A Three-Dimensional Printable Hydrogel Formulation for the Local Delivery of Therapeutic Nanoparticles to Cervical Cancer

Kiseleva, Mariia; Omar, Mahmoud Mohamed; Boisselier, Élodie; Selivanova, Svetlana V.; Fortin, Marc‐André

doi:10.1021/acsbiomaterials.1c01399

Cited by 18 publications

(18 citation statements)

References 68 publications

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“…Another study found that the survival rate of Hela cells cultured with 30 mg-mL-1 SOLE/PEGDA decreased from 72.3% to 41.7% under NIR irradiation in poly(ethylene glycol) bisacrylate (PEGDA) composite hydrogels loaded with spinach extract (SOLE, a natural photosensitizer). It indicates that SOLE/PEGDA hydrogels are antitumor active in PDT treatment [57].…”

Section: Light-responsive Hydrogelsmentioning

confidence: 95%

Research progress and clinical application of stimuli-responsive hydrogels in cervical cancer

Zhang¹

2022

HSET

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Cervical cancer is the fourth most common malignancy in women worldwide and poses a great risk to women's health. There is an urgent need to develop a range of effective and innovative therapeutic options to overcome the shortcomings of conventional treatments: poor efficacy and toxic side effects. As an alternative therapy, a number of advances have been made in hydrogel-based drug delivery systems that enable targeted and localized therapy, as well as controlled release of drugs at the tumor site. These advantages can effectively increase drug concentration and reduce damage to normal sites caused by chemical drug toxicity. This paper reviews the progress of research applications of stimuli-responsive hydrogels in cervical cancer. The response mechanisms of hydrogels and the principles of enhanced drug efficacy are discussed in focus. These include thermal-responsive hydrogels, pH-responsive hydrogels, light-responsive hydrogels, enzyme-responsive hydrogels, and dual-responsive hydrogels. It is also argued that through the increasing understanding of hydrogels, it can be used clinically as an effective and durable therapeutic tool.

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Section: Light-responsive Hydrogelsmentioning

confidence: 95%

Research progress and clinical application of stimuli-responsive hydrogels in cervical cancer

Zhang¹

2022

HSET

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“…As with liposomes, hydrogels can also be thermoresponsive and be used for specific heat-triggered drug release. Such thermoresponsive gels undergo a sol-to-gel transition when heated to a specific temperature (i.e., low critical gelation temperature), leading to drug release [ 153 , 154 ]. Several studies investigated thermo- and non-thermoresponsive GNP–hydrogel hybrids for cancer therapy.…”

Section: Organic Gnp Nanohybrid Chemotherapeutic Platformsmentioning

confidence: 99%

“…Alginate-based thermosensitive hydrogels with GNPs were also studied for cancer therapy by Kiseleva et al, who used alginate combined with a thermosensitive polymer, PF127, to make thermoresponsive hydrogels for the encapsulation and release of GNPs. In this study, GNPs were used as the therapeutic agent to be released from the gel via gel dissolution and GNP diffusion without being triggered by heat [ 153 ]. Another alginate-based nanohybrid hosting both GNPs and iron oxide nanoparticles was studied for magnetically targeted drug delivery, PTT, and magnetic resonance imaging (MRI).…”

Section: Organic Gnp Nanohybrid Chemotherapeutic Platformsmentioning

confidence: 99%

Gold-Nanoparticle Hybrid Nanostructures for Multimodal Cancer Therapy

et al. 2022

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With the urgent need for bio-nanomaterials to improve the currently available cancer treatments, gold nanoparticle (GNP) hybrid nanostructures are rapidly rising as promising multimodal candidates for cancer therapy. Gold nanoparticles (GNPs) have been hybridized with several nanocarriers, including liposomes and polymers, to achieve chemotherapy, photothermal therapy, radiotherapy, and imaging using a single composite. The GNP nanohybrids used for targeted chemotherapy can be designed to respond to external stimuli such as heat or internal stimuli such as intratumoral pH. Despite their promise for multimodal cancer therapy, there are currently no reviews summarizing the current status of GNP nanohybrid use for cancer theragnostics. Therefore, this review fulfills this gap in the literature by providing a critical analysis of the data available on the use of GNP nanohybrids for cancer treatment with a specific focus on synergistic approaches (i.e., triggered drug release, photothermal therapy, and radiotherapy). It also highlights some of the challenges that hinder the clinical translation of GNP hybrid nanostructures from bench to bedside. Future studies that could expedite the clinical progress of GNPs, as well as the future possibility of improving GNP nanohybrids for cancer theragnostics, are also summarized.

