Cell Mitosis Research Articles

TMOD-35. EGFRVIII OVEREXPRESSION AND LOSS OF MOUSE SPECIFIC CDKN2A IN GLIAL CELLS LEADS TO SPONTANEOUS GLIOMAGENESIS IN A NOVEL MOUSE MODEL

Abstract A new mouse model for the classical subtype of human glioblastoma (GBM) has been bred using Cre-mediated EGFRvIII overexpression and homozygous p19-ARF deletion, the mouse homolog of human p14ARF/CDKN2A, in GFAP expressing cells. Transgenic mice develop intraparenchymal and/or leptomeningeal brain lesions with some spinal cord invasion as early as 1 month old and 95% of mice die by 6 months due to hydrocephalus and/or paralysis. Mice with high grade tumors have worse survival and similar features to human classical GBM such as necrosis, high levels of mitosis and infiltration of tumor cells into normal brain. Immunohistochemical analysis confirms EGFRvIII overexpression and p19-ARF loss in Cre-expressing cells, along with patchy positive GFAP and high proliferation by Ki67. Bulk RNA sequencing reveals GEC3 tumors cluster closely with human classical GBM and have significant upregulation of downstream markers in the JAK/STAT and P13K/AKT pathways. Adherent and neurosphere primary culture of dissociated tumors indicate that tumor cells maintain EGFRvIII expression in culture and generate xenograft tumors by 3 weeks after intracranial injections into NODSCID mice. Xenograft tumors are reminiscent of the primary tumor, with similar histopathological features and immunohistochemical staining. Our spontaneous glioma model is a powerful tool for future studies focused on the role of the immune microenvironment on glioma recurrence and resistance.

NEK2 is a potential pan-cancer biomarker and immunotherapy target

BackgroundNEK2 is a member of the NEKs family and plays an important role in cell mitosis. Increasing evidence suggests that NEK2 is associated with the development of multiple tumors, but systematic studies of NEK2 in cancer are still lacking. Therefore, we evaluated the prognostic value of NEK2 in 33 cancers to elucidate the potential function of NEK2 in pan-cancers.MethodsWe investigated the role of NEK2 in pan-cancers utilizing The Cancer Genome Atlas (TCGA) and the Genotype-Tissue Expression (GTEx) database. Additionally, we analyzed the association between NEK2 gene expression across various cancers, protein expression, the tumor microenvironment (TME), and drug sensitivity using several software and web platforms.The potential oncogenic role of NEK2 was initially explored using bioinformatics methods. Furthermore, we conducted in vitro experiments to preliminarily validate the function of NEK2 in cervical cancer.ResultsNEK2 is overexpressed in almost all tumors, and mutation of NEK2 are associated with a poorer tumor prognosis. In addition, the correlation between NEK2 and immune features such as immune cell infiltration, immune checkpoint genes, tumor mutational burden (TMB), Microsatellite instability(MSI) etc. suggest that NEK2 could potentially be applied in the immunotherapy of tumors.ConclusionNEK2 may be a potential pan-cancer biomarker and immunotherapeutic target for improving the efficacy of tumor therapy.

NEK2 Promotes ESCC Malignant Progression by Inhibiting Cellular Senescence via the FOXM1/c-Myc/p27 Signaling Pathway.

