Cationic nanoparticles enhance T cell tumor infiltration and antitumor immune responses to a melanoma vaccine

Smith, Rasheid; Wafa, Emad I.; Geary, Sean M.; Ebeid, Kareem; Alhaj‐Suliman, Suhaila O.; Salem, Aliasger K.

doi:10.1126/sciadv.abk3150

Cited by 23 publications

(14 citation statements)

References 73 publications

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“…130 Cationic polymeric NPs using PLGA-PAMAM structure exhibit robust adjuvant properties in cancer vaccines, suggesting the great potential of cationic nanomaterials in cancer treatment. 131…”

Section: Polymeric Npsmentioning

confidence: 99%

“…The dendritic cells (DCs) targeting ability of polymer NPs was effectively enhanced by glycosylation on PLGA, and the glycosylated PLGA group demonstrated 3.5‐fold higher DCs uptake efficiency in vitro compared to control 130 . Cationic polymeric NPs using PLGA‐PAMAM structure exhibit robust adjuvant properties in cancer vaccines, suggesting the great potential of cationic nanomaterials in cancer treatment 131 …”

Section: Np Technologiesmentioning

confidence: 99%

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Advances and applications of nanoparticles in cancer therapy

Huang,

He,

Liang

et al. 2024

MedComm – Oncology

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Rapid growth in nanoparticles (NPs) as delivery systems holds vast promise to promote therapeutic approaches for cancer treatment. Presently, a diverse array of NPs with unique properties have been developed to overcome different challenges and to achieve sophisticated delivery routes for enhancement of a series of therapies. Inspiring advances have been achieved in the field of cancer therapy using NPs. In this review, we aim to summarize the up‐to‐date progression of NPs for addressing various challenges, and expect to elicit novel and potential opportunities alternatively. We first introduce different sorts of NP technologies, illustrate their mechanisms, and present their applications. Then, the achievements made by NPs to break obstacles in delivering cargoes to specific sites through particular routes are highlighted, including long‐circulation, tumor targeting, responsive release, and subcellular localization. We subsequently retrospect recent research of NPs in different cancer treatments from single therapy, like chemotherapy, to combination therapy, like chemoradiotherapy, and to integrative therapy. Finally, the challenges and perspectives of NPs in cancer therapy, and their potential impact on the field of oncology are discussed. We believe this review can offer a deeper understanding of the challenges and opportunities of NPs for cancer therapy.

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Section: Polymeric Npsmentioning

confidence: 99%

Section: Np Technologiesmentioning

confidence: 99%

Advances and applications of nanoparticles in cancer therapy

Huang,

He,

Liang

et al. 2024

MedComm – Oncology

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“…56 Different studies suggest that a modest negative surface charge appears to be favourable for circumvention of MPS clearance and improved blood compatibility, thereby extending blood circulation time and improving tumour delivery. 57,58 On the other hand, cationic nanocarriers were recently used for the improvement of tumour immunosurveillance 59 as well as, more specifically, the administration of cancer vaccines which preferentially target antigen presenting cells. 18 These findings were reflected by our in vitro system: whereas internalization of anionic MSN-COOH particles was still slightly higher in PC-3 vs. THP-1 cells, cationic MSN-NH 2 particles had a preference for THP-1 cells.…”

Section: Papermentioning

confidence: 99%

Towards a simple in vitro surface chemistry pre-screening method for nanoparticles to be used for drug delivery to solid tumours

Schmid

Kaiser²,

Willbold³

et al. 2023

Biomater. Sci.

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“…These include combinatorial therapy of vaccines with immune checkpoint inhibitors 10,11 and other chemo drugs, 12,13 neoantigen-based vaccine therapy, 14,15 and engineering novel adjuvants 16,17 or other delivery platforms for tumor antigens. [18][19][20] Recently there has been an interest in the delivery of antigens and other immunomodulatory molecules using engineered 3D scaffolds. [21][22][23] Biodegradable polymer scaffolds are a promising drug delivery platform for anticancer applications.…”

Section: Introductionmentioning

confidence: 99%

“…A number of strategies are being investigated to improve the T‐cell response to therapeutic cancer vaccines. These include combinatorial therapy of vaccines with immune checkpoint inhibitors 10,11 and other chemo drugs, 12,13 neoantigen‐based vaccine therapy, 14,15 and engineering novel adjuvants 16,17 or other delivery platforms for tumor antigens 18–20 . Recently there has been an interest in the delivery of antigens and other immunomodulatory molecules using engineered 3D scaffolds 21–23 .…”

Section: Introductionmentioning

confidence: 99%

Engineered polymer‐based scaffold as an implantable therapeutic vaccine against melanoma

Unnikrishnan,

Menon,

K. G.

et al. 2023

J of Applied Polymer Sci

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Although tumor‐antigen‐based therapeutic cancer vaccines are a potential cancer immunotherapy strategy, recent clinical trials show low efficacy for multiple reasons. One method that has been recently investigated to improve the efficacy of therapeutic cancer vaccines is the development of implantable vaccines for sustained delivery of antigens and CD8 T cell activation. Here, we optimized the composition for an implantable vaccine scaffold composed of alginate, polyvinyl alcohol, and poly(methyl vinyl ether‐ alt‐maleic anhydride) loaded with tumor antigens. Considering the adjuvant property of aluminum compounds, aluminum ion was used to crosslink alginate in the scaffold. The scaffold showed an effective antigen incorporation efficiency of 90.34 ± 0.55% using ovalbumin as the model antigen and 89.67 ± 2.8% using B16‐F10 cell lysate. SEM analysis of the scaffold showed pore size ranging from 5 to 10 μm. Cell viability analysis using mouse RAW 264.7 macrophages proved the cytocompatibility of the scaffold. In vitro antigen release studies using ovalbumin showed 8.42% release for a period of 14 days. In vivo antitumor analysis carried out in subcutaneous mouse B16‐F10 melanoma model demonstrated that the scaffold vaccine reduced the rate of tumor growth and improved survival in tested animals. The median survival time increased from 29 days in untreated animals to 58 days in scaffold vaccine‐implanted animals.

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Cationic nanoparticles enhance T cell tumor infiltration and antitumor immune responses to a melanoma vaccine

Cited by 23 publications

References 73 publications

Advances and applications of nanoparticles in cancer therapy

Advances and applications of nanoparticles in cancer therapy

Towards a simple in vitro surface chemistry pre-screening method for nanoparticles to be used for drug delivery to solid tumours

Engineered polymer‐based scaffold as an implantable therapeutic vaccine against melanoma

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