Tumor Blood Vessels Research Articles

Normalization of tumor vasculature by imiquimod: proposal for a new anticancer therapeutic indication for a TLR7 agonist

Imiquimod (IMQ), a drug from aminoquinoline group, is the toll-like receptor 7 (TLR7) agonist. It acts as an immunostimulant and radio-sensitizing agent. IMQ stimulates both innate and adaptive immune response. Despite studies conducted, there are no unambiguous data showing how IMQ affects the condition of tumor blood vessels. Tumor vasculature plays the main role in tumor progression. Formation of abnormal blood vessels increases area of hypoxia which recruits suppressor cells, blocks tumor infiltration by CD8+ T lymphocytes, inhibits efficacy of chemoterapeutic drug and leads to cancer relapse. Normalization is a type of therapy targeted at abnormal tumor blood vessels. Here, we demonstrated that 50 µg of IMQ inhibits the growth of melanoma tumors more efficiently, compared to other tested doses and the control group. Dose escalation did not improve the therapeutic antitumor potential of TLR7 agonist. A dose of 50 µg of IMQ most effectively reduced tumor blood vessel density. Imiquimod normalized tumor vasculature both structurally (by reducing vessel tortuosity and increasing pericyte coverage) and functionally (by improving tumor perfusion) in a dose-dependent manner. Hypoxia regions in tumors of treated mice were significantly reduced after IMQ administration. A dose of 50 µg of IMQ had also the greatest impact on the changes in tumor-infiltrating T lymphocytes levels. TLR7 agonist inhibited angiogenesis in treated mice. Functional vascular normalization by IMQ increases the effectiveness of low dose of doxorubicin. Higher dose of IMQ showed worse effects than lower doses including decreased tumor perfusion, increased tumor hypoxia and immunosuppression. This knowledge may help to optimize the combination of the selected IMQ dose with e.g. chemotherapy or radiotherapy to elicit synergistic effect in cancer treatment. To conclude, we outline IMQ repurposing as a vascular normalizing agent. Our research results may contribute to expanding the therapeutic indications for the use of IMQ in anticancer therapy in the future.

Chlorin e6: a promising photosensitizer of anti-tumor and anti-inflammatory effects in PDT.

Photodynamic therapy (PDT) involves the activation of photosensitizers (PSs) by visible laser light at the target site to catalyze the production of reactive oxygen species, resulting in tumor cell death and blood vessel closure. The efficacy of PDT depends on the PSs, the amount of oxygen, and the intensity of the excitation laser. PSs have been extensively researched, and great efforts have been made to develop an ideal photosensitizer. Chlorin-e6 is an FDA-approved second-generation PSs that has attracted widespread research interest in the medical field, especially with respect to antitumor and anti-inflammatory activity. Chlorin-e6 possesses the advantages of a large absorption coefficient, high strength, low residue in the body, and relatively high safety and thus has promising application prospects. Here we review the use of chlorin-e6 in PDT and discuss the prospects of further development of this technology.

Vesicles Secreted by Renal Cell Carcinoma Cells Cause Vascular Endothelial Cells to Express PSMA and Drive Tumor Progression

Prostate-specific membrane antigen (PSMA) protein expression is induced during prostate cancer progression and metastasis. Recently, we reported that PSMA-positive vesicles released by prostate cancer cell lines enhanced vascular endothelial cell angiogenesis and that PSMA may be involved in tumor angiogenesis. Similarly, it is known that PSMA is upregulated in peritumoral vessels in renal cell carcinoma (RCC). In this study, we investigated the significance and molecular function of PSMA in RCC. PSMA immunohistochemical staining confirmed PSMA presence only in perinephric tumor vessels, and PSMA intensity was strongly correlated with recurrence rate and venous invasion. Spatial gene expression analysis revealed that FOLH1 expression, which codes PSMA, was upregulated in tumor blood vessels around renal cancer, and that angiogenesis-related pathways were enhanced. The 10,000 g pellet fraction of the renal cancer cell lines Caki1- and ACHN-conditioned medium (CM) induced PSMA positivity in human umbilical vein endothelial cells (HUVECs) and enhanced tube formation. Mass spectrometry indicated that the 10,000 g pellet fraction contained various kinds of growth factors, like GDF15 and MYDGF. RNA sequencing showed that supplementing HUVECs with RCC cell CM-enhanced angiogenesis-related signaling pathways. Conclusively, microvesicle components secreted by RCC cells transform vascular endothelial cells into PSMA-positive cells, enhancing angiogenesis.