Never in mitosis gene A (NIMA)-related kinase 2 (NEK2) is a crucial serine-threonine kinase involved in the process of cell mitosis. However, the precise relationship between NEK2 and esophageal squamous cell carcinoma (ESCC) remains inadequately understood. NEK2 expression in ESCC tissues was assessed through bioinformatics analysis, reverse transcription-quantitative PCR (RT-qPCR) and immunohistochemistry, revealing a correlation with ESCC patient prognosis. Cultured ESCC cells and human normal esophageal epithelial cells (HEEC) were used to investigate the effects of NEK2 knockdown on the development and progression of ESCC by integrated confluence algorithm, colony formation, wound-healing, transwell, and ESCC xenograft tumor model, in vitro and in vivo. In ESCC tissues, NEK2 was found to be significantly upregulated, and its expression correlated with poor prognosis in ESCC patients. NEK2 may facilitate ESCC development by regulating cell proliferation, migration, and invasion. Additionally, results from in vivo experiments suggested that NEK2 knockdown can inhibit tumor growth. Moreover, forkhead box M1 (FOXM1) was identified as a potential downstream target of NEK2 in the regulation of ESCC, with its overexpression reversing the effects of NEK2 knockdown on ESCC. Mechanistic studies also indicated that NEK2 may promote the malignant progression of ESCC by inhibiting cellular senescence through the activation of the FOXM1/c-Myc/p27 signaling pathways, which may provide a novel perspective for the management of ESCC.

Single-agent Adavosertib Shows Anticancer Effects Against Colorectal Cancer Cells.

Colorectal cancer (CRC) is the third most common malignancy and the second most common cause of cancer-related deaths worldwide. Adavosertib (AZD1775), a small molecule inhibitor of WEE1 kinase, abrogates G2/M cell cycle arrest and induces double-stranded DNA breaks. According to previous findings, adavosertib, in combination with other DNA-damaging agents, causes premature mitosis and cell death in p53-mutated cancer cells mainly via abrogation of the G2/M cell cycle checkpoint. This study aims to evaluate the inhibition of WEE1 kinase by adavosertib as monotherapy in the TP53-wildtype human CRC cell line HCT116. In this study, HCT116 cells were treated with different concentrations of adavosertib for 24 to 72 hours. Cell viability was assessed by Water-Soluble Tetrazolium 1 (WST-1) assay and crystal violet assays. Cell migration was evaluated by the wound healing assay. Cell cycle distribution and apoptosis were analyzed by flow cytometry. The IC50 value of adavosertib for the HCT116 cell line was 0.1310 μM. Adavosertib monotherapy (both 0.125 and 0.250 μM) significantly reduced cell viability, inhibited cell migration and abrogated intra-S phase cell cycle arrest. In addition, 0.250 μM of adavosertib significantly induced apoptosis in HCT116 cells. Adavosertib effectively inhibits the TP53-wildtype HCT116 cells via the abrogation of intra-S phase cell cycle arrest. Our findings suggest that adavosertib monotherapy may be a potential targeted therapy for CRC.

Molecular details and phosphoregulation of the CENP-T-Mis12 complex interaction during mitosis in DT40 cells

Molecular details and phosphoregulation of the CENP-T-Mis12 complex interaction during mitosis in DT40 cells

Establishing a Mandibular Osteosarcoma Model in SD Rats Using Tissue Block Transplantation.

To investigate the feasibility of establishing a mandibular osteosarcoma model in Sprague-Dawley (SD) rats using tissue block transplantation, providing a foundational model for osteosarcoma research. Fourteen male SD rats, 3 weeks old and SPF grade, were randomly divided into a control group (n=4) and a mandibular osteosarcoma group (n=10). Using tissue block transplantation, UMR106 cell-induced tumor tissues were transplanted subcutaneously into the left mandibular marrow cavity of the SD rats. Observations included behavioral changes, weight variations, tumor growth, and tumor formation rate. Bone changes were monitored via micro-CT scanning, and histological analysis was conducted using HE staining. Two weeks post-transplantation, the mandibular osteosarcoma group exhibited significant left facial swelling, malocclusion, eating difficulties, and weight loss compared to the control group. The tumor formation rate was 80% (8/10). Micro-CT scans indicated significant bone destruction in the osteosarcoma group. HE staining revealed high cellular atypia and pathological mitoses in both subcutaneous and mandibular osteosarcoma cells, with no notable abnormalities in lung tissues. Tissue block transplantation is a viable method to establish a mandibular osteosarcoma model in SD rats. This method is simple, with a high tumor formation rate, providing an ideal animal model for mandibular osteosarcoma research.