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“…Although multiple 3D printing methods exist, extrusion‐based printing has been most widely adopted due to its simplistic working principle and ease of use. [ 3,4 ] Inks used in extrusion 3D printing mainly consist of chemically modified versions of gelatin, [ 5–12 ] alginate, [ 13–16 ] hyaluronic acid, [ 17–20 ] collagen, [ 1,21,22 ] decellularized extracellular matrix, [ 23–25 ] or combinations of these. [ 26–35 ] The traditional approach for developing 3D printable inks has been to chemically modify naturally‐derived hydrogel materials to make them more printable, while attempting to maintain their favorable biological properties.…”

Section: Introductionmentioning

confidence: 99%

“…Although multiple 3D printing methods exist, extrusion-based printing has been most widely adopted due to its simplistic working principle and ease of use. [3,4] Inks used in extrusion 3D printing mainly consist of chemically modified versions of gelatin, [5][6][7][8][9][10][11][12] alginate, [13][14][15][16] hyaluronic acid, [17][18][19][20] collagen, [1,21,22] decellularized extracellular matrix, [23][24][25] or combinations of these. [26][27][28][29][30][31][32][33][34][35] The traditional approach for developing 3D printable inks invented a fabrication method that included extrusion printing followed by spraying a salt gelling agent at each layer.…”

Section: Introductionmentioning

confidence: 99%

3D Printing of Self‐Assembling Nanofibrous Multidomain Peptide Hydrogels

et al. 2023

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has been to chemically modify naturallyderived hydrogel materials to make them more printable, while attempting to maintain their favorable biological properties. Recently, two generalizable strategies have been proposed to allow for the printing of a wide range of hydrogel materials, which both include a stabilization method to allow for short term print fidelity, followed by a crosslinking method to impart longterm stability. [36,37] Despite these advances, naturally derived materials suffer from batch to batch variability, frequently require chemical modification to have sufficient mechanical properties, and have predefined bioactivity. [38] A more favorable approach for the creation of new 3D printable inks is to design synthetic materials with specified mechanical, biological, and chemical properties. One class of materials that offers this design freedom is self-assembling peptides (SAPs). [39][40][41][42] SAPs are peptides that assemble into nanostructures due to the orchestration of well-designed supramolecular forces. These nanostructures can then interact in such a way to generate a macroscopic hydrogel. SAPs are easy to synthesize, chemically well-defined, purifiable, and offer design flexibility to achieve a wide range of material properties. In addition, their synthesis is inherently modular, and the properties of SAPs can be altered by simply changing their primary sequence or through the incorporation of bioactive peptide sequences. Because SAPs consist solely of amino acid building blocks, their chemistry and degradation products are biologically friendly, which is a common drawback of hydrogels made from other polymers. Thus, SAPs offer the flexibility of synthetic hydrogel materials, while also maintaining the biocompatibility of naturally derived ones.SAPs are an attractive soft material for extrusion 3D printing because they commonly have shear thinning and rapidly selfhealing properties due to their noncovalent assembly mechanism. [4,43] Despite this, there has been limited 3D printing work involving SAPs. The Hauser lab was the first to demonstrate the 3D printing of SAPs, using tetrapeptides and PBS in a coaxial printing system to create centimeter sized constructs and encapsulate cells. [44,45] Although this work presented multiple breakthroughs, limitations included the use of noncanonical amino acids and limited print fidelity and complexity. The other major work showing the extrusion 3D printing of SAPs, from the Stupp lab, demonstrated the shear alignment of nanofibers using a peptide amphiphile ink. [46] The authors 3D printing has become one of the primary fabrication strategies used in biomedical research. Recent efforts have focused on the 3D printing of hydrogels to create structures that better replicate the mechanical properties of biological tissues. These pose a unique challenge, as soft materials are difficult to pattern in three dimensions with high fidelity. Currently, a small number of biologically derived polymers that form hydrogels are frequently reused for 3D printing ...

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A Three-Dimensional Printable Hydrogel Formulation for the Local Delivery of Therapeutic Nanoparticles to Cervical Cancer

Cited by 18 publications

References 68 publications

Research progress and clinical application of stimuli-responsive hydrogels in cervical cancer

Research progress and clinical application of stimuli-responsive hydrogels in cervical cancer

Gold-Nanoparticle Hybrid Nanostructures for Multimodal Cancer Therapy

3D Printing of Self‐Assembling Nanofibrous Multidomain Peptide Hydrogels

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