Navigating Tumor Microenvironment Barriers with Nanotherapeutic Strategies for Targeting Metastasis.

Therapeutic strategy for efficiently targeting cancer cells needs an in-depth understanding of the cellular and molecular interplay in the tumor microenvironment (TME). TME comprises heterogeneous cells clustered together to translate tumor initiation, migration, and proliferation. The TME mainly comprises proliferating tumor cells, stromal cells, blood vessels, lymphatic vessels, cancer-associated fibroblasts (CAFs), extracellular matrix (ECM), and cancer stem cells (CSC). The heterogeneity and genetic evolution of metastatic tumors can substantially impact the clinical effectiveness of therapeutic agents. Therefore, the therapeutic strategy shall target TME of all metastatic stages. Since the advent of nanotechnology, smart drug delivery strategies are employed to deliver effective drug formulations directly into tumors, ensuring controlled and sustained therapeutic efficacy. The state-of-the-art nano-drug delivery systems are shown to have innocuous modes of action in targeting the metastatic players of TME. Therefore, this review provides insight into the mechanism of cancer metastasis involving invasion, intravasation, systemic transport of circulating tumor cells (CTCs), extravasation, metastatic colonization, and angiogenesis. Further, the novel perspectives associated with current nanotherapeutic strategies are highlighted on different stages of metastasis.

Harvey Cushing: France Military Hospital Surgical Unit Head and World War I U.S. Army Medical Corps Commissioner.

This historical account reviews the course and lasting impact of Dr. Harvey Cushing (1869-1939) in neurosurgery. The writing of this project was sparked by the discovery of original scientific and bibliographical information about Cushing. It is a thorough review of archival documents about Harvey Cushing and the Cushing family. Harvey Cushing received his early schooling at the Cleveland Manual Training School, which provided him early access to science and developed his manual dexterity. Along with obtaining a degree at Yale University and training at both Harvard Medical School and The Johns Hopkins Hospital, Cushing collaborated with Louise Eisenhardt, Riva Rocci, Ivan Petrovich Pavlov, William Stewart Halstead, and Sir William Osler. Cushing wrote several monographs including Blood Vessel Tumours of the Brain, The Pituitary Body and its Disorders, and Tumors of the Nervus Acousticus. Cushing served in the U.S. Army Medical Corps, worked as the surgical unit head for a French military hospital, and treated Lieutenant Edward Revere Osler. Cushing's armamentarium included electromagnets for brain surgery. He was elected to the American Academy of Arts and Sciences and received various accolades. Cushing trained Walter Dandy, Louise Eisenhardt, and Wilder Penfield. This historical reconstruction provides glimpses into the personality of Dr. Harvey Cushing and his marked impact on neurosurgery and adds to the growing literature on his person.

Predictive value of a constructed artificial neural network model for microvascular invasion in hepatocellular carcinoma: A retrospective study.

Microvascular invasion (MVI) is a significant risk factor for recurrence and metastasis following hepatocellular carcinoma (HCC) surgery. Currently, there is a paucity of preoperative evaluation approaches for MVI. To investigate the predictive value of texture features and radiological signs based on multiparametric magnetic resonance imaging in the non-invasive preoperative prediction of MVI in HCC. Clinical data from 97 HCC patients were retrospectively collected from January 2019 to July 2022 at our hospital. Patients were classified into two groups: MVI-positive (n = 57) and MVI-negative (n = 40), based on postoperative pathological results. The correlation between relevant radiological signs and MVI status was analyzed. MaZda4.6 software and the mutual information method were employed to identify the top 10 dominant texture features, which were combined with radiological signs to construct artificial neural network (ANN) models for MVI prediction. The predictive performance of the ANN models was evaluated using area under the curve, sensitivity, and specificity. ANN models with relatively high predictive performance were screened using the DeLong test, and the regression model of multilayer feedforward ANN with backpropagation and error backpropagation learning method was used to evaluate the models' stability. The absence of a pseudocapsule, an incomplete pseudocapsule, and the presence of tumor blood vessels were identified as independent predictors of HCC MVI. The ANN model constructed using the dominant features of the combined group (pseudocapsule status + tumor blood vessels + arterial phase + venous phase) demonstrated the best predictive performance for MVI status and was found to be automated, highly operable, and very stable. The ANN model constructed using the dominant features of the combined group can be recommended as a non-invasive method for preoperative prediction of HCC MVI status.