Intramammary Labeling of Epithelial Cell Division

Thymidine analogs such as ethynyl deoxyuridine (EdU) or bromodeoxyuridine (BrdU) can be used to label mitosis of mammary epithelial cells (MEC) and to quantify their proliferation. However, labeling cells in larger animals requires considerable amounts of chemical that can be costly and hazardous. We developed a strategy to infuse EdU into the mammary glands of ewes to directly label mitotic MEC. First, each udder half of nulliparous ewes (n = 2) received an intramammary infusion of one of four different concentrations of EdU (0, 0.1, 1.0 or 10 mM) which was compared to BrdU IV (5 mg/kg) 24 h later. Tissues were analyzed by immunofluorescent histochemistry to detect EdU, BrdU, and total MEC. Of the EdU doses tested, 10 mM EdU yielded the greatest labeling index, while a proportion of MEC were labeled by both EdU and BrdU. We next sought to establish whether intramammary labeling could detect the induction of mitosis after exposure to exogenous estrogen and progesterone (E + P). We first infused EdU (10 mM) into the right udder half of ewes (n = 6) at t 0, followed by thymidine (100 mM) 24 h later to prevent further labeling. Three ewes were then administered E + P for 5 d, while n = 3 ewes served as controls. On d 5, EdU was infused into the left udder half of all mammary glands alongside BrdU IV (5 mg/kg). By the time of necropsy 24 h later an average MEC labeling index of 2.9% resulted from EdU delivered at t 0. In the left half of the udder on d 5, CON glands had a final EdU labeling index of 3.4% while glands exposed to E + P had a labeling index of 4.6% (p = 0.05). The corresponding degree of labeling with BrdU was 5.6% in CON glands, and 12% following E + P (p < 0.001). Our findings reveal that intramammary labeling is an efficient and cost-effective method for single- and dual-labeling of cell division in the mammary glands.

Recent advances in Tumor Treating Fields (TTFields) therapy for glioblastoma.

Tumor Treating Fields (TTFields) therapy is a locoregional, anticancer treatment consisting of a noninvasive, portable device that delivers alternating electric fields to tumors through arrays placed on the skin. Based on efficacy and safety data from global pivotal (randomized phase III) clinical studies, TTFields therapy (Optune Gio) is US Food and Drug Administration-approved for newly diagnosed (nd) and recurrent glioblastoma (GBM) and Conformité Européenne-marked for grade 4 glioma. Here we review data on the multimodal TTFields mechanism of action that includes disruption of cancer cell mitosis, inhibition of DNA replication and damage response, interference with cell motility, and enhancement of systemic antitumor immunity (adaptive immunity). We describe new data showing that TTFields therapy has efficacy in a broad range of patients, with a tolerable safety profile extending to high-risk subpopulations. New analyses of clinical study data also confirmed that overall and progression-free survival positively correlated with increased usage of the device and dose of TTFields at the tumor site. Additionally, pilot/early phase clinical studies evaluating TTFields therapy in ndGBM concomitant with immunotherapy as well as radiotherapy have shown promise, and new pivotal studies will explore TTFields therapy in these settings. Finally, we review recent and ongoing studies in patients in pediatric care, other central nervous system tumors and brain metastases, as well as other advanced-stage solid tumors (ie, lung, ovarian, pancreatic, gastric, and hepatic cancers), that highlight the broad potential of TTFields therapy as an adjuvant treatment in oncology.

