Small-Molecule Therapeutics Achieve Multiple Mechanism-Mediated Sensitizations of Colorectal Cancer to Immune Checkpoint Blockade via Neutrophil Micropharmacies.

Immune checkpoint blockade (ICB) therapy has been approved for colorectal cancer (CRC). However, response rates are variable and often <50%. The low tumor immunogenicity and immunosuppressive tumor microenvironment (TME) jointly contribute to this suboptimal response rate.

Spatiotemporally Controlled T-Cell Combination Therapy for Solid Tumor.

Due to multidimensional complexity of solid tumor, development of rational T-cell combinations and corresponding formulations is still challenging. Herein, a triple combination of T cells are developed with Indoleamine 2,3-dioxygenase inhibitors (IDOi) and Cyclin-dependent kinase 4/6 inhibitors (CDK4/6i). To maximize synergism, a spatiotemporally controlled T-cell engineering technology to formulate triple drugs into one cell therapeutic, is established.

Enhancing Glioblastoma Immunotherapy with Integrated Chimeric Antigen Receptor T Cells through the Re-Education of Tumor-Associated Microglia and Macrophages.

Glioblastoma (GBM) is an aggressive brain cancer that is highly resistant to treatment including chimeric antigen receptor (CAR)-T cells. Tumor-associated microglia and macrophages (TAMs) are major contributors to the immunosuppressive GBM microenvironment, which promotes tumor progression and treatment resistance. Hence, the modulation of TAMs is a promising strategy for improving the immunotherapeutic efficacy of CAR-T cells against GBM.

An elastase-inhibiting, plaque-targeting and neutrophil-hitchhiking liposome against atherosclerosis.

Neutrophil extracellular traps (NETs) play a crucial role in the formation of vulnerable plaques and the development of atherosclerosis. Alleviating the pathological process of atherosclerosis by efficiently targeting neutrophils and inhibiting the activity of neutrophil elastase to inhibit NETs is relatively unexplored and is considered a novel therapeutic strategy with clinical significance. Sivelestat (SVT) is a second-generation competitive inhibitor of neutrophil elastase with high specificity.

New-generation cytopharmaceuticals with powerfully boosted extravasation for enhanced cancer therapy.

Effective extravasation of therapeutic agents into solid tumors still faces huge challenges. Since the doubted effectiveness of enhanced penetration and retention effect, first-generation neutrophil cytopharmaceuticals with encapsulated drugs have been developed to improve the drug accumulation in tumors based on the active chemotaxis and extravasation of neutrophils. Herein, a new generation of neutrophil cytopharmaceuticals with enhanced tumor-specific extravasation is reported to satisfy more complex clinical demands.

Reprogrammed siTNF/neutrophil cytopharmaceuticals targeting inflamed joints for rheumatoid arthritis therapy.

Rheumatoid arthritis (RA) is an autoimmune disease characterized by severe synovial inflammation and cartilage damage. Despite great progress in RA therapy, there still lacks the drugs to completely cure RA patients. Herein, we propose a reprogrammed neutrophil cytopharmaceuticals loading with TNF-targeting-siRNA (siTNF) as an alternative anti-inflammatory approach for RA treatment.

Real-time detection of T cell activation by visualizing TCR nanoclusters with a cholesterol derived aggregation-induced emission probe.

Successful T-cell based immunotherapy usually depends on the activation of T cells. Most of commonly used methods for assessing T cell activity rely on the antibody-based technology, which focus on detecting protein-centered activation markers, including CD25, cytokines and so on. However, these methods always involve tedious sample-preparation process, labor-consuming and costly, which could not be utilized in real-time detection.

Sensitizing Tumors to Immune Checkpoint Blockage via STING Agonists Delivered by Tumor-Penetrating Neutrophil Cytopharmaceuticals.

Immune checkpoint inhibitors (ICIs) have displayed potential efficacy in triple-negative breast cancer (TNBC) treatment, while only a minority of patients benefit from ICI therapy currently. Although activation of the innate immune stimulator of interferon genes (STING) pathway potentiates antitumor immunity and thus sensitizes tumors to ICIs, the efficient tumor penetration of STING agonists remains critically challenging. Herein, we prepare a tumor-penetrating neotype neutrophil cytopharmaceutical (NEs@STING-Mal-NP) with liposomal STING agonists conjugating on the surface of neutrophils, which is different from the typical neutrophil cytopharmaceutical that loads drugs inside the neutrophils.

