Engineered exosomes from different sources for cancer-targeted therapy

Past, present, and future of exosomes research in cancer: A bibliometric and visualization analysis

Cancer seriously threatens the lives and health of people worldwide, and exosomes seem to play an important role in managing cancer effectively, which has attracted extensive attention from researchers in recent years. This study aimed to scientifically visualize exosomes research in cancer (ERC) through bibliometric analysis, reviewing the past, summarizing the present, and predicting the future, with a view to providing valuable insights for scholars and policy makers. Researches search and data collection from Web of Science Core Collection and clinical trial.gov. Calculations and visualizations were performed using Microsoft Excel, VOSviewer, Bibliometrix R-package, and CiteSpace. As of December 1, 2024, and March 8, 2025, we identified 8,001 ERC-related publications and 107 ERC-related clinical trials, with an increasing trend in annual publications. Our findings supported that China, Nanjing Medical University, and International Journal of Molecular Sciences were the most productive countries, institutions, and journals, respectively. Whiteside, Theresa L. had the most publications, while Théry, C was the most co-cited scholar. In addition, Cancer Research was the most co-cited journal. Spatial and temporal distribution of clinical trials was the same as for publications. High-frequency keywords were "extracellular vesicle," "microRNA" and "biomarker." Additional, "surface functionalization," "plant," "machine learning," "nanomaterials," "promotes metastasis," "engineered exosomes," and "macrophage-derived exosomes" were promising research topics. Our study comprehensively and visually summarized the structure, hotspots, and evolutionary trends of ERC. It would inspire subsequent studies from a macroscopic perspective and provide a basis for rational allocation of resources and identification of collaborations among researchers.

Endoscopic nasal delivery of engineered endothelial progenitor cell-derived exosomes improves angiogenesis and neurological deficits in rats with intracerebral hemorrhage

Intracerebral hemorrhage (ICH) remains a life-threatening condition due to its high mortality and limited treatment options. This study explores a novel therapeutic strategy using engineered exosomes derived from endothelial progenitor cells (EPC-EXOs) to improve ICH outcomes. EPC-EXOs were modified with a CD47-enriched red blood cell membrane via co-extrusion to enhance their anti-phagocytic properties, thereby reducing degradation by activated microglia after ICH. A minimally invasive endoscopic-guided delivery system was developed to facilitate the targeted intranasal administration of these engineered EPC-EXOs (m-Oe-EXOs), allowing direct entry into brain tissue. We confirmed m-Oe-EXOs' high retention and effective distribution in the brain. Functional analysis demonstrated that EPC-EXOs significantly promoted the proliferation, migration, and angiogenesis of brain microvascular endothelial cells (BMECs), with proteomic analysis identifying HSP90 as a key protein activating the Akt pathway in BMECs. In vivo, m-Oe-EXOs demonstrated therapeutic efficacy by improving blood-brain barrier integrity, reducing hematoma volume, and enhancing neurological recovery in ICH rats. Collectively, our findings highlight the potential of minimally invasive, endoscopic-guided delivery of m-Oe-EXOs as an innovative approach for ICH treatment, providing new insights into targeted, exosomes-based regenerative therapies.

Titanium nitride meta-biosensors targeting extracellular vesicles for high-sensitivity prostate cancer detection

Disposable plasmonic metasurfaces with high biosensing performance are urgently sought for clinical label-free detection. Low-cost aluminum (Al) and titanium nitride (TiN) offer promising alternatives to noble metals for constructing these metasurfaces. However, Al suffers from limited chemical stability, and TiN exhibits weak plasmonic effects, both of which hinder their application in meta-biosensing. Here we integrate their complementary advantages and propose the TiN/Al meta-biosensors. They not only empower the unique near-field enhancement for sensing by TiN/Al hybrid plasmonic modes, but also construct a robust TiN armor against external wear, heat, moisture and corrosion during the bio-detection process. Compared to traditional gold-based counterparts, our meta-biosensors offer superior optical sensitivity at a much lower cost and with fewer pretreatment steps. The excellent biosensing performance facilitates the development of a high-throughput detection system for serum small extracellular vesicles (sEVs), aiding in the diagnosis and follow-up of prostate cancer. The sEVs meta-biosensing demonstrates a diagnostic sensitivity of 100% for significantly distinguishing early cancer, breaking through the conventional testing limitation. Moreover, it doubles the prediction accuracy of cancer recurrence risk following surgery. Our research highlights the potential for large-scale development of powerful meta-biosensors based on non-noble materials, opening up significant opportunities in cancer diagnosis and prognosis.

Glioblastoma Cell Derived Exosomes as a Potent Vaccine Platform Targeting Primary Brain Cancers and Brain Metastases

Glioblastoma multiforme (GBM) is the most prevalent brain tumor that remains incurable up to now. The rapid advancement of immunotherapy makes vaccines a promising therapeutic approach for GBM. However, current vaccine platforms, such as peptides, dendritic cells, mRNA, and viral vectors, are subject to limitations such as inadequate antigen loading, insufficient immune system activation, ineffective vector delivery, complicated fabrication process, and complex formulation. Here, we developed a GBM tumor cell derived homologous exosomal nanovaccine that does not need to carry any additional tumor antigens and leads to the activation of antigen-presenting cells (APCs) in lymph nodes, increasing the proportion of immune cells (matured dendritic cells, cytotoxic T cells, and memory T cells) and in turn promoting the expression of cytokines (TNF-α, IL-6, and IFN-γ), which effectively stimulates innate immunity to trigger durable protective immunity against tumor cell insult. Our nanovaccine platform possesses efficient dual-targeting capability to lymph nodes and the brain. More importantly, the developed exosomal nanovaccines protected 100% of treated mice by inducing sustained and strong immunity against GL261-luc GBM tumor cells, resulting in 100% mouse survival (8/8) up to 5 months. Our nanovaccines also induced antitumor immune responses in the immunosuppressed CT2A-luc GBM mouse model with greatly improved survival compared to control mice. Exosomal nanovaccines also demonstrated effectiveness in preventing brain metastasis in the B16F10-luc melanoma malignant brain metastasis mouse model, and the mice showed notably improved survival rates. Our simple and potent exosomes offer a versatile platform for clinical translation as individualized vaccine therapy.

Exosomes in melanoma: Future potential for clinical theranostics

Melanoma, an aggressive form of skin cancer, presents significant therapeutic challenges due to its resistance to conventional treatments and propensity for metastasis. Exosomes, nanoscale vesicles secreted by a wide variety of cells, have emerged as promising tools for developing novel melanoma therapies. Exosome-based therapeutic approaches offer several advantages, including inherent biocompatibility, low immunogenicity, and the ability to cross biological barriers. This review explores the therapeutic potential of exosomes in melanoma treatment, focusing on their multifaceted roles in modulating tumor cell behavior, enhancing anti-tumor immune responses, and serving as targeted drug delivery vehicles. We discuss various strategies employed to engineer exosomes for enhanced therapeutic efficacy, including loading them with chemotherapeutic agents, small interfering RNAs (siRNAs), microRNAs (miRNAs), and immunomodulatory molecules. Additionally, we highlight the potential of exosomes derived from diverse sources to enhance anti-cancer effects. Furthermore, we address the challenges and future directions in translating exosome-based therapies from bench to bedside, emphasizing the need for standardized isolation and manufacturing protocols, as well as rigorous preclinical and clinical evaluations to unlock the full therapeutic potential of exosomes in the fight against melanoma.