PIWIL1 is recruited to centrosomes during mitosis in colorectal cancer cells and is linked to cell cycle progression

PIWI proteins, traditionally associated with germline development, have recently gained attention for their expression in various cancers, including colorectal cancer. However, the molecular mechanisms underlying their reactivation and impact on cancer initiation and progression remain elusive. Here, we found that PIWIL1 is expressed at relatively high levels in CRC-derived samples and cell lines, where it undergoes a dynamic relocalization to the centrosome during mitosis. Knockdown of PIWIL1 induces G2/M arrest associated with disruption of the mitotic spindle and aberrant metaphase events, highlighting its role in cell cycle progression. We also found that the expression of PIWIL1 is lost during the differentiation of Caco-2 cells into enterocytes and that PIWIL1 is expressed in cells at the base of the intestinal crypts in normal human colon tissue, where intestinal stem cells are known to reside. Thus, it is possible that the presence of PIWIL1 in cancer cells reflects a physiological role of this protein in stem cell maintenance, which would argue in favor of the proposed stem cell origin of CRC. Supporting this view, dedifferentiation of human fibroblasts into induced pluripotent stem cells (iPSCs) involves the reactivation of PIWIL2 expression, another member of the PIWI protein family. Overall, our findings suggest a role of PIWIL1 in mediating cell cycle dynamics, both in colorectal cancer cells and possibly also in intestinal stem cells. In a broader aspect, we provide evidence supporting an involvement of PIWI proteins in somatic stem cell maintenance, thus expanding the known non-gonadal functions of this protein family.

Cdk1 Deficiency Extends the Postnatal Window of Cardiomyocyte Proliferation and Restores Cardiac Function after Myocardial Infarction.

Cyclin-dependent kinase 1 (Cdk1) is a master regulator of the G2-M transition between DNA replication and cell division. This study investigates the regulation of cardiomyocyte (CM) proliferation during the early neonatal period and following ischemic injury in adult mice. We analyzed cell cycle dynamics with the assessment of DNA synthesis, and cytokinesis in murine hearts during the first 15 days after birth. A distinct proliferative block was observed at 1 day, followed by a second wave of DNA synthesis at 4 days, leading to CM binucleation (CMBN) by day 5. Genome-wide mRNA profiling revealed the differential expression of cell cycle regulatory genes during this period, with a downregulation of factors involved in cell division and mitosis. The loss of Cdk1 impaired CMBN but extended the neonatal CM proliferation window until day 10 post-birth. In adult hearts, the cardiac-specific ablation of Cdk1 triggered CM proliferation post-myocardial-infarction (MI) in specific zones, driven by the activation of EGFR1 signaling and suppression of the anti-proliferative p38 and p53 signaling. This was accompanied by restoration of fractional shortening, mitochondrial function, and decreased reactive oxygen species. Additionally, cardiac hypertrophy was mitigated, and survival rates post-MI were increased in Cdk1-knockout mice. These findings reveal a novel role of Cdk1 in regulating cell cycle exit and re-entry in differentiated CMs and offer insights into potential strategies for cardiac repair.

TonEBP degradation is essential for microtubule nucleation and regrowth

TonEBP is a transcription factor known for its involvement in diverse physiological processes, including cell cycle, mitosis, migration, and cytoskeletal remodeling. However, the role of TonEBP regarding microtubules, essential structural components of the cytoskeleton, remains unclear. Here, we introduce a novel function for TonEBP as a regulator of microtubule nucleation. Our initial findings reveal that Nocodazole, a well-known microtubule depolymerizing agent, significantly downregulates the protein level of TonEBP. Moreover, microtubule depolymerization induces rapid degradation of TonEBP through the ubiquitin-proteasome pathway. Knockdown of TonEBP results in enhanced microtubule polymerization and regrowth, whereas the presence of TonEBP impairs microtubule nucleation. Collectively, our data suggest that TonEBP negatively regulates microtubule nucleation.

Kinesins regulate the heterogeneity in centrosome clustering after whole-genome duplication.