Can we diagnose noninvasive follicular thyroid neoplasm with papillary-like nuclear features before surgery?

Noninvasive follicular thyroid neoplasm with papillary-like nuclear features (NIFTP) can be differentiated from invasive encapsulated follicular variant of papillary thyroid carcinoma (eFV-PTC) by the presence of a tumor capsule or blood vessel invasion in histological examination. The objective of this study was to investigate whether it is possible to distinguish between NIFTP and invasive eFV-PTC before surgery. Patients diagnosed with NIFTP and invasive eFV-PTC from 2017 to 2023 were analyzed for biochemical, ultrasonographic, and cytological features. No differences were found in thyroid function tests, thyroid autoantibody levels, tumor size, or ultrasonographic characteristics. However, patients with invasive eFV-PTC had higher preoperative neutrophil-to-lymphocyte ratio (NLR) values and a higher Bethesda cytology category compared to those with NIFTP. In the multivariable analysis, NLR was the only significant predictor of invasive eFV-PTC. Nevertheless, there was no reliable NLR cutoff for distinguishing between the two entities. Overall, this study substantiates considerable overlap in demographic and clinical data between NIFTP and invasive eFV-PTC. Although the higher NLR observed in thyroid cancer does not provide strong discrimination, it suggests that the invasive nature of tumor cells might elicit a more profound systemic inflammatory or immune response.

Integrated identification and mechanism exploration of bioactive ingredients from Salvia miltiorrhiza to induce vascular normalization.

The clinical management of ischemic disease and cancer is complex, with disruptions in local vascular function and tumor angiogenesis contributing to blood stasis, which complicates treatment strategies. Salvia miltiorrhiza, a natural product, is known to restore vascular structure and function. However, its specific roles in concurrently addressing ischemic disease and cancer within the same organism remain poorly understood. This study aimed to explore the material basis, pharmacological effects, and underlying mechanisms of Salvia miltiorrhiza extract (SME) in promoting blood flow recovery in ischemic hindlimbs and inducing tumor vascular normalization. The pharmacological effects of SME were evaluated in a mouse model combining ischemic hindlimbs and tumors. Mice were administered low (SME-L) or high (SME-H) doses of SME daily, and the gastrocnemius muscle mass and tumor vascular structure were assessed. Laser Doppler perfusion imaging (LDPI) was used to monitor hindlimb blood flow recovery and tumor vascular perfusion. The pharmacokinetics of the key bioactive constituents in SME were characterized by liquid chromatography-mass spectrometry (LC-MS). Interactions between SME's active compounds and predicted targets were investigated using molecular docking, microscale thermophoresis (MST), and luciferase reporter assays. The synergistic effects of the primary components, Tanshinone I (Tan I) and Salvianolic acid A (Sal A), were analyzed through tube formation assays, enzyme-linked immunosorbent assays (ELISA), immunofluorescence staining, and western blot. Phytochemical profiling revealed that SME contains several active compounds, including Danshensu, Sal A, Sal B, Tan IIA, and Tan I. SME treatment reduced the frequency of necrotic toes, increased muscle mass, and alleviated hypoxia in the gastrocnemius muscle. SME significantly improved tumor vascular perfusion and notably enhanced pericyte coverage and basement membrane integrity. Pharmacokinetic analysis identified Tan I and Sal A as the key bioactive components that promote vascular normalization. Tan I inhibited FoxO1, preventing endothelial cell activation induced by angiopoietin 2 (Ang2), while Sal A bound to Ang2, facilitating Tie2 activation mediated by Ang1. Both in vitro and in vivo results demonstrated that the combination of Tan I and Sal A exerted a synergistic therapeutic effect on correcting abnormal blood vessels in ischemic hindlimbs and tumors. Our study innovatively revealed a reliable mouse model wherein the Ang2/Tie2 signaling cascade disrupted the endothelial homeostasis to aggravate the progression of hindlimb ischemia and tumor angiogenesis. This balance can be rescued by the combination therapy of Tan I and Sal A that were both from SME, leading to the occurrence of vascular normalization.