Leveraging engineered yeast small extracellular vesicles serve as multifunctional platforms for effectively loading methyl salicylate through the "esterase-responsive active loading" strategy

Small extracellular vesicles (sEVs) are a promising vehicle for drug delivery because of their good biocompatibility and nontoxicity. The drug loading and encapsulation efficiencies of them are not satisfactory. This is especially the case when drugs are loaded by co-incubation. In this situation, as the difference in drug concentration between the inside and outside of the membrane of ordinary sEVs decreases, the drugs cannot diffuse efficiently into the inside of the vesicles. As a result, the drug loading efficiency is low. In this study, engineered yeast-derived small extracellular vesicles derived from Pichia pastoris X33 (XPP-sEVs) engineered with carboxylesterase 1 (CES1) were constructed using the "esterase-responsive active loading" method, which is based on the concept of prodrug design and guided by the strategy of immobilized enzymes, to improve the loading efficiency of methyl salicylate (MS) to about twice as much. This was achieved by engineering the CES1-contained small extracellular vesicles to catalyze the esterase hydrolysis reaction of MS to establish a continuous MS transmembrane concentration gradient for efficient loading of the active drugs, including methyl salicylate and its hydrolyzed active product salicylic acid. The results showed that the enzyme activity of the CES1-sEVs group finally reached 7.88 ± 0.43 U/mL, and the drug loading efficiency was about doubled. The results of drug release from the engineered extracellular vesicles showed that the release of the drug reached equilibrium around 100 min-2 h, during which there was no sudden release of the MS, and the final amount of the drug released could be increased by 12.34 % compared with the emulsion dosage form of the MS. Overall, the CES1-sEVs prepared in this study significantly improved the drug-loading efficiency of MS without affecting the anti-inflammatory activity of MS. The MS-CES1-sEVs prepared in this study are non-toxic and have a bright application prospect in the treatment of skin inflammation.

Unraveling exosome-mediated cancer therapy resistance: pathways and therapeutic challenges

Extracellular vesicles (EVs) have emerged as key cell-to-cell communication mediators and play significant roles in both physiological and pathological processes. In EVs, exosomes represent a distinct subpopulation of EVs that have been found to be involved in cancer initiation and therapeutic resistance. Exosomes transfer a diverse spectrum of molecular cargos that have significant effects on the tumor microenvironment (TME), thereby enabling cancer initiation, metastasis, and therapeutic resistance. Exosomes have recently been of interest in cancer therapy due to their role as important mediators of treatment resistance. The exosomal molecular content-proteins, miRNAs, and lncRNAs-allows exosomes to perform functions including drug efflux and detoxification, cell death pathway modulation, induction of epithelial-to-mesenchymal transition (EMT), and suppression of the immune system. In addition to facilitating immune and stromal cell interactions, exosomes cause extracellular matrix remodeling and induce tumor heterogeneity, making it more difficult to respond to therapy. This review covers intricate roles of exosomes in cancer therapy resistance with regard to their biogenesis, molecular content, and functional impact in the TME. Along with this, we also discuss new therapeutic strategies to overcome exosome-mediated resistance including utilizing exosome inhibitors, designed exosome therapy, and combination with conventional therapies. While exosomes hold promise in prediction and diagnosis through their biomarker function, their heterogeneous origins and cryptic functions make it difficult to target interventions. This review emphasizes that research on exosome-mediated pathways is urgently required to develop new therapeutic strategies that can improve cancer treatment outcomes.

The latest applications of exosome-mediated drug delivery in anticancer therapies

In recent years, the significant role of anticancer drugs in cancer treatment has garnered considerable attention. However, the application of these drugs is largely limited by their short half-life in blood circulation, low cellular uptake efficiency, and off-target effects. Exosomes, which serve as crucial messengers in intercellular communication, exhibit unique advantages in molecular delivery compared to traditional synthetic carriers, thereby offering new possibilities for modern drug delivery systems. Exosomes possess organotropic functions and are naturally produced by cells, making them promising candidates for natural drug delivery systems with organotropic properties and minimal side effects. These naturally derived carriers can achieve stable, efficient, and selective delivery of anticancer drugs, thereby enhancing the efficacy and potential of anticancer agents in cancer immunotherapy. This review provides a concise overview of the unique characteristics of exosomes related to anticancer drug delivery, strategies for utilizing exosomes as carriers in cancer therapy, and the latest advancements in the field.

Emerging roles of exosomal circRNAs in non-small cell lung cancer

Despite the prevalence of non-small cell lung cancer (NSCLC) is high, the limited early detection and management of these tumors are restricted since there is an absence of reliable and precise diagnostic biomarkers and therapeutic targets. Exosomes transport functional molecules for facilitating intercellular communication, especially in the tumor microenvironment, indicating their potential as cancer biomarkers and therapeutic targets. Circular RNA (circRNA), a type of non-coding RNA possessing a covalently closed loop structure, substantial abundance, and tissue-specific expression patterns, is stably enriched in exosomes. In recent years, significant breakthroughs have been made in research on exosomal circRNA in NSCLC. This review briefly introduces the biogenesis, characterizations, and functions of circRNAs and exosomes, and systematically describes the biological functions and mechanisms of exosomal circRNAs in NSCLC. In addition, this study summarizes their role in the progression of NSCLC and discusses their clinical significance as biomarkers and therapeutic targets for NSCLC.

Macrophage-derived exosomes in cancer: a double-edged sword with therapeutic potential

Solid cancer contains a complicated communication network between cancer cells and components in the tumor microenvironment (TME), significantly influencing the progression of cancer. Exosomes function as key carriers of signaling molecules in these communications, including the intricate signalings of tumor-associated macrophages (TAMs) on cancer cells and the TME. With their natural lipid bilayer structures and biological activity that relates to their original cell, exosomes have emerged as efficient carriers in studies on cancer therapy. Intrigued by the heterogeneity and plasticity of both macrophages and exosomes, we regard macrophage-derived exosomes in cancer as a double-edged sword. For instance, TAM-derived exosomes, educated by the TME, can promote resistance to cancer therapies, while macrophage-derived exosomes generated in vitro have shown favorable potential in cancer therapy. Here, we depict the reasons for the heterogeneity of TAM-derived exosomes, as well as the manifold roles of TAM-derived exosomes in cancer progression, metastasis, and resistance to cancer therapy. In particular, we emphasize the recent advancements of modified macrophage-derived exosomes in diverse cancer therapies, arguing that these modified exosomes are endowed with unique advantages by their macrophage origin. We outline the challenges in translating these scientific discoveries into clinical cancer therapy, aiming to provide patients with safe and effective treatments.

Innovative nanoparticle strategies for treating oral cancers

Conventional therapies for oral squamous cell carcinoma (OSCC), a serious worldwide health problem, are frequently constrained by inadequate targeting and serious side effects. Drug delivery systems (DDS) based on nanoparticles provide a possible substitute by improving drug stability, target accuracy, and lowering toxicity. By addressing issues like irregular vasculature and thick tumor matrices, these methods allow for more effective medication administration. For instance, the delivery of cisplatin via liposomes, as opposed to free drug formulations, results in a 40% improvement in tumor suppression. Likewise, compared to traditional techniques, poly (lactic-co-glycolic acid) (PLGA) nanoparticles can produce up to 2.3 times more intertumoral drug accumulation. These platforms have effectively administered natural substances like curcumin and chemotherapeutics like paclitaxel, enhancing therapeutic results while reducing adverse effects. Despite their promise, several types of nanoparticles have drawbacks. For example, PLGA nanoparticles have scaling issues because of their complicated production, whereas liposomes are quickly removed from circulation. In preclinical investigations, functionalized nanoparticles-like EGFR-targeted gold nanoparticles-improve selectivity and effectiveness by obtaining up to 90% receptor binding. By preferentially accumulating in tumors via the increased permeability and retention (EPR) effect, nanoparticles also improve immunotherapy and radiation. Mechanistically, they increase the death of cancer cells by causing DNA damage, interfering with cell division, and producing reactive oxygen species (ROS). There are still issues with toxicity (such as the buildup of metallic nanoparticles in the liver) and large-scale manufacturing. Nevertheless, developments in multifunctional platforms and stimuli-responsive nanoparticles show promise for getting over these obstacles. These developments open the door to more individualized and successful OSCC therapies.