After whole-genome duplication (WGD), tetraploid cells can undergo multipolar mitosis or pseudo-bipolar mitosis with clustered centrosomes. Kinesins play a crucial role in regulating spindle formation. However, the contribution of kinesin expression levels to the heterogeneity in centrosome clustering observed across different cell lines after WGD remains unclear. We identified two subsets of cell lines: "BP" cells efficiently cluster extra centrosomes for pseudo-bipolar mitosis, and "MP" cells primarily undergo multipolar mitosis after WGD. Diploid MP cells contained higher levels of KIF11 and KIF15 compared with BP cells and showed reduced sensitivity to centrosome clustering induced by KIF11 inhibitors. Moreover, partial inhibition of KIF11 or depletion of KIF15 converted MP cells from multipolar to bipolar mitosis after WGD. Multipolar spindle formation involved microtubules but was independent of kinetochore-microtubule attachment. Silencing KIFC1, but not KIFC3, promoted multipolar mitosis in BP cells, indicating the involvement of specific kinesin-14 family members in counteracting the forces from KIF11/KIF15 after WGD. These findings highlight the collective role of KIF11, KIF15, and KIFC1 in determining the polarity of the mitotic spindle after WGD.

The Role of Nde1 phosphorylation in interkinetic nuclear migration and neural migration during cortical development.

Nde1 is a cytoplasmic dynein regulatory protein with important roles in vertebrate brain development. One noteworthy function is in the nuclear oscillatory behavior in neural progenitor cells, the control and mechanism of which remain poorly understood. Nde1 contains multiple phosphorylation sites for the cell cycle-dependent protein kinase CDK1, though the function of these sites is not well understood. To test their role in brain development, we expressed phosphorylation-state mutant forms of Nde1 in embryonic rat brains using in utero electroporation. We find that Nde1 T215 and T243 phosphomutants block apical interkinetic nuclear migration (INM) and, consequently, mitosis in radial glial progenitor cells. Another Nde1 phosphomutant at T246 also interfered with mitotic entry without affecting INM, suggesting a more direct role for Nde1 T246 in mitotic regulation. We also found that the Nde1 S214F mutation, which is associated with schizophrenia, inhibits Cdk5 phosphorylation at an adjacent residue which causes alterations in neuronal lamination. These results together identify important new roles for Nde1 phosphorylation in neocortical development and disease, and represent the first evidence for Nde1 phosphorylation roles in INM and neuronal lamination.

Investigation of phytotoxic effects of fullerene С60 with the use of Allium-test

Aim. To investigate the cytogenetic effects of water-soluble fullerene C60 with the use of Allium test. To study the influence of various concentrations of fullerene С60 on the morpho-physiological parameters of A. cepa. Methods. The influence of different concentrations of fullerene С60 (25–100 μg/ml) on the induction of root formation and their growth, as well as its cytogenetic effects on the meristematic cells of root apices, were investigated. Results. It was found that fullerene C60 at concentrations of 50 and 75 μg/ml induced root formation and stimulated root growth, though causing minor deformations. Also, it was shown that fullerene С60 disrupts the progression of various phases of mitosis in the meristematic cells of roots, along with the occurrence of chromosomal aberrations at all investigated concentrations. Conclusions. The cytogenetic effects of water-soluble fullerene C60 were investigated for the first time using the Allium-test. Both positive effects on the morphophysiological parameters of A. cepa and its genotoxicity were demonstrated, which could indicate the disruptions in the mechanisms of spindle formation.

STAT3 and the STAT3‑regulated inhibitor of apoptosis protein survivin as potential therapeutic targets in colorectal cancer (Review).

