Litcius/Paper detail

ICAM-1-carrying targeted nano contrast agent for evaluating inflammatory injury in rabbits with atherosclerosis

Ping Li, Lin Jin, Feng Lan, Yingchun Wang, Rong Yang

2021Scientific Reports17 citationsDOIOpen Access PDF

Abstract

To investigate the feasibility of using ICAM-1-targeted nano ultrasonic contrast to evaluate the degree of inflammatory injury at different stages in the abdominal aorta of rabbits with atherosclerosis (AS). Twenty-five experimental rabbits were assigned to five groups: the control group (A); the week-4 after modeling group (B); the week-8 after modeling group (C); the week-12 after modeling group (D); the week-16 after modeling group (E). All groups were given 2D ultrasonography, conventional ultrasonic contrast (SonoVue), and ICAM-1-targeted nano ultrasonic contrast, respectively. Signal intensity of vascular perfusion was evaluated. Signal intensity of ICAM-1-targeted nano ultrasonic contrast was substantially enhanced and prolonged in the vascular wall of the abdominal bubble aorta increased in B, C, D, and E groups (all P < 0.05). A positive linear correlation between intensity and the expression of ICAM-1 (r = 0.895, P < 0.001). The intensity of outer membrane was enhanced from week 4 to week 12, and both the intima-media membrane and outer membrane were enhanced with double-layer parallel echo at week 16, which was in line with the progression of atherosclerotic plaque inflammatory injury. ICAM-1-targeted nano contrast agent would be possibly a novel non-invasive molecular imaging method for plaque inflammatory injury and site high expression of specific adhesion molecules in early atherosclerotic lesions.

Topics & Concepts

UltrasoundMedicineAbdominal aortaAortaContrast (vision)InflammationPerfusionPathologyIntensity (physics)ICAM-1Contrast-enhanced ultrasoundCell adhesion moleculeBiomedical engineeringInternal medicineRadiologyImmunologyComputer scienceArtificial intelligencePhysicsQuantum mechanicsCoronary Interventions and DiagnosticsAtherosclerosis and Cardiovascular DiseasesCell Adhesion Molecules Research