Injectable extracellular vesicle hydrogels with tunable viscoelasticity for depot vaccine

Extracellular vesicles (EVs) have been actively explored for therapeutic applications in the context of cancer and other diseases. However, the poor tissue retention of EVs has limited the development of EV-based therapies. Here we report a facile approach to fabricating injectable EV hydrogels with tunable viscoelasticity and gelation temperature, by metabolically tagging EVs with azido groups and further crosslinking them with dibenzocyclooctyne-bearing polyethylene glycol via efficient click chemistry. One such EV gel has a gelation temperature of 39.4 °C, enabling in situ gelation of solution-form EVs upon injection into the body. The in situ formed gels are stable for over 4 weeks and can attract immune cells including dendritic cells over time in vivo. We further show that tumor EV hydrogels, upon subcutaneous injection, can serve as a long-term depot for EV-encased tumor antigens, providing an extended time for the modulation of dendritic cells and subsequent priming of tumor-specific CD8+ T cells. The tumor EV hydrogel also shows synergy with anti-PD-1 checkpoint blockade for tumor treatment, and is able to reprogram the tumor microenvironment. As a proof-of-concept, we also demonstrate that EV hydrogels can induce enhanced antibody responses than solution-form EVs over an extended time. Our study yields a facile and universal approach to fabricating injectable EV hydrogels with tunable mechanics and improving the therapeutic efficacy of EV-based therapies.

Cutting-Edge Progress in the Acquisition, Modification and Therapeutic Applications of Exosomes for Drug Delivery

Exosomes are vesicles secreted by cells, typically ranging from 30 to 150 nm in diameter, and serve as crucial mediators of intercellular communication. Exosomes are capable of loading various therapeutic substances, such as small molecule compounds, proteins, and oligonucleotides, thereby making them an ideal vehicle for drug delivery. The distinctive biocompatibility, high stability, and targeting properties of exosomes render them highly valuable for future treatments of diseases like cancer and cardiovascular diseases. Despite the potential advantage of exosomes in delivering biologically active molecules, the techniques for the preparation, purification, preservation, and other aspects of stem cell exosomes are not yet mature enough. In this paper, we briefly introduce the composition, biogenesis, and benefits of exosomes, and primarily focus on summarizing the isolation and purification methods of exosomes, the preparation of engineered exosomes, and their clinical applications, to better provide new ideas for the development of exosome drug delivery systems.

Exosome-based nanomedicines for digestive system tumors therapy

Digestive system tumors constitute a major subset of malignancies, consistently ranking among the leading causes of mortality globally. Despite limitations inherent in current therapeutic modalities, recent advancements in targeted therapy and drug delivery systems have led to significant improvements in the efficacy of pharmacotherapy for digestive system tumors. In this context, exosomes - naturally occurring nanoscale vesicles - have emerged as promising drug delivery candidates due to their intrinsic molecular transport capabilities, superior biocompatibility, and targeted recognition of tumor cells. The integration of exosomes into cancer therapeutics represents a novel and potentially transformative approach for treating digestive system tumors, which may drive further progress in this field. This review comprehensively examines the sources, loading mechanisms, and therapeutic efficacy of exosomes in the context of digestive system tumor treatment. Furthermore, it discusses the opportunities and challenges associated with exosomes, offering insights into their future role within the therapeutic armamentarium against digestive tumors.

Extracellular vesicles: messengers of cross-talk between gastric cancer cells and the tumor microenvironment

Gastric cancer is a common malignancy characterized by an insidious onset and high mortality rate. Exosomes, a special type of extracellular vesicle, contain various bioactive molecules and have been found to play crucial roles in maintaining normal physiological functions and homeostasis in the body. Recent research has shown that the contents of exosome play a significant role in the progression and metastasis of gastric cancer through communication and regulatory functions. These mechanisms involve promoting gastric cancer cell proliferation and drug resistance. Additionally, other cells in the gastric cancer microenvironment can regulate the progression of gastric cancer through exosomes. These include exosomes derived from fibroblasts and immune cells, which modulate gastric cancer cells. Therefore, in this review, we provide a brief overview of recent advances in the contents and occurrence mechanisms of exosome. This review specifically focused on the regulatory mechanisms of exosomes derived from gastric cancer and other cellular subtypes in the tumor microenvironment. Subsequently, we summarize the latest research progress on the use of exosomes in liquid biopsy, discussing the potential of gastric cancer exosomes in clinical applications.

A combined "eat me/don't eat me" strategy based on exosome for acute liver injury treatment

Drug-induced liver injury (DILI) involves multifaceted pathogenesis, necessitating effective therapeutic strategies. Wnt2, secreted by liver sinusoidal endothelial cell (LSEC), activates the Wnt/β-catenin signaling pathway to promote hepatocyte proliferation after injury. To address the dual challenges of targeted delivery and phagocytosis evasion, we develop a combined "eat me/don't eat me" strategy. RLTRKRGLK (RLTR) peptide-functionalized exosomes are engineered by inserting DMPE-PEG2000-CRLTRKRGLK into the lipid membrane of exosome derived from bEnd.3 cell. Surface-displayed RLTR mediates exosomal enrichment in LSEC, while CD47 engineering reduces macrophage clearance via "don't eat me" signaling. Then, lentiviral transfection enables stable encapsulation of functional Wnt2 mRNA into ExoCD47 (designated Wnt2@ExoCD47). In both acetaminophen (APAP) and dimethylnitrosamine (DMN)-induced murine liver injury models, RLTR-Wnt2@ExoCD47 demonstrates LSEC-specific targeting and significant hepatoprotection. This engineered exosome platform provides a therapeutic strategy for DILI.

Crosstalk between exosomes and tumor-associated macrophages in hepatocellular carcinoma: implication for cancer progression and therapy

Hepatocellular carcinoma (HCC), the most prevalent type of primary liver cancer, represents a significant cause of cancer-related mortality. While our understanding of its pathogenesis is comparatively comprehensive, the influence of the tumor microenvironment (TME) on its progression warrants additional investigation. Tumor-associated macrophages (TAMs) have significant impacts on cancer cell proliferation, migration, invasion, and immune response, facilitating a complex interaction within the TME. Exosomes, which measure between 30 and 150 nanometers in size, are categorized into small extracellular vesicles, secreted by a wide range of eukaryotic cells. They can transfer biological molecules including proteins, non-coding RNAs, and lipids, which mediates the intercellular communication within the TME. Emerging evidence has revealed that exosomes regulate macrophage polarization, thus impacting cancer progression and immune responses within the TME of HCC. Moreover, TAM-derived exosomes also play crucial roles in malignant transformation, which hold immense potential for cancer therapy. In this review, we elaborate on the crosstalk between exosomes and TAMs within TME during HCC development. Moreover, we delve into the feasible treatment approaches for exosomes in cancer therapy and emphasize the limitations and challenges for the translation of exosomes derived from TAMs into clinical courses for cancer therapy, which may provide new perspectives on further ameliorations of therapeutic regimes based on exosomes to advance their clinical applications.

Unlocking exosome therapeutics: The critical role of pharmacokinetics in clinical applications

Exosomes are microscopic vesicles released by cells that transport various biological materials and play a vital role in intercellular communication. When they are engineered, they serve as efficient delivery systems for therapeutic agents, making it possible to precisely deliver active pharmaceutical ingredients to organs, tissues, and cells. Exosomes' pharmacokinetics, or how they are transported and metabolized inside the body, is affected by several factors, including their source of origination and the proteins in their cell membranes. The pharmacokinetics and mobility of both native and modified exosomes are being observed in living organisms using advanced imaging modalities such as in vitro-in vivo simulation, magnetic resonance imaging, and positron emission tomography. Establishing comprehensive criteria for the investigation of exosomal pharmacokinetic is essential, given its increasing significance in both therapy and diagnostics. To obtain a thorough understanding of exosome intake, distribution, metabolism, and excretion, molecular imaging methods are crucial. The development of industrial processes and therapeutic applications depends on the precise measurement of exosome concentration in biological samples. To ensure a seamless incorporation of exosomes into clinical practice, as their role in therapeutics grows, it is imperative to conduct a complete assessment of their pharmacokinetics. This review provides a brief on how exosome-based research is evolving and the need for pharmacokinetic consideration to realize the full potential of these promising new therapeutic approaches.

Exosome-decorated bio-heterojunctions reduce heat and ROS transfer distance for boosted antibacterial and tumor therapy

Photothermal and photodynamic therapies represent effective modalities for combatting bacteria and tumor cells. However, therapeutic outcomes are constrained by limitations related to the heat and reactive oxygen species (ROS) transfer distance from photosensitizers to targets. To address this issue, we have devised and developed exosome-decorated bio-heterojunctions (E-bioHJ) consisted of MXene (Ti3C2), liquid metal (LM) and exosomes sourced from CT26 cells to enhance the phototherapeutic consequences. Engineering E-bioHJ enhances phototherapeutic effect in antibacterial and anti-tumor treatment, which is ascribed to reducing transfer distance of the heat and ROS. When adorned with exosomes, E-bioHJ is targetedly delivered into the cytoplasm of tumor cells to generate amount heat and ROS under 808 nm near-infrared radiation, which further induces mitochondrial dysfunction and apoptosis/necroptosis. As envisaged, this study presents a novel tactic to enhance the antibacterial and anti-tumor efficacy of biomaterials through reducing the heat and ROS delivery travel distance.

Sustained release of miR-21 carried by mesenchymal stem cell-derived exosomes from GelMA microspheres inhibits ovarian granulosa cell apoptosis in premature ovarian insufficiency

Background

Premature ovarian insufficiency (POI) refers to the severe decline or failure of ovarian function in women younger than 40 years of age. It is a serious hazard to women's physical and mental health, but current treatment options are limited. Mesenchymal stem cell-derived exosomes (MSC-Exo) exhibit promising potential as a therapeutic approach for POI. However, their clinical application is hindered by their instability and low long-term retention rate in vivo.

Methods and results

In this study, miR-21 was identified as the predominant miRNA with low-expression in follicular fluid exosomes of POI patients and was shown to possess antiapoptotic activity. Next, we loaded miR-21 agomir to MSC-Exo to form Agomir21-Exo, which significantly reversed the apoptosis of granulosa cells in vitro. Moreover, we successfully developed GelMA hydrogel microspheres for encapsulating Agomir21-Exo through microfluidic technology, named GelMA-Ag21Exo, which had good injectability and significantly enhanced the stability and long-term retention of Agomir21-Exo in mice through sustained release. The release of Agomir21-Exo from GelMA-Ag21Exo notably alleviated the apoptosis of ovarian granulosa cells and improved the ovarian reserve and fertility in POI mice.

Conclusion

Our findings illustrate that activating miR-21 through Agomir21-Exo could improve the function of ovarian granulosa cells. The GelMA-Ag21Exo enhanced the exosome-based therapeutic efficacy of the Agomir21-Exo in vivo. These findings provide a novel and promising treatment strategy for POI patients.

Chitosan and hyaluronic acid in breast cancer treatment: Anticancer efficacy and nanoparticle and hydrogel development

The pervasive global health concern of breast cancer necessitates the development of innovative therapeutic interventions to enhance efficacy and mitigate adverse effects. Chitosan and hyaluronic acid, recognized for their biocompatibility and biodegradability, present compelling options for the novel drug delivery systems and therapeutic platforms in the context of breast cancer management. This review will delineate the distinctive attributes of chitosan and hyaluronic acid, encompassing their inherent anticancer properties, targeting capabilities, and suitability for chemical modifications along with nanoparticle development. These characteristics render them exceptionally well-suited for the fabrication of nanoparticles and hydrogels. The intrinsic anticancer potential of chitosan, in conjunction with its mucoadhesive properties, and the robust binding affinity of hyaluronic acid to CD44 receptors, facilitate specific drug delivery to the malignant cells, thus circumventing the limitations inherent in traditional treatment modalities such as chemotherapy. The incorporation of these materials into nanocarriers allows for the co-delivery of therapeutic agents, thereby potentiating synergistic effects, while hydrogel systems provide localized, controlled drug release and facilitate tissue regeneration. An analysis of advancements in their synthesis, functionalization, and application is presented, while also acknowledging challenges pertaining to scalability and clinical translation.

Exosome isolation and characterization for advanced diagnostic and therapeutic applications

Advancements in exosome isolation technologies are pivotal for transforming personalized medicine and enhancing clinical diagnostics. Exosomes, small extracellular vesicles with diameters ranging between 30 and 150 nm, are secreted into bodily fluids by a variety of cells and play essential roles in intercellular communication. These vesicles facilitate the transfer of nucleic acids, lipids, and proteins, affecting a wide range of biological and pathological processes. Given their importance in disease diagnostics, therapy, and as biomarkers, there has been a surge in developing methods to isolate them from fluids such as urine, saliva, blood, and cerebrospinal fluid. While traditional isolation techniques like ultracentrifugation and polymer-based precipitation have been foundational, recent technological advances have introduced more precise methods like microfluidics and immunoaffinity capture. These newer methods enable high-throughput and specific exosome isolation by targeting surface markers, thus enhancing purity. However, challenges such as balancing purity with yield and the lack of standardized protocols across different laboratories persist, impacting the consistency of findings. By integrating advanced isolation techniques and discussing their implications in diagnostics and therapy, this review aims to catalyze further research and adoption of exosome-based technologies in medicine, marking a significant stride towards tailored healthcare solutions.

Engineering Exosomes for CNS Disorders: Advances, Challenges, and Therapeutic Potential

The development of targeted drugs for diseases of the central nervous system (CNS) is a significant challenge due to the structural complexity and functional specificities of these systems. Recently, exosomes have emerged as a promising therapeutic platform, given their unique capacity to traverse the blood-brain barrier and deliver bioactive molecules to target cells. This review examines recent advances in exosome research with a particular focus on CNS diseases, emphasizing their role as carriers of therapeutic cargo, including proteins, RNAs, and lipids. Nevertheless, significant challenges remain before exosome-based therapies can be translated from preclinical research to clinical applications. These include the need for scalable production and standardized isolation methods. Despite these hurdles, ongoing studies continue to shed light on the mechanisms of exosome-mediated neuroprotection and neurodegeneration. This paves the way for innovative therapeutic strategies to address CNS disorders.

Extracellular vesicles: a new frontier in diagnosing and treating graft-versus-host disease after allogeneic hematopoietic cell transplantation

Graft-versus-host disease (GvHD) is a prevalent complication following allogeneic hematopoietic stem cell transplantation (HSCT) and is characterized by relatively high morbidity and mortality rates. GvHD can result in extensive systemic damage in patients following allogeneic HSCT (allo-HSCT), with the skin, gastrointestinal tract, and liver frequently being the primary target organs affected. The severe manifestations of acute intestinal GvHD often indicate a poor prognosis for patients after allo-HSCT. Endoscopy and histopathological evaluation remain employed to diagnose GvHD, and auxiliary examinations exclude differential diagnoses. Currently, reliable serum biomarkers for the diagnosis and differential diagnosis of GvHD are scarce. As an essential part of standard transplant protocols, early application of immunosuppressive drugs effectively prevents GvHD. Among them, steroids represent first-line therapeutic agents, and the JAK2 inhibitor ruxolitinib represents the second-line therapeutic agent. Currently, no efficacious treatment modality exists for steroid-resistant aGvHD. Therefore, the diagnosis and treatment of GvHD still face significant medical demands. Extracellular vesicles (EVs) are nanometer to micrometer-scale biomembrane vesicles containing various bioactive components, such as proteins, nucleotides, and metabolites. Distinctive changes in serum-derived EV components occur in patients after allo-HSCT; Hence, EVs are expected to be potential biomarkers for diagnosing and treating GvHD. Furthermore, cell-free therapeutics characterized by EVs derived from mesenchymal stem cells (MSCs) have manifested remarkable therapeutic efficacy in preclinical models and preclinical trials of GvHD. Customized engineered EVs with fewer toxic and side effects for the combined treatment of GvHD hold broad prospects for clinical translation. This review article examines the potential value of translating EVs into clinical applications for the diagnosis and treatment of GvHD. It summarizes the latest advancements and prospects of engineered EVs applying GvHD.

MiR-21-5p-enriched exosomes from hiPSC-derived cardiomyocytes exhibit superior cardiac repair efficacy compared to hiPSC-derived exosomes in a murine MI model

BACKGROUND

Heart disease remains a leading cause of mortality worldwide, with existing treatments often failing to effectively restore damaged myocardium. Human-induced pluripotent stem cells (hiPSCs) and their derivatives offer promising therapeutic options; however, challenges such as low retention, engraftment issues, and tumorigenic risks hinder their clinical utility. Recent focus has shifted to exosomes (exos) - nanoscale vesicles that facilitate intercellular communication - as a safer and more versatile alternative. Understanding the specific mechanisms and comparative efficacy of exos from hiPSCs vs hiPSC-derived cardiomyocytes (hiPSC-CMs) is crucial for advancing cardiac repair therapies.