Colorectal cancer (CRC) is one of the leading types of cancer worldwide. CRC development has been associated with the constitutive activation of signal transducer and activator of transcription 3 (STAT3). STAT3 is a master regulator of inflammation during cancer-associated colitis, and becomes upregulated in CRC. In CRC, STAT3 is activated by IL-6, among other pro-inflammatory cytokines, inducing the expression of target genes that stimulate proliferation, angiogenesis and the inhibition of apoptosis. One of the main STAT3-regulated inhibitors of apoptosis is survivin, which is a bifunctional protein that regulates apoptosis and participates in cell mitosis. Survivin expression is normally limited to foetal tissue; however, survivin is also upregulated in tumours. In silico and experimental analyses have shown that the STAT3 interactome is relevant during CRC progression, and the constitutive STAT3-survivin axis participates in development of the tumour microenvironment and response to therapy. The presence of a STAT3-survivin axis has been documented in CRC cohorts, and the expression of these molecules is associated with poor prognosis and a higher mortality rate in patients with CRC. Thus, STAT3, survivin, and the upstream activators IL-6 and IL-6 receptor, are considered therapeutic targets for CRC. Efforts to develop drugs targeting the STAT3-survivin axis include the evaluation of phytochemical compounds, small molecules and monoclonal antibodies. In the present review, the expression, function and participation of the STAT3-survivin axis in the progression of CRC were investigated. In addition, an update on the pre-clinical and clinical trials evaluating potential treatments targeting the STAT3-survivin axis is presented.

Gut mucosa alterations after kidney transplantation: a cross sectional study.

Kidney transplant recipients (KTRs) rely on immunosuppressants like mycophenolate to prevent organ rejection. However, mycophenolate often causes intestinal symptoms and inflammation in various organs, including the skin and the colon. While KTRs have an increased risk for skin cancer, the risk of colorectal cancer is not increased. Elucidating the histological alterations in the colon of KTRs and comparing these changes with known skin alterations would help understand how immunosuppressants influence cancer development and progression. Whole slide images from gut biopsies (Non-transplanted subjects n = 35, KTRs n = 49) were analyzed using the ImageJ and R programming environment. A total of 22,035 epithelial cells, 38,870 interstitial cells, 3465 epithelial cell mitoses, and 7477 endothelial cells, each characterized by multiple microscopy parameters, from a total of 1788 glands were analyzed. The large database was subsequently analyzed to verify the changes of inflammatory milieu in KTRs and in cancer. KTRs without colon-cancer showed a significantly higher density of interstitial cells in the colon compared to non-transplanted patients. Moreover, the increase in interstitial cell number was accompanied by subtle modifications in the architecture of the colon glands, without altering the epithelial cell density. We could not identify significant structural modifications in cancer samples between KTRs and non-transplanted patients. Our findings demonstrate an increased number of resident interstitial cells in the colon of KTRs, as in other patients treated with mycophenolate. These changes are associated with subtle alterations in the architecture of colon glands.

Ion-mediated condensation controls the mechanics of mitotic chromosomes

During mitosis in eukaryotic cells, mechanical forces generated by the mitotic spindle pull the sister chromatids into the nascent daughter cells. How do mitotic chromosomes achieve the necessary mechanical stiffness and stability to maintain their integrity under these forces? Here we use optical tweezers to show that ions involved in physiological chromosome condensation are crucial for chromosomal stability, stiffness and viscous dissipation. We combine these experiments with high-salt histone depletion and theory to show that chromosomal elasticity originates from the chromatin fibre behaving as a flexible polymer, whereas energy dissipation can be explained by modelling chromatin loops as an entangled polymer solution. Taken together, we show how collective properties of mitotic chromosomes, a biomaterial of incredible complexity, emerge from molecular properties, and how they are controlled by the physico-chemical environment.

