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- Microneedle-based delivery devices for cancer therapy: a reviewPublication . Moreira, André; Rodrigues, Ana Carolina Félix; Jacinto, Telma A.; Miguel, Sónia; Costa, Elisabete; Correia, I.J.Macroscale delivery systems that can be locally implanted on the tumor tissue as well as avoid all the complications associated to the systemic delivery of therapeutics have captured researchers' attention, in recent years. Particularly, the microneedle-based devices can be used to efficiently deliver both small and macro-molecules, like chemotherapeutics, proteins, and genetic material, along with nanoparticle-based anticancer therapies. Such capacity prompted the application of microneedle devices for the development of new anticancer vaccines that can permeate the tumor tissue and simultaneously improve the effectiveness of therapeutic agents. Based on the promising results demonstrated by the microneedle systems in the local administration of anticancer therapeutics, this review summarizes the different microneedle formulations developed up to now aimed for application on cancer therapy (mphasizing those produced with polymers). Additionally, the microneedles' general properties, type of therapeutic approach and its main advantages are also highlighted.
- Hyaluronic acid and vitamin E polyethylene glycol succinate functionalized gold-core silica shell nanorods for cancer targeted photothermal therapyPublication . Jacinto, Telma A.; Rodrigues, Ana Carolina Félix; Moreira, André F.; Miguel, Sónia P.; