Engineered multifunctional nanocarriers for controlled drug delivery in tumor immunotherapy

Katopodi, Theodora; Petanidis, Savvas; Tsavlis, Drosos; Anestakis, Doxakis; Charalampidis, Charalampos; Chatziprodromidou, Ioanna P.; Eskitzis, Panagiotis; Kosmıdis, Christoforos; Matthaios, Dimitris; Porpodis, Κonstantinos

doi:10.3389/fonc.2022.1042125

Cited by 5 publications

(5 citation statements)

References 122 publications

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“…or immune organs, increasing the drug bioavailability and inhibiting immune-related adverse effects and chemoresistance. Furthermore, since there is an increased surface area, off-target impacts may be minimized or eliminated [ 21 , 22 ]. The host’s immune system is gradually awakened by the slow release once it reaches the tumor location, leading to improved therapeutic benefits.…”

Section: Bioengineered Nanogelsmentioning

confidence: 99%

Hybrid Nanogel Drug Delivery Systems: Transforming the Tumor Microenvironment through Tumor Tissue Editing

Katopodi,

Petanidis,

Floros

et al. 2024

Cells

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The future of drug delivery offers immense potential for the creation of nanoplatforms based on nanogels. Nanogels present a significant possibility for pharmaceutical advancements because of their excellent stability and effective drug-loading capability for both hydrophobic and hydrophilic agents. As multifunctional systems, composite nanogels demonstrate the capacity to carry genes, drugs, and diagnostic agents while offering a perfect platform for theranostic multimodal applications. Nanogels can achieve diverse responsiveness and enable the stimuli-responsive release of chemo-/immunotherapy drugs and thus reprogramming cells within the TME in order to inhibit tumor proliferation, progression, and metastasis. In order to achieve active targeting and boost drug accumulation at target sites, particular ligands can be added to nanogels to improve the therapeutic outcomes and enhance the precision of cancer therapy. Modern “immune-specific” nanogels also have extra sophisticated tumor tissue-editing properties. Consequently, the introduction of a multifunctional nanogel-based drug delivery system improves the targeted distribution of immunotherapy drugs and combinational therapeutic treatments, thereby increasing the effectiveness of tumor therapy.

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Section: Bioengineered Nanogelsmentioning

confidence: 99%

Hybrid Nanogel Drug Delivery Systems: Transforming the Tumor Microenvironment through Tumor Tissue Editing

Katopodi,

Petanidis,

Floros

et al. 2024

Cells

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“…However, these traditional therapies are limited because of poor treatment efficiency and improper drug targeting and delivery 5,6 . To confront these challenges, researchers from different disciplines, including therapeutics, chemistry, materials science, and pharmacology, have collaborated closely to apply nanosystems to cancer therapies 7–10 . Nanosystems within the dimensions of 1 to 100 nm have been proposed for their minimal invasiveness, high effectiveness, and efficient drug delivery 11–13 .…”

Section: Introductionmentioning

confidence: 99%

“… 5 , 6 To confront these challenges, researchers from different disciplines, including therapeutics, chemistry, materials science, and pharmacology, have collaborated closely to apply nanosystems to cancer therapies. 7 , 8 , 9 , 10 Nanosystems within the dimensions of 1 to 100 nm have been proposed for their minimal invasiveness, high effectiveness, and efficient drug delivery. 11 , 12 , 13 Several variants of nano‐drug delivery systems have been successfully studied for therapeutic applications, such as liposomes, dendrimers, polymeric nanoparticles, nanoemulsions, carbon nanotubes, gold nanoparticles, magnetic nanoparticles, solid lipid nanoparticles, hydrogels, and micelles.…”

Section: Introductionmentioning

confidence: 99%

Delivery of miR‐3529‐3p using MnO₂‐SiO₂‐APTES nanoparticles combined with phototherapy suppresses lung adenocarcinoma progression by targeting HIGD1A