Magnetic Resonance Imaging-Based Radiogenomic Analysis Reveals Genomic Determinants for Nanoparticle Delivery into Tumors.

Even though the enhanced permeability and retention (EPR) effect is applicable for the passive targeting of solid tumors, many nanodrugs have failed to achieve meaningful clinical outcomes due to the heterogeneity of EPR effect. Therefore, understanding the mechanism of the EPR effect is crucial to overcome the obstacles nanomedicines face in clinical translation. The aim of this study was to establish a reliable method to increase awareness of the critical influencing factors of nanoparticle (NP) transport into tumors based on the EPR effect using a combined radiogenomics and clinical magnetic resonance imaging (MRI) technique and gene set pathway enrichment analysis. Employing poly(lactic-co-glycolic acid) (PLGA)-coated Fe3O4 NPs as the contrast agent, the monolayer and multilayer distribution of the NPs were observed and quantitatively analyzed by MRI, improving the accuracy of evaluating vascular permeability by MRI. By performing Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analyses of genes and pathways, we identified a variety of genes affecting vascular permeability, such as Cldn1, Dlg2, Bves, Prkag3, Cldn10, and Cldn8, which are related to tight junctions and control the permeability of blood vessels in tumors. The method presented here provides an MRI-supported approach to increase the breadth of data collected from genetic screens, reveals genetic evidence of the presence of NPs in tumors and lays a foundation for clinical patient stratification and personalized treatment.

3D electron microscopy for analyzing nanoparticles in the tumor endothelium

Delivering medical agents to diseased tissues has been challenging, leading researchers to study the in vivo transport process in the body for improving delivery. Many imaging techniques exist for mapping the distribution of medical agent-carrying nanoparticles in tissues, but they cannot capture the three-dimensional context of tissues with single nanoparticle resolution. Here, we developed 3DEM-NPD, a three-dimensional electron microscopy (3D EM) machine learning strategy to image and map single nanoparticle distributions (NPD) in tissues. 3DEM-NPD provides unbiased visualization and quantification of individual nanoparticles within organs. We applied this technique to quantify nanoparticle transport through tumor blood vessel endothelial cells. We measured the cell diameter, surface area, and volume and found that traditional 2D EM cannot accurately measure these features. We used machine learning to locate over 550,000 nanoparticles in less than 3 h with an accuracy of over 82%. The 3DEM-NPD method allowed us to establish a metric to quantify nanoparticle transport at the single nanoparticle level and to quantify the morphological features of ~2,800 vesicles. We find that on average there are only 2.4 nanoparticles per vesicle with a theoretical maximum of 158 nanoparticles per vesicle (~66x increase). These surprising results suggest the need to increase vesicle encapsulation efficiency for improved transport and they provide a benchmark for increasing nanoparticle transport and delivery. This technique may provide unique insights into the interactions between medical agents, drug carriers, emerging materials, and cells at the single-nanoparticle level throughout tissues.

Regulation of Stromal Cells by Sex Steroid Hormones in the Breast Cancer Microenvironment.

