# Experimental Characterisation of Differently Composed Thrombus Entities with Spectral-Detector-CT

**Authors:** Schekeb Aludin, Agreen Horr, Lars-Patrick Schmill, Carmen Wolf, Olav Jansen, Bodo Kurz, Julian Andersson, Svea Seehafer, Naomi Larsen, Patrick Langguth, Jens Trentmann

PMC · DOI: 10.3390/neurolint18020038 · Neurology International · 2026-02-21

## TL;DR

This study shows that spectral CT can better differentiate blood clot compositions than traditional CT scans, potentially improving stroke treatment.

## Contribution

The study demonstrates that spectral CT parameters like electron density and mass-attenuation curves can distinguish thrombus entities with varying red blood cell content.

## Key findings

- Conventional Hounsfield-unit values and spectral electron density increased with red blood cell content, enabling thrombus differentiation.
- Mass-attenuation curves showed distinct relative HU decreases at different monoenergetic levels, especially in thrombi with lower red blood cell content.
- Spectral CT offers improved thrombus characterization beyond traditional CT-density measurements.

## Abstract

Background/Objectives: Thrombus composition influences the success of endovascular therapy in stroke, but conventional CT is limited in determining it. Spectral-detector-CT (SDCT) can apply material-decomposition and virtual monoenergetic (MonoE) imaging, which may provide a way to gain information on thrombus composition. This experimental study aimed to evaluate the differentiability of heterogeneous thrombi with variable red blood cell (RBC) content using SDCT. Methods: Ten thrombus entities with different compositions on RBC and plasma, thus fibrin content, were manufactured (volumetric RBC%/Plasma% = 90/10; 80/20; 70/30; 60/40; 50/50; 40/60; 30/70; 20/80; 10/90; 5/95) and scanned in an SDCT. Conventional Hounsfield-unit (HU) values, spectral electron density (ED), effective atomic number (Z-effective) and HU in MonoE maps ranging from 40– to 200 keV were evaluated for thrombus differentiation. Results: Conventional HU increased with RBC content, allowing us to differentiate the entities (p < 0.001). ED values also increased with RBC content and allowed for differentiation too (p < 0.001). Z-effective values showed no differences among the different entities (p > 0.05). Regarding the mass-attenuation curves from 40 to 200 keV the different thrombi showed a similar curve progression with highest HU values at 40 and lowest at 200 keV. The thrombi could be distinguished overall at each monoenergetic level by HU (p < 0.001 for each level). The absolute decrease in HU between 40 and 200 keV was thereby not significantly different between the different entities, but the relative decrease was, as it was more pronounced in thrombi with lower RBC content (p < 0.001). Conclusions: Spectral CT enables differentiation between thrombi with different RBC and fibrin contents by means of ED or analysis of the mass-attenuation curve. This offers alternative possibilities that go beyond characterisation based on CT-density alone. The additional inclusion of spectral parameters in thrombus diagnostics could therefore improve diagnosis and treatment.

## Linked entities

- **Diseases:** stroke (MONDO:0005098)

## Full-text entities

- **Diseases:** vascular occlusion (MESH:D008641), ED (MESH:D028361), injury to (MESH:D014947), stroke (MESH:D020521), AIS (MESH:D000083242), Thrombus (MESH:D013927), Coagulopathies (MESH:D001778), anaemia (MESH:D000743), venous or cardiac thrombi (MESH:D006331)
- **Chemicals:** paraffin (MESH:D010232), sodium-chloride (MESH:D012965), iron (MESH:D007501), water (MESH:D014867), polyethylene (MESH:D020959), Calcium-chloride (MESH:D002122), haematoxylin (MESH:D006416), HU (-), paraformaldehyde (MESH:C003043), Agarose (MESH:D012685), iodine (MESH:D007455), citrate (MESH:D019343), calcium (MESH:D002118), eosin (MESH:D004801)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Full text

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## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12942994/full.md

## References

52 references — full list in the complete paper: https://tomesphere.com/paper/PMC12942994/full.md

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Source: https://tomesphere.com/paper/PMC12942994