Zhang

Wang

et al. 2023

Thoracic Cancer

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Background: The present study aimed to investigate the function of miR-3529-3p in lung adenocarcinoma and MnO 2 -SiO 2 -APTES (MSA) as a promising multifunctional delivery agent for lung adenocarcinoma therapy. Methods: Expression levels of miR-3529-3p were evaluated in lung carcinoma cells and tissues by qRT-PCR. The effects of miR-3529-3p on apoptosis, proliferation, metastasis and neovascularization were assessed by CCK-8, FACS, transwell and wound healing assays, tube formation and xenografts experiments. Luciferase reporter assays, western blot, qRT-PCR and mitochondrial complex assay were used to determine the targeting relationship between miR-3529-3p and hypoxia-inducible gene domain family member 1A (HIGD1A). MSA was fabricated using MnO 2 nanoflowers, and its heating curves, temperature curves, IC50, and delivery efficiency were examined. The hypoxia and reactive oxygen species (ROS) production was investigated by nitro reductase probing, DCFH-DA staining and FACS. Results: MiR-3529-3p expression was reduced in lung carcinoma tissues and cells. Transfection of miR-3529-3p could promote apoptosis and suppress cell proliferation, migration and angiogenesis. As a target of miR-3529-3p, HIGD1A expression was downregulated, through which miR-3529-3p could disrupt the activities of complexes III and IV of the respiratory chain. The multifunctional nanoparticle MSA could not only efficiently deliver miR-3529-3p into cells, but also enhance the antitumor function of miR-3529-3p. The underlying mechanism may be that MSA alleviates hypoxia and has synergistic effects in cellular ROS promotion with miR-3529-3p. Conclusions: Our results establish the antioncogenic role of miR-3529-3p, and demonstrate that miR-3529-3p delivered by MSA has enhanced tumor suppressive effects, probably through elevating ROS production and thermogenesis.

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“…Biomaterials have an important role in drug delivery systems, specifically regarding tumor target therapy. [ 5 ] It is widely believed that the enhanced permeation and retention effect is an important mechanism of biomaterials targeted therapy to improve the tumor immunotherapy effect, which prolongs the retention time by increasing the penetration of drugs into tumor tissues. [ 6 ] At the same time, a new innovative mechanism of drug enrichment is proposed, which can break through the basement membrane barrier of tumor blood vessels by inducing acute inflammation, briefly open the dynamic window, and realize the efficient penetration of biological materials like a volcanic eruption, effectively improving the enrichment and therapeutic effect in tumor tissues.…”

Section: Introductionmentioning

confidence: 99%

Biomaterials Elicit Pyroptosis Enhancing Cancer Immunotherapy

Zhang,

Wang,

Han

et al. 2023

Adv Funct Materials

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Cancer immunotherapy has the potential to revolutionize the treatment of malignant tumors, but its effectiveness is limited by the low immune response rate and immune‐related adverse events. Pyroptosis, as an inflammatory programmed cell death type, triggers strong acute inflammatory response and antitumor immunity, converting “cold” tumors to “hot”. Particularly, biomaterials loading pyroptosis inducers targeting the tumor microenvironment to engineer pyroptosis, have achieved great progress in recent years. Herein, the design strategy, mechanism pathway, and role of biomaterials to induce pyroptosis in cancer immunotherapy are comprehensively reviewed. The present review focuses on the application of biomaterials‐induced pyroptosis in cancer immunotherapy, including nanogel, polymer prodrug, nanovesicle, and mesoporous material. Additionally, the synthesis of a series of stimuli‐responsive nanoplatforms, including glutathione‐responsive, pH‐responsive, reactive oxygen species‐responsive, and enzyme‐mimicking catalytic performance, is described. Meanwhile, it augments multiple immune response processes of cell uptake, antigen presentation, T‐cell activation, and expansion. Finally, the perspectives of pyroptosis‐mediated inflammation to break through the tumor vascular basement membrane barrier achieving efficient volcanic penetration of biomaterials are discussed. Artificial intelligence, multi‐omics analysis, and anthropogenic animal models of organoids are presented, aiming to provide guidance and assistance for constructing effective and controllable pyroptosis‐engineered biomaterials and improving tumor immunotherapy.

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Engineered multifunctional nanocarriers for controlled drug delivery in tumor immunotherapy

Cited by 5 publications

References 122 publications

Hybrid Nanogel Drug Delivery Systems: Transforming the Tumor Microenvironment through Tumor Tissue Editing

Hybrid Nanogel Drug Delivery Systems: Transforming the Tumor Microenvironment through Tumor Tissue Editing

Delivery of miR‐3529‐3p using MnO₂‐SiO₂‐APTES nanoparticles combined with phototherapy suppresses lung adenocarcinoma progression by targeting HIGD1A

Biomaterials Elicit Pyroptosis Enhancing Cancer Immunotherapy

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Engineered multifunctional nanocarriers for controlled drug delivery in tumor immunotherapy

Cited by 5 publications

References 122 publications

Hybrid Nanogel Drug Delivery Systems: Transforming the Tumor Microenvironment through Tumor Tissue Editing

Hybrid Nanogel Drug Delivery Systems: Transforming the Tumor Microenvironment through Tumor Tissue Editing

Delivery of miR‐3529‐3p using MnO2‐SiO2‐APTES nanoparticles combined with phototherapy suppresses lung adenocarcinoma progression by targeting HIGD1A

Biomaterials Elicit Pyroptosis Enhancing Cancer Immunotherapy

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Delivery of miR‐3529‐3p using MnO₂‐SiO₂‐APTES nanoparticles combined with phototherapy suppresses lung adenocarcinoma progression by targeting HIGD1A