Self‐Propelling Janus Particles for Hemostasis in Perforating and Irregular Wounds with Massive Hemorrhage

Li, Qing; Hu, Enling; Yu, Kun; Xie, Ruiqi; Lu, Fei; Lu, Bitao; Bao, Rong; Zhao, Tianfu; Dai, Fangyin; Lan, Guangqian

doi:10.1002/adfm.202004153

Cited by 69 publications

(55 citation statements)

References 46 publications

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“…Quantitative analysis of the adhesion efficiency of platelets and erythrocytes was conducted as described in our previous study [ 8 ]. Briefly, fresh erythrocytes and platelet-rich plasma were separated from rabbit blood via centrifugation (1500 rpm, 5 min).…”

Section: Methodsmentioning

confidence: 99%

“…More than 50% of these deaths can be avoided if appropriate hemostatic materials are applied within the initial hour [ 3 ]. However, currently available hemostatic materials involving sponge-like chitosan dressing [ 4 ], modified chitosan powder [ 5 ], oxidized cellulose [ 6 ] and zeolite powder [ 7 ] can only cater to superficial, externally accessible, and compressible wounds and display low efficiency for severe trauma generated by small-caliber firearms or improvised explosive devices [ 8 ]. This is mainly because these hemostatic materials only accelerate the coagulation of supernatant blood on the wound surface and are incapable of penetrating the deep sites of wounds to activate clotting at the source of bleeding [ 9 ].…”

Section: Introductionmentioning

confidence: 99%

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Microcluster colloidosomes for hemostat delivery into complex wounds: A platform inspired by the attack action of torpedoes

Xie

et al. 2022

Bioactive Materials

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Microcluster colloidosomes for hemostat delivery into complex wounds: A platform inspired by the attack action of torpedoes

Xie

et al. 2022

Bioactive Materials

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“…In the flow-liquid model, the ability of the applied MF to control the movement of SEC-Fe@Ca(+t) (abbreviated as SEC-Fe@Ca(+t+M)) against flowing fluid was investigated. A fluid-propelling device was constructed in-house as we previously reported [ 13 ]. The device comprised a glass tube connected to an injection pump at one end and Y-shaped bifurcated junction at the other end.…”

Section: Methodsmentioning

confidence: 99%

“…Insufficient adaptation to hemorrhagic hemocoels probably leaves part of the bleeding sites without external hemostatic treatment, thus prolonging the hemostasis time [ 2 , 3 ]. To address the insufficient adaptation issue, powered hemostat systems with gas-propelling properties have been developed to facilitate better contact with bleeding sites, especially in irregular wounds [ 12 , 13 ]. For example, a Janus particle system composed of microporous starch@CaCO 3 can generate CO 2 bubbles upon contacting blood with the synergistic use of protonated tranexamic acid (TXA-NH 3 + ).…”

Section: Introductionmentioning

confidence: 99%

“…During the bubble release, a propulsion force is generated to push the particles upstream. Because the propulsion force of the bubbles occur in various directions, each particle travels in random directions, and thus full contact is achieved between the hemostatic agent and bleeding sites [ 13 ]. Unfortunately, the solo gas-propelling force may be not lasting when CaCO 3 was depleted gradually, failing to deliver particles to the bleeding sites at the bottom of deep severe wounds.…”

Section: Introductionmentioning

confidence: 99%

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Dual-Driven Hemostats Featured with Puncturing Erythrocytes for Severe Bleeding in Complex Wounds

et al. 2022

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Achieving rapid hemostasis in complex and deep wounds with secluded hemorrhagic sites is still a challenge because of the difficulty in delivering hemostats to these sites. In this study, a Janus particle, SEC-Fe@CaT with dual-driven forces, bubble-driving, and magnetic field– (MF–) mediated driving, was prepared via in situ loading of Fe3O4 on a sunflower sporopollenin exine capsule (SEC), and followed by growth of flower-shaped CaCO3 clusters. The bubble-driving forces enabled SEC-Fe@CaT to self-diffuse in the blood to eliminate agglomeration, and the MF-mediated driving force facilitated the SEC-Fe@CaT countercurrent against blood to access deep bleeding sites in the wounds. During the movement in blood flow, the meteor hammer-like SEC from SEC-Fe@CaT can puncture red blood cells (RBCs) to release procoagulants, thus promoting activation of platelet and rapid hemostasis. Animal tests suggested that SEC-Fe@CaT stopped bleeding in as short as 30 and 45 s in femoral artery and liver hemorrhage models, respectively. In contrast, the similar commercial product Celox™ required approximately 70 s to stop the bleeding in both bleeding modes. This study demonstrates a new hemostat platform for rapid hemostasis in deep and complex wounds. It was the first attempt integrating geometric structure of sunflower pollen with dual-driven movement in hemostasis.

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Biomimetic Natural Biopolymer‐Based Wet‐Tissue Adhesive for Tough Adhesion, Seamless Sealed, Emergency/Nonpressing Hemostasis, and Promoted Wound Healing

Yang

Kang

Gao

et al. 2022

Adv Funct Materials

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Bioadhesives have been used in clinics among the most prospective alternatives to sutures and staples for wound sealing and repairing; however, they generally have inadequate adhesion to wet surfaces, improper mechanical strength, poor hemostasis, and cytotoxicity. To address these challenges, a robust wet tissue adhesive based on collagen and starch materials (CoSt) is designed in this study. CoSt hydrogels integrate the feature of drainage, molecular penetration and strengthen cross-linking similar to mussel, ivy, and oyster glues, which remove interfacial water quickly, reinforce tough dissipation and involve multiple reversible dynamic interactions. Therefore, they form strong adhesion and sutureless sealing of injured tissues, accompanying actuate robust biointerfaces in direct contact with tissue liquids or blood, resolving the crucial impediments with sutures and commercially accessible adhesives. The novel bioadhesive shows repeatable strong wet tissue adhesiveness (62 ± 4.8 KPa), high sealing performance (153.2 ± 35.1 mmHg), fast self-healing ability, excellent injectability, and shape adaptability. For different hemostatic needs in rat models of tail amputation, skin incision, severe liver, abdominal aorta, and transected nerve injuries, the CoSt hydrogel shows better hemostatic efficiency than fibrin glue because of the coordinate efficacy of tough wound sealing property, outstanding red blood cell arresting capability, and the activation of hemostatic barrier membrane. Moreover, in vivo investigation of the skin injury repair of the rat model validate that CoSt hydrogels accelerate wound healing and functional recovery via skin damage/defects. Tough wet adhesion, quick hemostasis, distinguished biocompatibility, suitability to match irregular-shaped target sites, and good wound healing promotion of the CoSt hydrogel makes it a prospective bioadhesive for various biomedical applications.

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Self‐Propelling Janus Particles for Hemostasis in Perforating and Irregular Wounds with Massive Hemorrhage

Cited by 69 publications

References 46 publications

Microcluster colloidosomes for hemostat delivery into complex wounds: A platform inspired by the attack action of torpedoes

Microcluster colloidosomes for hemostat delivery into complex wounds: A platform inspired by the attack action of torpedoes

Dual-Driven Hemostats Featured with Puncturing Erythrocytes for Severe Bleeding in Complex Wounds

Biomimetic Natural Biopolymer‐Based Wet‐Tissue Adhesive for Tough Adhesion, Seamless Sealed, Emergency/Nonpressing Hemostasis, and Promoted Wound Healing

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