support a vascular-centered model of Long COVID and suggest new diagnostic and therapeutic pathways.

1. Introduction

The COVID-19 pandemic has left a legacy of chronic illness in the form of Long COVID. Characterized by persistent symptoms beyond 12 weeks post-infection, Long COVID affects up to 30% of infected individuals and presents with fatigue, cognitive dysfunction, cardiovascular instability, and clotting abnormalities. While early hypotheses focused on viral persistence and autoimmunity, recent research highlights vascular injury and coagulation dysfunction as central to its pathophysiologyrpthjournal.org.

One of the most striking discoveries is the presence of microclots—small, fibrinaloid aggregates that resist enzymatic breakdown and impair capillary perfusion. These clots are structurally distinct from typical thrombi and exhibit amyloid-like properties. Their formation appears to be driven by spike protein exposure, platelet hyperactivation, and dysregulation of fibrinolytic pathways.

2. Microclot Formation and Amyloid Clot Structure

Microclots in Long COVID patients differ structurally and functionally from those seen in acute thrombosis. Pretorius et al. first described these fibrinaloid clots using fluorescence microscopy, revealing dense, misfolded fibrin networks that bind amyloid dyes such as thioflavin T. These clots are enriched in inflammatory proteins, including serum amyloid A, complement components, and spike protein fragmentsbioRxiv.

Amyloid clot formation results from aberrant fibrinogen polymerization, triggered by oxidative stress and inflammatory cytokines. The spike protein itself may act as a nucleating agent, binding to fibrin and altering its structure. This results in clots that are mechanically stiff, poorly permeable, and resistant to enzymatic degradation.

3. Platelet Hyperactivation and Coagulopathy

Platelets in Long COVID patients show signs of hyperactivation, including increased expression of P-selectin, CD62P, and integrin αIIbβ3. Flow cytometry and electron microscopy studies reveal degranulated platelets with enhanced aggregation potential. This hyperactivation is likely driven by persistent immune stimulation, endothelial injury, and direct interaction with spike proteinMedHelp.

Activated platelets release procoagulant microparticles and promote thrombin generation. They also interact with neutrophils to form neutrophil extracellular traps (NETs), which further propagate clot formation. The resulting thromboinflammatory environment contributes to microvascular occlusion and tissue damage.

4. Role of von Willebrand Factor, Fibrinogen, and PAI-1

von Willebrand Factor (vWF)

vWF is a multimeric glycoprotein essential for platelet adhesion and aggregation. In Long COVID, elevated vWF levels reflect endothelial activation and damage. Ultra-large vWF multimers may promote spontaneous platelet aggregation and microthrombi formationAmerican Physiological Society Journal.

Fibrinogen

Fibrinogen levels are often elevated in Long COVID patients, correlating with inflammatory markers such as IL-6 and CRP. Misfolded fibrinogen contributes to amyloid clot formation and impairs fibrinolysis. Studies using scanning electron microscopy show dense fibrin networks with reduced porosity and increased rigidityCardiovascular Diabetology.

Plasminogen Activator Inhibitor-1 (PAI-1)

PAI-1 is the primary inhibitor of tissue plasminogen activator (tPA), and its elevation suppresses fibrinolysis. In Long COVID, PAI-1 levels are persistently high, contributing to clot persistence and impaired resolution. This imbalance between coagulation and fibrinolysis is a hallmark of the condition.

5. Resistance to Plasmin-Mediated Clot Breakdown

Traditional thrombi are degraded by plasmin, generated from plasminogen via tPA. In Long COVID, this pathway is disrupted. Amyloid clots resist plasmin cleavage due to altered fibrin architecture and PAI-1 overexpression. Pretorius et al. demonstrated that even high concentrations of plasmin fail to degrade these clots in vitrorpthjournal.org.

This resistance has clinical implications. Persistent microclots may impair oxygen delivery, promote inflammation, and contribute to symptoms such as fatigue and cognitive dysfunction. Therapeutic strategies must therefore address both clot formation and fibrinolytic resistance.

6. Visualization Techniques: Fluorescence Microscopy and Thromboelastography

Fluorescence Microscopy

Fluorescence microscopy using amyloid-binding dyes (e.g., thioflavin T, Congo red) allows visualization of fibrinaloid clots. These techniques reveal dense, misfolded fibrin networks with high fluorescence intensity. Pretorius et al. used this method to compare plasma from Long COVID patients and healthy controls, finding significant differences in clot structure and densityrpthjournal.org.

Thromboelastography (TEG)

TEG measures the viscoelastic properties of clot formation and breakdown. In Long COVID, TEG profiles show increased clot strength, prolonged clotting time, and reduced fibrinolysis. These findings support the presence of hypercoagulability and impaired clot resolution.

7. Therapeutic Implications and Clinical Trials

Several therapeutic strategies are under investigation to address microclot burden and fibrinolytic resistance. These include:

• Fibrinolytics: Lumbrokinase, nattokinase, and serrapeptase are being tested for their ability to degrade amyloid clots.
• Anticoagulants: DOACs and low-dose aspirin may reduce clot formation but do not address fibrinolytic resistance directly.
• Endothelial support: Omega-3 fatty acids, sulforaphane, and statins may reduce endothelial inflammation and vWF release.

The PolyBio Research Foundation and Mount Sinai are conducting trials on multi-agent protocols targeting platelet hyperactivation and clot persistence.

Conclusion

Microclot formation and fibrinolytic resistance represent a central axis of Long COVID pathology. Driven by spike protein exposure, platelet hyperactivation, and dysregulated fibrinolysis, these clots impair oxygen delivery and promote systemic inflammation. Visualization techniques such as fluorescence microscopy and thromboelastography confirm their presence and guide therapeutic strategies. Future research must prioritize vascular-centered models and develop targeted diagnostics and treatments.

📎 References

1. Dr. Jill Carnahan – Microclots and Long COVID
2. Pretorius et al. – RPTH Journal
3. bioRxiv – Spike Protein Amyloid Fibrils
4. Nature – Fibrin Drives Thromboinflammation
5. PolyBio – Lumbrokinase Trial
6. MedHelp Clinics – Amyloid Fibrin Microclots
7. Cardiovascular Diabetology – Proteomics of Microclots
8. Blood Journal – Coagulation Abnormalities
9. [Technology Networks – Microclot Research](https://www