ABSTRACT
Iron is essential for many physiological processes, and the dysregulation of its metabolism is implicated in the pathogenesis of various diseases. Recent advances in iron metabolism research have revealed multiple complex pathways critical for maintaining iron homeostasis. Molecular imaging, an interdisciplinary imaging technique, has shown considerable promise in advancing research on iron metabolism. Here, we comprehensively review the multifaceted roles of iron at the cellular and systemic levels (along with the complex regulatory mechanisms of iron metabolism), elucidate appropriate imaging methods, and summarize their utility and fundamental principles in diagnosing and treating diseases related to iron metabolism. Utilizing molecular imaging technology to deeply understand the complexities of iron metabolism and its critical role in physiological and pathological processes offers new possibilities for early disease diagnosis, treatment monitoring, and the development of novel therapies. Despite technological limitations and the need to ensure the biological relevance and clinical applicability of imaging results, molecular imaging technology's potential to reveal the iron metabolic process is unparalleled, providing new insights into the link between iron metabolism abnormalities and various diseases.
ABSTRACT
The ultimate goal of cutaneous wound healing is to reform a stratified epithelium to restore the normal epidermal barrier, which involves the epithelial-to-mesenchymal transition (EMT) process. However, healing strategies based on EMT induction are immature and ambiguous to date. Excessive induction of EMT may cause fibrosis, hypertrophic scarring, and increased risk of malignancy. Here, we present a new EMT-inducing strategy for eliciting partial EMT to facilitate proper epithelial cell migration. The new EMT-inducing system integrates black phosphorus nanosheets (BPNSs), catechol-modified chitosan (CA-CS), and oxidized dextran (Odex) to engineer an adhesive hydrogel patch (C&BP-Patch) with remarkable efficacy on infectious burn wound healing. The C&BP-Patch can orchestrate key early skin wound healing processes including hemostasis, inflammation, and proliferation, which enable fast partial EMT induction to restore an intact epithelial barrier. The C&BP-Patch acts initially as a high-performance bio-sealant to create a moist and stable microenvironment for EMT. Moreover, the photothermal effects of the C&BP-Patch can eliminate bacteria, accelerate microcirculation and reduce inflammation to maintain a proper EMT. Most importantly, the BPNSs can intrinsically induce partial EMT of epithelial cells via a Snail1-mediated signaling pathway. Therefore, our study proposes a new strategy for effective infectious burn wound healing based on inducing partial EMT.