Breast cancer is a prevalent hormone-dependent malignancy, and estrogens/estrogen receptor (ER) signaling are pivotal therapeutic targets in ER-positive breast cancers, where endocrine therapy has significantly improved treatment efficacy. However, the emergence of both de novo and acquired resistance to these therapies continues to pose challenges. Additionally, androgens are produced locally in breast carcinoma tissues by androgen-producing enzymes, and the androgen receptor (AR) is commonly expressed in breast cancer cells. Intratumoral androgens play a significant role in breast cancer progression and are closely linked to resistance to endocrine treatments. The tumor microenvironment, consisting of tumor cells, immune cells, fibroblasts, extracellular matrix, and blood vessels, is crucial for tumor progression. Stromal cells influence tumor progression through direct interactions with cancer cells, the secretion of soluble factors, and modulation of tumor immunity. Estrogen and androgen signaling in breast cancer cells affects the tumor microenvironment, and the expression of hormone receptors correlates with the diversity of the stromal cell profile. Notably, various stromal cells also express ER or AR, which impacts breast cancer development. This review describes how sex steroid hormones, particularly estrogens and androgens, affect stromal cells in the breast cancer microenvironment. We summarize recent findings focusing on the effects of ER/AR signaling in breast cancer cells on stromal cells, as well as the direct effects of ER/AR signaling in stromal cells.

Potential Role of the Tie2/ Angiopoietin System in Hepatitis C Virus- Induced Hepatocellular Carcinoma.

The Tie2/Ang pathway was found to be involved in forming tumor blood vessels in various tumors. The goal of this study was to evaluate the value of Tie2/Ang pathway as a novel biomarkers for the early detection of chronic hepatitis C virus (CHC)-related hepatocellular carcinoma (HCC). And the possibility of their future application in HCC treatment. Flow cytometry was performed to identify and count Tie2 expressing monocytes (TEMs) in peripheral blood monocytes from HCC patients (n = 25), CHC cirrhotic patients (n = 25) and healthy volunteers (n = 25). In addition, Angiopoietin 1 and 2 (Ang) levels in the serum were determined by enzyme linked immunosorbent assay (ELIZA). Percentage of TEMs in peripheral blood monocytes, serum Ang2 levels and Ang2/Ang1 ratio significantly increased in HCC patients compared with CHC patients and healthy controls (P< 0.001). However significant increase was only noticed in serum Ang1 levels in HCC group compared to the control group (P <0.05). TEMs may promote angiogenesis in HCC regarding the Ang2/Tie2 signal pathway. Percentage of TEMs in peripheral blood monocytes, Ang2 serum levels and Ang2/Ang1 ratio may be applied as a biomarkers for identifying CHC-related HCC. Moreover, inhibiting the proangiogenic functions of this pathway may represent a promising strategy to improve the efficacy of current treatments for HCC.

Progress on angiogenic and antiangiogenic agents in the tumor microenvironment.

The development of tumors and their metastasis relies heavily on the process of angiogenesis. When the volume of a tumor expands, the resulting internal hypoxic conditions trigger the body to enhance the production of various angiogenic factors. These include vascular endothelial growth factor (VEGF), fibroblast growth factor (FGF), platelet-derived growth factor (PDGF), and transforming growth factor-α (TGF-α), all of which work together to stimulate the activation of endothelial cells and catalyze angiogenesis. Antiangiogenic therapy (AAT) aims to normalize tumor blood vessels by inhibiting these angiogenic signals. In this review, we will explore the molecular mechanisms of angiogenesis within the tumor microenvironment, discuss traditional antiangiogenic drugs along with their limitations, examine new antiangiogenic drugs and the advantages of combination therapy, and consider future research directions in the field of antiangiogenic drugs. This comprehensive overview aims to provide insights that may aid in the development of more effective anti-tumor treatments.

Sequential treatment of anti-PD-L1 therapy prior to anti-VEGFR2 therapy contributes to more significant clinical benefits in non-small cell lung cancer