AIM

To evaluate and compare the therapeutic efficacy of exos secreted by hiPSCs and hiPSC-CMs in cardiac repair, and to elucidate the role of microRNA 21-5p (miR-21-5p) in the observed effects.

METHODS

We differentiated hiPSCs into CMs using small molecule methods and characterized the cells and their exos.

RESULTS

Our findings indicate that hiPSC-CMs and their exos enhanced cardiac function, reduced infarct size, and decreased myocardial fibrosis in a murine myocardial infarction model. Notably, hiPSC-CM exos outperformed hiPSC-CM cell therapy, showing improved ejection fraction and reduced apoptosis. We identified miR-21-5p, a microRNA in hiPSC-CM exos, as crucial for CM survival. Exos with miR-21-5p were absorbed by AC16 cells, suggesting a mechanism for their cytoprotective effects.

CONCLUSION

Overall, hiPSC-CM exos could serve as a potent therapeutic agent for myocardial repair, laying the groundwork for future research into exos as a treatment for ischemic heart disease.

Extracellular vesicles in cancer´s communication: messages we can read and how to answer

Extracellular vesicles (EVs) are emerging as critical mediators of intercellular communication in the tumor microenvironment (TME), profoundly influencing cancer progression. These nano-sized vesicles, released by both tumor and stromal cells, carry a diverse cargo of proteins, nucleic acids, and lipids, reflecting the dynamic cellular landscape and mediating intricate interactions between cells. This review provides a comprehensive overview of the biogenesis, composition, and functional roles of EVs in cancer, highlighting their significance in both basic research and clinical applications. We discuss how cancer cells manipulate EV biogenesis pathways to produce vesicles enriched with pro-tumorigenic molecules, explore the specific contributions of EVs to key hallmarks of cancer, such as angiogenesis, metastasis, and immune evasion, emphasizing their role in shaping TME and driving therapeutic resistance. Concurrently, we submit recent knowledge on how the cargo of EVs can serve as a valuable source of biomarkers for minimally invasive liquid biopsies, and its therapeutic potential, particularly as targeted drug delivery vehicles and immunomodulatory agents, showcasing their promise for enhancing the efficacy and safety of cancer treatments. By deciphering the intricate messages carried by EVs, we can gain a deeper understanding of cancer biology and develop more effective strategies for early detection, targeted therapy, and immunotherapy, paving the way for a new era of personalized and precise cancer medicine with the potential to significantly improve patient outcomes.

Exosomes derived from natural killer cells: transforming immunotherapy for aggressive breast cancer

Natural killer cell-derived exosomes (NK-Exos) hold great promise as immune modulators and immunotherapeutics against cancer due to their intrinsically latent anti-tumor effects. They use these nanosized vesicles to deliver cytotoxic molecules, such as perforin, granzymes, and miRNAs, directly to cancer cells to kill them, avoiding immune suppression. NK-Exos has particular efficacy for treating aggressive breast cancer by modulating the TME to activate the immune response and suppress immunosuppressive factors. Bioengineering advances have extended the therapeutic potential of NK-Exos, which permits precise tumor cell targeting and efficient delivery of therapeutic payloads, including small RNAs and chemotherapeutic agents. In engineered NK-Exos, sensitization of cancer cells to apoptosis, reduction of tumor growth, and resistance to drugs have been demonstrated to be highly effective. When combined, NK-Exos synergizes with radiotherapy, chemotherapy, or checkpoint inhibitors, enhancing therapeutic efficacy, and minimizing systemic toxicity. This review emphasizes the critical role of NK-Exos in breast cancer treatment, their integration into combination therapies, and the need for further research to overcome existing limitations and fully realize their clinical potential.

Clinical Impact of Exosome Chemistry in Cancer

As we progress into the 21st century, cancer stands as one of the most dreaded diseases. With approximately one in every four individuals facing a lifetime risk of developing cancer, cancer remains one of the most serious health challenges worldwide. Its multifaceted nature makes it an arduous and tricky problem to diagnose and treat. Over the years, researchers have explored plenty of approaches and avenues to improve cancer management. One notable strategy includes the study of extracellular vesicles (EVs) as potential biomarkers and therapeutics. Among these EVs, exosomes have emerged as particularly promising candidates due to their unique characteristic properties and functions. They are small membrane-bound vesicles secreted by cells carrying a cargo of biomolecules such as proteins, nucleic acids, and lipids. These vesicles play crucial roles in intercellular communication, facilitating the transfer of biological information between cell-to-cell communication. Exosomes transport cargoes such as DNA, RNA, proteins, and lipids involved in cellular reprogramming and promoting cancer. In this review, we explore the molecular composition of exosomes, significance of exosomes chemistry in cancer development, and its theranostic application as well as exosomes research complications and solutions.

A bibliometric and visualized analysis of extracellular vesicles in degenerative musculoskeletal diseases (from 2006 to 2024)

Background

With the rapid development of extracellular vesicles (EVs) in regenerative medicine research, they have become a promising new direction in the mechanistic, diagnosis and treatment studies of degenerative musculoskeletal diseases (DMDs), and has attracted increasing attention. However, there is currently a lack of comprehensive and objective summary analysis to help researchers quickly and conveniently understand the development trajectory and future trends of this field.

Method

This study collected articles and reviews published from 2006 to 2024 on EVs in DMDs from the Web of Science database. Bibliometric and visual analysis was conducted using several tools, including Microsoft Excel Office, VOSviewer, CiteSpace, Pajek, and R packages.

Results

1,182 publications were included in the analysis from 2006 to 2024. Notably, there was a rapid increase in the number of publications starting in 2016, suggesting that this field remains in a developmental stage. Co-authorship analysis revealed that China ranked first in terms of publications, whereas the United States led in citations. The journal with the highest number of publications was International Journal of Molecular Sciences (INT J MOL SCI). The most prolific authors were Ragni, E with 23 publications, while the most cited author was Toh, WS. Additionally, nine of the top 10 institutions were from China, with Shanghai Jiao Tong University leading in the number of publications. The most cited article was "MSC exosomes mediate cartilage repair by enhancing proliferation, attenuating apoptosis and modulating immune reactivity", authored by Zhang, S, and published in BIOMATERIALS in 2018.

Conclusion

This study, through bibliometric and visual analysis, clearly illustrates the collaborative relationships among countries, authors, institutions, and journals, providing valuable insights for researchers seeking academic collaboration opportunities. Moreover, the analysis of keywords and citations allows researchers to better understand key research hotspots and frontiers in this field, and points toward promising directions for future research. The growing interest in EV research in DMDs over recent years indicates increasing attention and a dynamic progression in this field.

Exosomes in Precision Oncology and Beyond: From Bench to Bedside in Diagnostics and Therapeutics

Exosomes have emerged as pivotal players in precision oncology, offering innovative solutions to longstanding challenges such as metastasis, therapeutic resistance, and immune evasion. These nanoscale extracellular vesicles facilitate intercellular communication by transferring bioactive molecules that mirror the biological state of their parent cells, positioning them as transformative tools for cancer diagnostics and therapeutics. Recent advancements in exosome engineering, artificial intelligence (AI)-driven analytics, and isolation technologies are breaking barriers in scalability, reproducibility, and clinical application. Bioengineered exosomes are being leveraged for CRISPR-Cas9 delivery, while AI models are enhancing biomarker discovery and liquid biopsy accuracy. Despite these advancements, key obstacles such as heterogeneity in exosome populations and the lack of standardized isolation protocols persist. This review synthesizes pioneering research on exosome biology, molecular engineering, and clinical translation, emphasizing their dual roles as both mediators of tumor progression and tools for intervention. It also explores emerging areas, including microbiome-exosome interactions and the integration of machine learning in exosome-based precision medicine. By bridging innovation with translational strategies, this work charts a forward-looking path for integrating exosomes into next-generation cancer care, setting it apart as a comprehensive guide to overcoming clinical and technological hurdles in this rapidly evolving field.

Hybrid lipid nanoparticles with tumor antigen-primed dendritic cell membranes for post-surgical tumor immunotherapy

Post-surgical tumor recurrence poses a major challenge in cancer treatment due to residual tumor cells and surgery-induced immunosuppression. Here, we developed hybrid nanoparticles, termed T-DCNPs, designed to promote antigen-specific activation of cytotoxic CD8+ T cells while concurrently inhibiting immunosuppressive pathways within the tumor microenvironment. T-DCNPs were formulated by co-extruding lipid nanoparticles containing a transforming growth factor β inhibitor with dendritic cells that were pre-treated with autologous neoantigens derived from surgically excised tumors. By using whole tumor antigens rather than specific peptides, T-DCNPs effectively overcame tumor heterogeneity and elicited a robust, targeted immune response. In vitro studies showed that T-DCNPs enhanced CD8+ T cell proliferation and reduced programmed death-1 (PD-1) expression, leading to increased antitumor cytotoxicity. In vivo experiments, involving intratumoral injections of T-DCNPs in distant tumor and post-surgical melanoma models, demonstrated a significant reduction in distant tumor growth, decreased recurrence rates, and extended survival compared to control groups. Flow cytometry and immunohistochemistry analyses further confirmed the enhanced infiltration of activated CD8+ T cells and a marked reduction in immunosuppressive markers, including PD-1 and Foxp3, within the treated tumors. These results suggest that T-DCNPs, through the dual mechanisms of tumor antigen-specific T cell activation and immune modulation, offer a promising strategy to prevent tumor recurrence following surgery and could potentially improve the efficacy of postoperative cancer immunotherapy.

Exosomal dynamics: Bridging the gap between cellular senescence and cancer therapy

Cancer remains one of the most devastating diseases, severely affecting public health and contributing to economic instability. Researchers worldwide are dedicated to developing effective therapeutics to target cancer cells. One promising strategy involves inducing cellular senescence, a complex state in which cells exit the cell cycle. Senescence has profound effects on both physiological and pathological processes, influencing cellular systems through secreted factors that affect surrounding and distant cells. Among these factors are exosomes, small extracellular vesicles that play crucial roles in cellular communication, development, and defense, and can contribute to pathological conditions. Recently, there has been increasing interest in engineering exosomes as precise drug delivery vehicles, capable of targeting specific cells or intracellular components. Studies have emphasized the significant role of exosomes from senescent cells in cancer progression and therapy. Notably, chemotherapeutic agents can alter the tumor microenvironment, induce senescence, and trigger immune responses through exosome-mediated cargo transfer. This review explores the intricate relationship between cellular senescence, exosomes, and cancer, examining how different therapeutics can eliminate cancer cells or promote drug resistance. It also investigates the molecular mechanisms and signaling pathways driving these processes, highlighting current challenges and proposing future perspectives to uncover new therapeutic strategies for cancer treatment.

Research progress on small extracellular vesicles in diabetic nephropathy

Virtually all cell types are capable of secreting small extracellular vesicles (sEV), which can be internalized by recipient cells, thereby serving as vehicles for intercellular communication. The cargoes of these vesicles, such as microRNAs, circular RNAs, proteins, and lipids, play significant roles in both normal cellular functions and the pathogenesis of various diseases. Diabetic Nephropathy (DN), a complication arising from diabetes, is expected to contribute to a 54% increase in the global diabetic population between 2015 and 2030, leading to substantial economic burdens on individuals and healthcare systems. sEVs, as promising biomarkers, demonstrate diverse mechanistic responses in different types of Diabetic Kidney Disease (DKD). They also hold advantages in the early prediction of renal damage. This article reviews the functional mechanisms of sEVs in DKD and their potential as therapeutic targets and biomarkers.

The Common Hallmarks and Interconnected Pathways of Aging, Circadian Rhythms, and Cancer: Implications for Therapeutic Strategies

The intricate relationship between cancer, circadian rhythms, and aging is increasingly recognized as a critical factor in understanding the mechanisms underlying tumorigenesis and cancer progression. Aging is a well-established primary risk factor for cancer, while disruptions in circadian rhythms are intricately associated with the tumorigenesis and progression of various tumors. Moreover, aging itself disrupts circadian rhythms, leading to physiological changes that may accelerate cancer development. Despite these connections, the specific interplay between these processes and their collective impact on cancer remains inadequately explored in the literature. In this review, we systematically explore the physiological mechanisms of circadian rhythms and their influence on cancer development. We discuss how core circadian genes impact tumor risk and prognosis, highlighting the shared hallmarks of cancer and aging such as genomic instability, cellular senescence, and chronic inflammation. Furthermore, we examine the interplay between circadian rhythms and aging, focusing on how this crosstalk contributes to tumorigenesis, tumor proliferation, and apoptosis, as well as the impact on cellular metabolism and genomic stability. By elucidating the common pathways linking aging, circadian rhythms, and cancer, this review provides new insights into the pathophysiology of cancer and identifies potential therapeutic strategies. We propose that targeting the circadian regulation of cancer hallmarks could pave the way for novel treatments, including chronotherapy and antiaging interventions, which may offer important benefits in the clinical management of cancer.

Killing the killers: Natural killer cell therapy targeting glioma stem cells in high-grade glioma

High-grade gliomas (HGGs), including glioblastoma (GBM) in adults and diffuse intrinsic pontine glioma (DIPG) in children, are among the most aggressive and deadly brain tumors. A key factor in their resilience is the presence of glioma stem cells (GSCs), which drive tumor initiation, progression, and resistance to treatment. Targeting and eradicating GSCs holds potential for curing both GBM and DIPG. Natural killer (NK) cells, as part of the innate immune system, naturally recognize and destroy malignant cells. Recent advances in NK cell-based therapies, such as chimeric antigen receptor (CAR)-NK cells, NK cell engagers, and NK cell-derived exosomes, offer promising approaches for treating GBM and DIPG, particularly by addressing the persistence of GSCs. This review highlights these advancements, explores challenges such as the blood-brain barrier and the immunosuppressive tumor microenvironment, and proposes future directions for improving and clinically advancing these NK cell-based therapies for HGGs.

Mesenchymal Stromal Cell Exosome-Induced Vascular Regeneration in a PCOS Mouse Model

The efficacy of Bone Marrow Mesenchymal Stem Cell-derived Exosomes (BMSCs-Exo) in addressing the complexities of Polycystic Ovary Syndrome (PCOS) has been explored in a controlled experimental study using a DHEA-induced PCOS model in 6-8-week-old female NMRI mice. This research undertook an in vivo approach with fifteen female murine subjects to investigate the potential of BMSCs-Exo in promoting vascular regeneration and alleviating the adverse effects associated with PCOS. Through a strategic intervention, the study aimed to modulate the pathophysiological markers of oxidative stress and inflammation that are hallmark features of PCOS. Remarkably, the administration of BMSCs-Exo led to decreased CD31 expression in ovarian tissues, suggesting reduced angiogenesis and endothelial activation. Moreover, a significant reduction in pro-inflammatory cytokines and oxidative stress markers was noted, aligning closely with the metrics observed in the control group. These findings illuminate a promising therapeutic avenue utilizing BMSCs-Exo to recalibrate angiogenic, inflammatory, and oxidative stress responses in PCOS. This research not only contributes to the current understanding of PCOS management but also opens new doors for innovative clinical treatments.

Trojan Horse-Like Biohybrid Nanozyme for Ameliorating Liver Ischemia-Reperfusion Injury

Liver ischemia and reperfusion (I/R) injury is a reactive oxygen species (ROS)-related disease that occurs during liver transplantation and resection and hinders postoperative liver function recovery. Current approaches to alleviate liver I/R injury have limited effectiveness due to the short circulation time, poor solubility, and severe side effects of conventional antioxidants and anti-inflammatory drugs. Herein, a universal strategy is proposed to fabricate a Trojan horse-like biohybrid nanozyme (THBN) with hepatic-targeting capabilities. Tannic acid (TA) mediates adeno-associated virus (AAV8) decoration onto 2D Ti3C2 nanosheets, resulting in THBN with a size of 116.2 ± 9.5 nm. Remarkably, THBN exhibits catalase (CAT)-like activity, broad-spectrum ROS scavenging activity and targeted delivery to liver tissue owing to the presence of AAV8. Both in vivo and in vitro experiments confirmed the efficacy of THBN in attenuating liver I/R injury by mitigating inflammation and oxidative stress and inhibiting hepatocellular apoptosis. RNA-seq analysis suggests that THBN may alleviate liver I/R injury by activating the PKC pathway. The effective targeting and therapeutic capabilities of THBN represent an advancement in nanotherapeutics for hepatic ischemia‒reperfusion injury, shedding light on the promising potential of this next-generation nanotherapeutic approach.

Engineered exosomes in service of tumor immunotherapy: From optimizing tumor-derived exosomes to delivering CRISPR/Cas9 system

Exosomes can be modified and designed for various therapeutic goals because of their unique physical and chemical characteristics. Researchers have identified tumor-derived exosomes (TEXs) as significant players in cancer by influencing tumor growth, immune response evasion, angiogeneis, and drug resistance. TEXs promote the production of specific proteins important for cancer progression. Due to their easy accessibility, TEXs are being modified through genetic, drug delivery, membrane, immune system, and chemical alterations to be repurposed as vehicles for delivering drugs to improve cancer treatment outcomes. In the complex in vivo environment, the clustered regularly interspaced short palindromic repeats and CRISPR-associated protein 9 (CRISPR/Cas9) system encounters challenges from degradation, neutralization, and immune responses, emphasizing the need for strategic distribution strategies for effective genome editing. Engineered exosomes present a promising avenue for delivering CRISPR/Cas9 in vivo. In this review, we will explore different techniques for enhancing TEXs using various engineering strategies. Additionally, we will discuss how these exosomes can be incorporated into advanced genetic engineering systems like CRISPR/Cas9 for possible therapeutic uses.

Molecular anti-tumorigenic mechanism of Radix Polygoni Multiflori-derived exosome-like nanoparticles

The incidence and mortality rate of liver cancer are on the rise worldwide and effective therapeutic strategies are needed. Previous studies demonstrated that exosomes and exosome-like nanoparticles (ELNs) have numerous biological activities including antioxidant, anti-tumor, and anti-inflammatory effects. In this study, ELNs were successfully isolated for the first time from Radix Polygoni Multiflori (RPM) juice by ultracentrifugation. This indicated that RPM-ELNs could be internalized by hepatoma cells effectively and inhibit their proliferation and migration in vitro. RNA sequencing and qPCR experiments were performed, and the results of bioinformatic analyses revealed that RPM-ELNs could globally regulate expression levels of numerous genes associated with cancer and the cell cycle. In addition, it showed that RPM-ELNs mainly target liver tissue of mice in vivo.

Overexpression of NKG2D and IL24 in NK Cell-Derived Exosomes for Cancer Therapy

Natural killer (NK) cell-derived exosomes (NK-Exos) are emerging as a promising avenue in cancer immunotherapy due to their inherent tumor-targeting properties and their capacity to deliver therapeutic agents directly to malignant cells. This research delves into the boosted anti-tumor potency of NK-Exos that has been genetically enhanced to overexpress NKG2D, a vital activating receptor, along with interleukin-24 (IL24), a cytokine renowned for its selective suppressive impact on tumor cells. NKG2D facilitates the recognition of tumor cells by binding to stress-induced ligands, while IL24 induces apoptosis and modulates immune responses to enhance tumor destruction. The NK-Exos engineered to express both NKG2D and IL24 significantly enhanced tumor targeting and increased the apoptosis rate of tumor cells by 30% in A549 and by 20% in HELA at 48 h compared with non-modified NK-Exos, respectively. Furthermore, this enhancement also impacted cell proliferation, with inhibition rates increasing by 30%, 15%, and 15% in A549, HELA, and MCF-7 cells, respectively, and it reduced A549 cell migration by 10%. The integration of NKG2D and IL24 within NK-Exos confers a dual therapeutic mechanism, synergistically amplifying their efficacy in cancer treatment. The utility of NK-Exos co-expressing NKG2D and IL24 offers a novel approach to overcome the limitations of current therapies, providing prolonged tumor suppression and precise targeting of malignant cells and holding great promise for clinical application.

Bio-orthogonal-labeled exosomes reveals specific distribution in vivo and provides potential application in ARDS therapy

Exosomes derived from specific cells may be useful for targeted drug delivery, but tracking them in vivo is essential for their clinical application. However, their small size and complex structure challenge the development of exosome-tracking techniques, and traditional labeling methods are limited by weak affinity and potential toxicity. To address these issues, here we developed a novel bio-orthogonal labeling strategy based on phosphatidylinositol derivatives to fluorescently label exosomes from various human and mouse cell types. The different cell-derived exosomes revealed organ-specific distribution patterns and a favorable safety profile. Notably, 4T1 cell-derived exosomes specifically targeted the lungs. When used as drug carriers loaded with anti-inflammatory resveratrol, these exosomes showed significant therapeutic efficacy in mice with acute respiratory distress syndrome (ARDS), effectively reducing inflammatory responses, mitigating pulmonary fibrosis, and restoring lung tissue morphology and function. Our findings provide a novel exosome labeling strategy and an invaluable tool for their in vivo tracking and targeting screening, while exosomes that specifically target the lungs offer a potential therapeutic strategy for organ-specific diseases such as ARDS.

Natural and Bioengineered Extracellular Vesicles in Diagnosis, Monitoring and Treatment of Cancer

Extracellular vesicles (EVs) are cell derived nanovesicles which are implicated in both physiological and pathological intercellular communication, including the initiation, progression, and metastasis of cancer. The exchange of biomolecules between stromal cells and cancer cells via EVs can provide a window to monitor cancer development in real time for better diagnostic and interventional strategies. In addition, the process of secretion and internalization of EVs by stromal and cancer cells in the tumor microenvironment (TME) can be exploited for delivering therapeutics. EVs have the potential to provide a targeted, biocompatible, and efficient delivery platform for the treatment of cancer and other diseases. Natural as well as engineered EVs as nanomedicine have immense potential for disease intervention. Here, we provide an overview of current knowledge of EVs' function in cancer progression, diagnostic and therapeutic applications for EVs in the cancer setting, as well as current EV engineering strategies.

Research progress of extracellular vesicles in the pathogenesis of type IIIA chronic prostatitis

Chronic prostatitis is a prevalent urological condition that significantly impacts patients' quality of life. Advances in the study of Extracellular Vesicles (EV) have revealed their close involvement in the pathogenesis of prostatitis. This paper reviews the progress in understanding the role of EV in the pathogenesis of chronic prostatitis type IIIA, particularly their involvement in inflammatory responses, cell signaling, and interactions with immune cells. Additionally, it explores the potential applications of EV as drug delivery vehicles, including the targeted delivery of anti-inflammatory agents and immunomodulators, and highlights the challenges associated with developing exosome-based therapeutic strategies. In-depth research on EV holds promise for offering new insights into the diagnosis and treatment of inflammatory diseases.

Application of engineered exosomes in tumor therapy

Malignant tumors pose a significant threat to human health, and conventional cancer therapies are limited by inadequate targeting, leading to severe side effects. Exosomes, as extracellular vesicles mediating intercellular communication, exhibit advantages such as low immunogenicity, high biocompatibility, and low toxicity. After modification, engineered exosomes can be employed as targeted delivery vehicles in tumor therapy. This review summarizes the cellular origin, production methods, engineering strategies, and drug-loading routes of engineered exosomes, discusses their applications in cancer treatment, and delves into the challenges and issues in translating engineered exosomes to clinical practice, aiming to provide insights for exosome engineering research.

