Macrophage-red blood cell hybrid membrane-coated ultrasound-responsive microbowls to eliminate pathogens, endotoxins, and heavy metal ions from blood

Sepsis is a potentially life-threatening condition triggered by pathogens such as bacteria and toxins. In clinical settings, hemoperfusion has been used as a therapeutic technique for the treatment of sepsis to remove pathogens, toxins and other inflammatory mediators from the bloodstream. However,...

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Bibliographic Details
Published in:New journal of chemistry 2024-06, Vol.48 (25), p.1166-11616
Main Authors: Jing, Jianxing, Lv, Mingchen, Hu, Wei, Teng, Runxin, Ge, Zhenghong, Wu, Peng, Zhang, Yao, Sun, Min, Fan, Zhen
Format: Article
Language:English
Subjects:
Adsorption
Asymmetric structures
Bacteria
Biocompatibility
Blood
Blood circulation
Cell membranes
Dibutyl phthalate
Endotoxins
Erythrocytes
Heavy metals
Hemoperfusion
Microparticles
Pathogens
Pressure gradients
Radiation pressure
Sepsis
Sound waves
Toxins
Ultrasonic imaging
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Summary:Sepsis is a potentially life-threatening condition triggered by pathogens such as bacteria and toxins. In clinical settings, hemoperfusion has been used as a therapeutic technique for the treatment of sepsis to remove pathogens, toxins and other inflammatory mediators from the bloodstream. However, the existing adsorption process of hemoperfusion is not specific to sepsis-related pathogens or toxins, resulting in unsatisfactory removal effectiveness and the lack of capture selectivity. Herein, we developed an ultrasound-responsive asymmetric polymeric microbowl coated with macrophage and red blood cell (RBC) membranes to selectively eliminate pathogens, toxins, and heavy metal ions from blood. Poly(glycidyl methacrylate) spherical microparticles were first synthesized and then eroded using dibutyl phthalate and styrene to form a microbowl structure. This asymmetric structure could provide acoustic radiation pressure gradients to realize orientation motion under non-invasive ultrasound fields with a velocity of 37.14 μm s −1 at 20 V p-p , which could increase adsorption efficiency in physiological environments by fuel-free programable movements. In addition, the macrophage and RBC membrane coating endowed the microbowl with desired biocompatibility, enhanced blood circulation and the ability to selectively eliminate endotoxins, bacteria and heavy metal ions. Endotoxin removal assay showed that 92.80% of endotoxin was eliminated within 15 minutes. Owing to the affinity between the red blood cell membrane and heavy metal ions, the removal efficiency reached 92.75% and 93.91% for Pb 2+ and Hg 2+ , respectively. Meanwhile, over 90% of S. aureus in the blood was eliminated owing to the selective recognition and adhesion of bacteria by macrophage membrane proteins. Overall, this work on ultrasound-responsive asymmetric polymeric microbowls provides a new insight to eliminate pathogens, toxins and heavy metal ions from the bloodstream for sepsis treatment. An ultrasound-driven asymmetric microbowl coated with hybrid cell membranes was developed to eliminate pathogens, toxins and heavy metal ions from the bloodstream through sonication for sepsis treatment.
ISSN:1144-0546
1369-9261
DOI:10.1039/d4nj00783b