ObjectiveAnti-angiogenic therapy and immune checkpoint blockade therapy are currently important treatments for non-small cell lung cancer. However, the combined use of the two therapies is controversial, and few studies have investigated the effects of different time sequences of the two therapies on treatment outcomes. MethodsThe tumor-bearing mouse model was established and the mice were divided into four groups, including AA-ICB sequence group, ICB-AA sequence group, synchronization group and the control group. Immunohistochemistry was used to assess tumor microvessels and PD-L1 expression. Selected immune cell populations were evaluated using flow cytometry. Meta-analysis and clinical information were used to elucidate the clinical effects of administration sequence. ResultsWe found that anti-PD-L1 treatment followed by anti-VEGFR2 therapy exerts the best inhibitory effect on tumor growth. Different sequences of anti-angiogenic therapy and immune checkpoint blockade therapy resulted in different proportions of tumor microvessels and immune cell populations in the tumor microenvironment. We further revealed that the administration of anti-PD-L1 before anti-VEGFR brought more normalized tumor blood vessels and CD8+T cell infiltration and reduced immunosuppressive cells in the tumor microenvironment. Subsequent re-transplantation experiments confirmed the long-term benefits of this treatment strategy. The meta-analysis reinforced that immunotherapy prior to anti-angiogenic therapy or combination therapy have better therapeutic effects in advanced non-small cell lung cancer. ConclusionOur study demonstrated that the therapeutic effect of anti-angiogenic treatment after immune checkpoint therapy was superior to that of concurrent therapy, whereas anti-angiogenic therapy followed by immunotherapy did not bring more significant clinical benefits than independent monotherapy.

Abstract C039: The impact of antiangiogenic therapy on blood vessels and CD8 infiltration in renal cancer metastases is space, time, site, dose, and drug dependent

Abstract Clear cell renal cell carcinoma (ccRCC) is the most prevalent renal neoplasm, with bone as a major site for distant spread in 35% to 40% of the patients. These metastases are typically osteolytic, resistant to treatments, hence result in a variety of skeletal-related complications strongly contributing to mortality. A key feature of ccRCC is the loss of function of the von Hippel–Lindau (VHL) protein leading to extensive angiogenesis. Consequently, different anti-angiogenic tyrosine kinase inhibitors (TKIs) are used as the first or subsequent line of treatment for these patients as single agents or in combination with immune checkpoint inhibitors. However, limited data about their efficacy in bone metastasis is available, and their impact on the immune infiltrate, including effector CD8 cells, is unclear. We hypothesized that TKIs, by inhibiting angiogenesis, significantly reprogram the microenvironment and limit immune infiltration in space, time, dose, and drug dependent fashion. To test these hypotheses, we developed an immunocompetent mouse model of bone metastasis by orthotopical intratibial implantation of luciferase-GFP-positive mouse RENCA-VHL- cell line. Interestingly, intratibial injections gave rise to metastases in lungs, creating a unique opportunity to study two metastatic sites. Three different TKIs currently used in patients were tested and compared to control: axitinib (A), cabozantinib (C), and lenvantinib (L). Outcomes were monitored by macroscopic bioluminescence detection in vivo, 3D multiparametric spatial analysis of bones and lungs, in vivo, and ex vivo. Compared to control-treated mice, high doses of A, C, and L significantly reduced tumor progression in both tumor sites. Even though these TKIs are clinically considered equal, significant differences in their efficacy were noted. Spatial analysis of tumor cells and blood vessels showed a significant decrease in blood vessels formation in both an organ- and TKI-specific pattern over time. Additionally, the reduction of neo angiogenesis in treated tumors directly limited the infiltration of CD8 cells, which localized at the interface with tumor free bone/lung tissue. Interestingly, TKI dose reduction significantly improved CD8 infiltration, while controlling tumor size. TKI withdrawal, instead, led to rapid progression of tumor in both sites and significantly shortened mice survival. In conclusion, we established bone and lung metastatic models of ccRCC and characterized and compared the effects of three antiangiogenic TKIs on angiogenesis and CD8 infiltration. TKIs reduced tumor growth and progression, because of blood vessel formation inhibition. Furthermore, TKI treatment reduced the infiltration of effector T cells in tumors in a dose-dependent manner, an outcome that can have a major impact when TKIs are combined with immunotherapy, a preferential therapeutic regimen for ccRCC patients. Overall, we believe our studies provide important insights and efficacy predictions for innovative therapeutic applications in ccRCC bone metastatic patients. Citation Format: Stefan Maksimovic, Nina Costanza Boscolo, Ludovica La Posta, Matthew T. Campbell, Eleonora Dondossola. The impact of antiangiogenic therapy on blood vessels and CD8 infiltration in renal cancer metastases is space, time, site, dose, and drug dependent [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Tumor-body Interactions: The Roles of Micro- and Macroenvironment in Cancer; 2024 Nov 17-20; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(22_Suppl):Abstract nr C039.