Iron citrate Synthesit: impact on blood parameters in non-iron deficient models

Iron's significance extends beyond treating anemia, impacting various disorders. However, studies on iron-fortified diets in healthy subjects are limited. To evaluate the effects of Synthesit iron citrate on biochemical, hematological parameters, and body weight in aged rhesus macaques, and its safety in SHK-line mice. An experimental study involved SHK mice and rhesus macaques receiving Synthesit iron citrate, with blood parameters, histology, hematopoietic stem cells, and biochemistry monitored over 30 days (14 mice) and six weeks (8 macaques). The study shows increased hematopoietic cell types and mitosis index, with significant increases in Myelokaryocyte count (32.4%), megakaryocyte count (3.7-fold), myeloblast count (1.7-fold), mononuclear cell count (2.5-fold), erythroblast count (4-fold), and reticulocytes (13.3%). In macaques, supplementation initially reduced erythrocyte count, followed by recovery, while thrombocyte count increased initially but decreased post-supplementation. Leukocyte analysis showed varied responses, with a decrease in monocyte and lymphocyte but an increase in neutrophil percentage. Biochemical analyses revealed improvements in glucose (baseline: 4.36 ± 0.32 mmol/l vs day 43: 3.30 ± 1.06 mmol/l), cholesterol (baseline: 4.563 ± 0.799 mmol/l vs day 29: 2.84 ± 0.88 mmol/l), and triglyceride levels (baseline: 1.49 ± 0.63 mmol/l vs day 29: 0.70 ± 0.34 mmol/l). The novel study reveals the effects of iron citrate synthesis in non-iron deficient models into the blood parameters which has metabolic potential. In conclusion, Synthesit® iron citrate supplementation exhibits promising effects on hematopoiesis and metabolic parameters in murine and primate models.

MG53 suppresses tumor growth via transcriptional inhibition of KIF11 in pancreatic cancer

Pancreatic ductal adenocarcinoma (PDAC) poses a formidable challenge in oncology due to its limited treatment options and poor long-term survival rates. Our previous work identified MG53, a member of the tripartite motif family protein (TRIM72), as a key player in tissue repair with potential applications in regenerative medicine. Despite the focus on MG53’s cytosolic functions, its nuclear role in suppressing pancreatic cancer remains unknown. Through orthotopic and subcutaneous transplantation studies in mice, we observed enhanced tumor growth in MG53-deficient mice compared to wild-type counterparts. The overexpression of KIF11, a motor protein crucial for cell mitosis regulation, has been linked to the aggressive proliferation of pancreatic cancer cells. Confocal imaging confirmed MG53′s presence in the nucleus of human pancreatic cancer cells, while functional assays demonstrated its impact on KIF11 expression and subsequent cell proliferation. Mechanistically, we revealed MG53′s transcriptional control over KIF11, leading to cell cycle arrest. Our findings position MG53 as a promising tumor suppressor in PDAC, offering a novel avenue for therapeutic intervention by regulating KIF11 expression.

Photothermal and Antibacterial PDA@Ag/SerMA Microneedles for Promoting Diabetic Wound Repair.

Diabetic foot ulcer (DFU) is a common and severe complication of diabetes characterized by wound neuropathy, ischemia, and susceptibility to infection, making its treatment difficult. Dressings are commonly used in treating diabetic wounds; however, they have disadvantages, including lack of flexibility and mechanical strength, lack of coagulation activity, resistance to biodegradation, and low drug delivery efficiency. Developing more effective strategies for diabetic wound treatment has become a new focus. Microneedles (MN) can be used as a drug delivery platform for DFU wounds, allowing safe, effective, painless and minimally invasive medication administration through the skin. Herein, PDA@Ag/SerMA microneedles were prepared by combining the photothermal properties of polydopamine (PDA), the antimicrobial properties of argentum (Ag), and the ability of sericin methacryloyl (SerMA) to promote cell mitosis to accelerate wound healing and treat diabetic ulcer wounds. The results revealed that PDA@Ag/SerMA microneedles exhibited approximately 100% antimicrobial efficacy against Staphylococcus aureus and Escherichia coli under 808 nm near-infrared (NIR) irradiation. Furthermore, the wound healing rate of mice reached 95% within 12 days, which demonstrated the excellent antibacterial properties and wound healing efficacy of PDA@Ag/SerMA microneedles at cellular and animal levels, providing a potential solution for treating DFU.