Single-component lipid nanoparticles for engineering SOCS1 gene-silenced dendritic cells to boost tumor immunotherapy.

Dendritic cells (DCs) that can prime antitumor responses show great potential in tumor immunotherapy, whereas the unsatisfactory effect which can be ascribed in part to the high expression of inhibitory cytokines, such as the suppressor of cytokine signaling 1 (SOCS1), restricts their application. Thus, silencing these genes in DCs is essential for DC-based therapy. However, safe and effective delivery of siRNA to DCs still faces challenges.

The Impaired Mechanism and Facilitated Therapies of Efferocytosis in Atherosclerosis.

Cardiovascular disease is responsible for the largest number of deaths worldwide, and atherosclerosis is the primary cause. Apoptotic cell accumulation in atherosclerotic plaques leads to necrotic core formation and plaque rupture. Emerging findings show that the progression of atherosclerosis appears to suppress the elimination of apoptotic cells.

An EPR-Independent extravasation Strategy: Deformable leukocytes as vehicles for improved solid tumor therapy.

Effective delivery of therapeutic modality throughout the tumorous nidus plays a crucial role in successful solid tumor treatment. However, conventional nanomedicines based on enhanced permeability and retention (EPR) effect have yielded limited delivery/therapeutic efficiency, due mainly to the heterogeneity of the solid tumor. Leukocytes, which could intrinsically migrate across the vessel wall and crawl through tissue interstitium in a self-deformable manner, have currently emerged as an alternative drug delivery vehicle.

Targeted downregulation of HIF-1α for restraining circulating tumor microemboli mediated metastasis.

Tumor metastasis is directly correlated to poor prognosis and high mortality. Circulating tumor cells (CTCs) play a pivotal role in metastatic cascades, of which CTC clusters is highly metastatic compared to single CTCs. Although platelets and neutrophils within the bloodstream could further exacerbate the pro-metastatic effect of single CTCs, the influence of platelets and neutrophils on CTC clusters mediated metastasis remains unclear.

Neutrophil Cyto-Pharmaceuticals Suppressing Tumor Metastasis via Inhibiting Hypoxia-Inducible Factor-1α in Circulating Breast Cancer Cells.

Circulating tumor cells (CTCs) are reported as the precursor of tumor metastases, implying that stifling CTCs would be beneficial for metastasis prevention. However, challenges remain for the application of therapies that aim at CTCs due to lack of effective CTC-targeting strategy and sensitive therapeutic agents. Herein, a general CTC-intervention strategy based on neutrophil cyto-pharmaceuticals is proposed for suppressing CTC colonization and metastasis formation.

Poly-β-cyclodextrin Supramolecular Nanoassembly with a pH-Sensitive Switch Removing Lysosomal Cholesterol Crystals for Antiatherosclerosis.

Cholesterol crystals (CCs), originally accumulating in the lysosome of cholesterol-laden cells, can aggravate the progression of atherosclerosis. β-cyclodextrin (CD) is a potent cholesterol acceptor or CC solubilizer. However, the random extraction of cholesterol impedes the application of CD for removing lysosomal CCs.

A neutrophil-mimetic magnetic nanoprobe for molecular magnetic resonance imaging of stroke-induced neuroinflammation.

Neuroinflammation plays a key role in the progression of brain injury induced by stroke, and has become a promising target for therapeutic intervention for stroke. Monitoring this pivotal process of neuroinflammation is highly desirable to guide specific therapy. However, there is still a lack of a satisfactory nanoprobe to selectively monitor neuroinflammation.

Modular synthesis of amphiphilic chitosan derivatives based on copper-free click reaction for drug delivery.

Amphiphilic chitosan derivatives have attracted wide attention as drug carriers due to their physicochemical properties. However, obtaining a desired amphiphilic chitosan derivative by tuning the various functional groups was complex and time-consuming. Therefore, a facile and common synthesis strategy would be promising.

