An infected skin wound caused by external injury remains a serious challenge in clinical practice. Wound dressings with the properties of antibacterial activity and potent regeneration capacity are highly desirable for wound healing. In this paper, a degradable, ductile, and wound-friendly Zn-MOF encapsulated methacrylated hyaluronic acid (MeHA) microneedles (MNs) array is fabricated through the molding method for promoting wound healing. Due to the damage capability against the bacteria capsule and oxidative stress of the zinc ion released from the Zn-MOF, such MNs array presents excellent antibacterial activity, as well as considerable biocompatibility. Besides, the degradable MNs array composed of photo-crosslinked MeHA possesses the superior capabilities to continuously and steadily release the loaded active ingredients and avoid secondary damage to the wound. Moreover, the low molecular weight hyaluronic acid (HA) generated by hydrolysis of MeHA is also conducive to tissue regeneration. Benefiting from these features, it has been demonstrated that the Zn-MOF encapsulated degradable MNs array can dramatically accelerate epithelial regeneration and neovascularization. These results indicate that the combination of MOFs and degradable MNs array is of great value for promoting wound healing.
Patches with the capacity of controllable delivering active molecules toward the wound bed to promote wound healing are expectant all along. Herein, a novel porous metal‐organic framework (MOF) microneedle (MN) patch enabling photothermal‐responsive nitric oxide (NO) delivery for promoting diabetic wound healing is presented. As the NO‐loadable copper‐benzene‐1,3,5‐tricarboxylate (HKUST‐1) MOF is encapsulated with graphene oxide (GO), the resultant NO@HKUST‐1@GO microparticles (NHGs) are imparted with the feature of near‐infrared ray (NIR) photothermal response, which facilitate the controlled release of NO molecules. When these NHGs are embedded in a porous PEGDA‐MN, the porous structure, larger specific surface area, and sufficient mechanical strength of the integrated MN could promote a more accurate and deeper delivery of NO molecules into the wound site. By applying the resultant NHG‐MN to the wound of a type I diabetic rat model, the authors demonstrate that it is capable of accelerating vascularization, tissue regeneration, and collagen deposition, indicating its bright prospect applied in wound healing and other therapeutic scenarios.
In article number 2100056 by Yongan Wang, Yuan Luo, Yuanjin Zhao, and co‐workers, a ZIF‐8@MeHA microneedle (MN) array is fabricated by template molding method for wound healing. Such an MN patch has a good antibacterial effect by releasing Zn2+ to kill microbes. Meanwhile, the MeHA hydrogel is capable of promoting the regeneration of neonatal epithelial tissues through gradual degradation.
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