Therapeutic potential of exosomal lncRNAs derived from stem cells in wound healing: focusing on mesenchymal stem cells

The self-renewal ability and multipotency of stem cells give them great potential for use in wound healing. Stem cell-derived exosomes, owing to their close biological resemblance to their parent cells, offer a more efficient, safer, and economical approach for facilitating cellular communication and interactions within different environments. This potential makes them particularly valuable in the treatment of both acute and chronic wounds, such as lacerations, burns, and diabetic ulcers. Long non-coding RNAs (lncRNAs) enclosed in exosomes, as one of the leading actors of these extracellular microvesicles, through interaction with miRNAs and regulation of various signaling pathways involved in inflammation, angiogenesis, cell proliferation, and migration, could heal the wounds. Exosome-derived lncRNAs from stem cells facilitate extracellular matrix remodeling through interaction between macrophages and fibroblasts. Moreover, alongside regulating the expression of inflammatory cytokines, controlling reactive oxygen species levels, and enhancing autophagic activity, they also modulate immune responses to support wound healing. Regulating the expression of genes and signaling pathways related to angiogenesis, by increasing blood supply and accelerating the delivery of essential substances to the wound environment, is another effect exosomal lncRNAs derived from stem cells for wound healing. These lncRNAs can also enhance skin wound healing by regulating homeostasis, increasing the proliferation and differentiation of cells involved in the wound-healing process, and enhancing fibroblast viability and migration to the injury site. Ultimately, exosome-derived lncRNAs from stem cells offer valuable and novel insights into the molecular mechanisms underlying improved wound healing. They can pave the way for potential therapeutic strategies, fostering further research for a better future. Meanwhile, exosomes derived from mesenchymal stem cells, due to their exceptional regenerative properties, as well as the lncRNAs derived from these exosomes, have emerged as one of the innovative tools in wound healing. This review article aims to narrate the cellular and molecular roles of exosome-derived lncRNAs from stem cells in enhancing wound healing with a focus on mesenchymal stem cells.

TMEM45A enhances palbociclib resistance and cellular glycolysis by activating AKT/mTOR signaling pathway in HR+ breast cancer

Palbociclib, a CDK4/6 inhibitor, plays a crucial role in the treatment of HR+ breast cancer. However, resistance to palbociclib is a significant concern that merits further investigation. Our investigation identifies TMEM45A as a potential driver of palbociclib resistance and its association with increased cellular glycolysis. We demonstrate that TMEM45A is highly expressed in palbociclib-resistant breast cancer (BRCA) cells, correlating with enhanced tumor progression. Silencing TMEM45A enhances sensitivity to palbociclib, promotes cell cycle arrest and apoptosis, and inhibits the proliferation of BRCA cells. Moreover, attenuation of TMEM45A expression reduces cancer aggressiveness by decreasing the expression of EMT and glycolysis-related proteins. Subsequent gene set enrichment analysis (GSEA) confirms that TMEM45A activates the AKT/mTOR signaling pathway, which is integral to cell cycle progression and glycolysis. In a cell line-derived xenograft (CDX) mouse model, TMEM45A knockdown significantly restores sensitivity to palbociclib and suppresses tumor growth. Additionally, the use of engineered exosomes loaded with siRNA targeting TMEM45A presents a promising strategy for enhancing CDK4/6 inhibitor sensitivity without observable toxic side effects in a patient-derived xenograft (PDX) model. Collectively, our findings suggest that TMEM45A may be a therapeutic target for overcoming palbociclib resistance, and exosomal siRNA delivery could be a viable strategy for precision medicine in HR+ breast cancer.

Latexin (LXN) enhances tumor immune surveillance in mice by inhibiting Treg cells through the macrophage exosome pathway

Latexin (LXN) is a secreted protein with a molecular weight of 29 KD, which is considered a tumor suppressor and plays an important role in the inflammatory immune response. LXN is highly expressed in macrophages and regulates macrophage polarity and tumor immune escape, demonstrating excellent clinical potential. However, its mechanism is still unclear. In this study, a macrophage-T cell co-culture system is established to clarify the secretion of macrophage LXN into the extracellular through exosomes. The results indicate that LXN in macrophage-derived exosomes is functional, that is, LXN-enriched exosome inhibits CD4+T cell differentiation into Treg cells in vitro and in vivo, and exhibits good tumor suppressive effects. Based on this discovery, a biomimetic nanoparticle loaded with LXN protein (MØ@LXN-NPS) is designed and synthesized. Furthermore, the MØ@LXN-NPS shows excellent performance in both in vivo and in vitro, especially in enhancing tumor immune surveillance by inhibiting Treg cells in tumor microenvironment, thus exhibiting excellent anti-tumor activity. This study provides a demonstration for the transition of biomolecules from functional research to engineering applications. The excellent performance of MØ@LXN-NPS in tumor immune regulation suggests that the engineered biomimetic nanomedicine has good clinical application prospects.

Targeting secretory autophagy in solid cancers: mechanisms, immune regulation and clinical insights

Secretory autophagy is a classical form of unconventional secretion that integrates autophagy with the secretory process, relying on highly conserved autophagy-related molecules and playing a critical role in tumor progression and treatment resistance. Traditional autophagy is responsible for degrading intracellular substances by fusing autophagosomes with lysosomes. However, secretory autophagy uses autophagy signaling to mediate the secretion of specific substances and regulate the tumor microenvironment (TME). Cytoplasmic substances are preferentially secreted rather than directed toward lysosomal degradation, involving various selective mechanisms. Moreover, substances released by secretory autophagy convey biological signals to the TME, inducing immune dysregulation and contributing to drug resistance. Therefore, elucidating the mechanisms underlying secretory autophagy is essential for improving clinical treatments. This review systematically summarizes current knowledge of secretory autophagy, from initiation to secretion, considering inter-tumor heterogeneity, explores its role across different tumor types. Furthermore, it proposes future research directions and highlights unresolved clinical challenges.

Exosome-mediated delivery of CRISPR-Cas9: A revolutionary approach to cancer gene editing

Several molecular strategies based on targeted gene delivery systems have been developed in recent years; however, the CRISPR-Cas9 technology introduced a new era of targeted gene editing, precisely modifying oncogenes, tumor suppressor genes, and other regulatory genes involved in carcinogenesis. However, efficiently and safely delivering CRISPR-Cas9 to cancer cells across the cell membrane and the nucleus is still challenging. Using viral vectors and nanoparticles presents issues of immunogenicity, off-target effects, and low targeting affinity. Naturally, extracellular vesicles called exosomes have garnered the most attention as delivery vehicles in oncology-related CRISPR-Cas9 calls due to their biocompatibility, loading capacity, and inherent targeting features. The following review discusses the current progress in using exosomes to deliver CRISPR-Cas9 components, the approaches to load the CRISPR components into exosomes, and the modification of exosomes to increase stability and tumor-targeted delivery. We discuss the latest strategies in targeting recently accomplished in the exosome field, including modifying the surface of exosomes to enhance their internalization by cancer cells, as well as the measures taken to overcome the impacts of TME on delivery efficiency. Focusing on in vitro and in vivo experimentation, this review shows that exosome-mediated CRISPR-Cas9 can potentially treat cancer types, including pancreatic, lymphoma, and leukemia, for given gene targets. This paper compares exosome-mediated delivery and conventional vectors regarding safety, immune response, and targeting ability. Last but not least, we present the major drawbacks and potential development of the seemingly promising field of exosome engineering in gene editing, with references to CRISPR technologies and applications that may help make the target exosomes therapeutic in oncology.

An Injectable Hydrogel Bioimplant Loaded with Engineered Exosomes and Triple Anti-Tuberculosis Drugs with Potential for Treating Bone and Joint Tuberculosis

Purpose

Treatment for bone and joint tuberculosis (BJTB) is challenging due to its refractory and recurrent nature. This study aimed to develop a bioimplantable scaffold with osteoinductive and antituberculosis characteristics to treat BJTB.

Methods

This scaffold is built on oxidized hyaluronic acid and carboxymethyl chitosan hydrogel mixed with hydroxyapatite as a bone tissue engineered material. In order to make the scaffold have the biological activity of promoting tissue repair, the engineered exosomes (Exoeng) were added innovatively. In addition, drug-loaded liposomes equipped with an aldehyde group on the surface are cross-linked with the amine group of the hydrogel skeleton to participate in the Schiff base reaction.

Results

The designed scaffold has characteristics of self-healing and injectability exhibit excellent anti-tuberculosis and promoting bone repair activities. Exoeng strongly stimulates cellular angiogenesis and osteogenic differentiation. The liposomes coated in hydrogel can release three kinds of anti-tuberculosis drugs smoothly and slowly, achieving a long term anti-tuberculosis.

Conclusion

The composite bio-scaffold shows good tissue repair and long-term anti-tuberculosis abilities, which expected to provide a viable treatment plan for bone-related BJTB.