Unveiling the therapeutic potential of anthocyanin/cisplatin-loaded chitosan nanoparticles against breast and liver cancers

BackgroundLiver and breast cancers are among the leading causes of cancer-related deaths worldwide, prompting researchers to seek natural anticancer agents and reduce chemotherapy side effects. Red beetroot (Beta vulgaris Linnaeus), rich in polyphenols and powerful antioxidants, has shown potential in cancer prevention. This study aimed to evaluate the impact of red beetroot-derived anthocyanin (Ant), Ant-loaded chitosan nanoparticles (Ant NPs), cisplatin (Cis), Cis-loaded chitosan (Cis NPs), and Cis + Ant-loaded chitosan NPs on human hepatoma HepG2 and breast adenocarcinoma MCF7 cell lines.MethodsNPs preparation was evaluated by zeta potential, FTIR, and SEM. The cytotoxic, apoptotic, antioxidant, anti-inflammatory, anti-metastatic, and anti-angiogenic effects were assessed by MTT assay, qPCR, AO/EB staining, and flow cytometry.ResultsTreatment with Ant, Ant NPs, Cis, Cis NPs, and Cis + Ant NPs caused cytotoxicity in HepG2 and MCF7 with best effect in Cis-treated cells. The anticancer effects were attributed to mitochondrial-dependent apoptosis (with high Bax and low Bcl2 expression), chromatin disintegration, and cell cycle arrest in G2/M and S phases. All treatments inhibited migration by downregulating the migration-related gene MMP9 and upregulating the anti-migratory gene TIMP1 and decreased the angiogenesis-related gene VEGF and the inflammatory gene TNFα with best results in Cis NPs-treated cells. Interestingly, Ant, Ant NPs, and Cis + Ant NPs increased the antioxidant status (high GSH and upregulated expression of Nrf2 and OH-1) and decreased drug resistance-related MAPK1 and MDR1 genes compared to Cis and Cis NPs-treated cells.ConclusionsAnthocyanin and cisplatin-loaded chitosan nanoparticles effectively combat breast and liver cancers by inducing cancer cell apoptosis, enhancing antioxidant defenses, and reducing inflammation. They also inhibit tumor spread and blood vessel formation through downregulation of MMP9 and VEGF, highlighting their therapeutic potential.

Iron-based MOF with Catalase-like activity improves the synergistic therapeutic effect of PDT/ferroptosis/starvation therapy by reversing the tumor hypoxic microenvironment

Reversing the hypoxic microenvironment of tumors is an important method to enhance the synergistic effect of tumor treatment. In this work, we developed the nanoparticles called Ce6@HGMOF, which consists of a photosensitizer (Ce6), glucose oxidase (GOX), chemotherapy drugs (HCPT) and an iron-based metal-organic framework (MOF). Ce6@HGMOF can consume glucose in tumor cells through “starvation therapy”, cut off their nutrition source, and produce gluconic acid and hydrogen peroxide (H2O2). Utilizing this feature, Ce6@HGMOF can produce oxygen through catalase-like catalytic activity, thereby reversing the hypoxic microenvironment of tumors. This strategy of changing the hypoxic environment can help to slow down the growth of tumor blood vessels and improve the drug-resistant microenvironment to some extent. Meanwhile, increasing the supply of oxygen can enhance the effect of photodynamic therapy (PDT) and enhance the oxidative stress damage caused by reactive oxygen species (ROS) in tumor cells. On the other hand, cancer cells usually produce higher levels of glutathione (GSH) to adapt to high oxidative stress and protect themselves. The Ce6@HGMOF we designed can also consume GSH and induce ferroptosis of tumor cells through Fenton reaction with H2O2, while enhancing the effect of PDT. This innovative synergistic strategy, the combination of PDT/ferroptosis /starvation therapy, can complement each other and enhance each other. It has great potential as a powerful new anti-tumor paradigm in the future.

Enhancing Tumor Targeted Therapy: The Role of iRGD Peptide in Advanced Drug Delivery Systems.