Combination of metabolic intervention and T cell therapy enhances solid tumor immunotherapy.

Treatment of solid tumors with T cell therapy has yielded limited therapeutic benefits to date. Although T cell therapy in combination with proinflammatory cytokines or immune checkpoints inhibitors has demonstrated preclinical and clinical successes in a subset of solid tumors, unsatisfactory results and severe toxicities necessitate the development of effective and safe combinatorial strategies. Here, the liposomal avasimibe (a metabolism-modulating drug) was clicked onto the T cell surface by lipid insertion without disturbing the physiological functions of the T cell.

Anisamide-functionalized pH-responsive amphiphilic chitosan-based paclitaxel micelles for sigma-1 receptor targeted prostate cancer treatment.

Controlled release and tumor-selective distribution are highly desirable for anticancer nanomedicines. Here, we design and synthesize an anisamide-conjugated N-octyl-N,O-maleoyl-O-phosphoryl chitosan (a-OMPC) which can form amphiphilic micelles featuring pH-responsive release and high affinity to sigma-1 receptor-overexpressed tumors for paclitaxel (PTX) delivery. Thereinto, maleoyl and phosphoryl groups cooperatively contribute to pH-responsive drug release due to a conversion from hydrophile to hydrophobe in the acidic microenvironment of endo/lysosomes.

An apoptotic body-biomimic liposome in situ upregulates anti-inflammatory macrophages for stabilization of atherosclerotic plaques.

The macrophages mediated inflammation participates in every stage of atherosclerosis. Attenuation of macrophages inflammatory responses by active ingredients in atherosclerotic plaques is benefit to atherosclerotic stabilization and regression, but meanwhile, it is highly desired to develop accurate therapeutics for reducing off-target effects. Previous studies revealed that the apoptotic bodies are effectively recognized and engulfed by macrophages own to increased exposure of phosphatidylserine (PtdSer), which is regarded as a key "eat-me" signal.

Recognition, Intervention, and Monitoring of Neutrophils in Acute Ischemic Stroke.

Neutrophils are implicated in numerous inflammatory diseases, and especially in acute ischemic stroke (AIS). The unchecked migration of neutrophils into cerebral ischemic regions, and their subsequent release of reactive oxygen species, are considered the primary causes of reperfusion injury following AIS. Reducing the infiltration of inflammatory neutrophils may therefore be a useful therapy for AIS.

Cellular Vehicles Based on Neutrophils Enable Targeting of Atherosclerosis.

Given the multiple interactions between neutrophils (NEs) and atherosclerosis (AS), in this study, we exploited NEs as cellular vehicles loaded with cationic liposomes for actively targeting atherosclerotic sites. The cellular vehicles based on NEs possess efficient internalization of cationic liposomes and sensitive response to the chemotaxis of atherosclerotic inflammatory cells, which ultimately realize the targeted delivery of the cargos into the target cells in vitro. Moreover, these effects also translated to significant enhancement of the accumulation of NEs' cargos into the atherosclerotic plaque in vivo after administering NE vehicles to the AS animal model.

Co-delivery of TRAIL and siHSP70 using hierarchically modular assembly formulations achieves enhanced TRAIL-resistant cancer therapy.

The combined therapy of tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) and heat shock protein 70-targeting siRNA (siHSP70) has shown an improved anti-tumor effect on TRAIL-resistant tumor. However, vehicles to co-deliver these two biopharmaceuticals are challenging because of the distinct location of their targets on the cell surface and in the cytosol. Here we developed a hierarchically modular assembly formulation (TH-s-RSC) via the copper-free click reaction to co-encapsulate the positively-charged TRAIL and negatively-charged siHSP70 and release them in the extracellular space and cytoplasm.

The development of tertiary amine cationic lipids for safe and efficient siRNA delivery.

Cationic liposomes have shown great potential in efficient siRNA delivery, and their positive charge is crucial for tight extracellular siRNA binding, effective intracellular siRNA disassembly and physiological toxicity. Thus, the development of novel cationic lipids with a suitable positive charge is desirable for safe and efficient siRNA delivery. Herein, we fabricated a library of 21 tertiary amine-derived cationic lipids (TA) to achieve a balance between effectiveness and safe siRNA delivery.