Chemotherapy remains the primary therapeutic approach in treating cancer. The tumor microenvironment (TME) is the complex network surrounding tumor cells, comprising various cell types, such as immune cells, fibroblasts, and endothelial cells, as well as ECM components, blood vessels, and signaling molecules. The often stiff and dense network of the TME interacts dynamically with tumor cells, influencing cancer growth, immune response, metastasis, and resistance to therapy. The effectiveness of the treatment of solid tumors is frequently reduced due to the poor penetration of the drug, which leads to attaining concentrations below the therapeutic levels at the site. Cell-penetrating peptides (CPPs) present a promising approach that improves the internalization of therapeutic agents. CPPs, which are short amino acid sequences, exhibit a high ability to pass cell membranes, enabling them to deliver drugs efficiently with minimal toxicity. Specifically, the iRGD peptide, a member of CPPs, is notable for its capacity to deeply penetrate tumor tissues by binding simultaneously integrins ανβ3/ανβ5 and neuropilin receptors. Indeed, ανβ3/ανβ5 integrins are characteristically expressed by tumor cells, which allows the iRGD peptide to home onto tumor cells. Notably, the respective dual-receptor targeting mechanism considerably increases the permeability of blood vessels in tumors, enabling an efficient delivery of co-administered drugs or nanoparticles into the tumor mass. Therefore, the iRGD peptide facilitates deeper drug penetration and improves the efficacy of co-administered therapies. Distinctively, we will focus on the iRGD mechanism of action, drug delivery systems and their application, and deliberate future perspectives in developing iRGD-conjugated therapeutics. In summary, this review discusses the potential of iRGD in overcoming barriers to drug delivery in cancer to maximize treatment efficiency while minimizing side effects.

Synthesis of heavy-atom-free thienoisoindigo dye as near-infrared photosensitizer for type I photodynamic therapy and photoacoustic imaging

Thienoisoindigo (TIIG) has been extensively employed as promising building block of near-infrared (NIR) dyes and organic semiconductor materials. Herein, heavy-atom-free TIIG-based NIR dye TIIGTPA is reported as photosensitizer for combinational photodynamic and photothermal therapy and photoacoustic imaging (PAI). By introducing two methoxy-substituted triphenylamines as the rotors and electron donors at the periphery sites of the electron-deficient TIIG core, dye TIIGTPA featuring Donor-Acceptor-Donor (D-AD) structure is constructed with intensive NIR absorption. Through co-assembly with amphipathic F-127, water-soluble TIIGTPA NPs were prepared with good superoxide anion radical (O2-•) production and high photothermal conversion efficiency (PCE) of 59.0 % under 730 nm photoirradiation. Additionally, the excellent photothermal effect enabled a superior photoacoustic response for tumor blood vessel visualization through PAI. All results indicated the favorable potential of TIIGTPA NPs for PAI-mediated combinational phototherapy.

RNA Nanotechnology for Codelivering High-Payload Nucleoside Analogs to Cancer with a Synergetic Effect.

Nucleoside analogs are potent inhibitors for cancer treatment, but the main obstacles to their application in humans are their toxicity, nonspecificity, and lack of targeted delivery tools. Here, we report the use of RNA four-way junctions (4WJs) to deliver two nucleoside analogs, floxuridine (FUDR) and gemcitabine (GEM), with high payloads through routine and simple solid-state RNA synthesis and nanoparticle assembly. The design of RNA nanotechnology for the co-delivery of nucleoside analogs and the chemotherapeutic drug paclitaxel (PTX) resulted in synergistic effects and high efficacy in the treatment of Triple-Negative Breast Cancer (TNBC). The 4WJ-drug complexes were confirmed to have efficient tumor spontaneous targeting and no toxicity because the motility of RNA nanoparticles has been previously shown to enable these RNA-drug complexes to spontaneously accumulate in tumor blood vessels. The negative charge of RNA enables those RNA complexes that are not targeted to tumor vasculature to circulate in the blood and enter the urine through the kidney glomerulus, without accumulating in organs, therefore being nontoxic. Drug incorporation into RNA 4WJ can be precisely controlled with a defined loading amount, location, and ratio. The incorporation of nucleoside analogs into 4WJ only requires one step using nucleoside analogue phosphoramidites during solid-phase RNA synthesis, without the need for additional conjugation and purification processes.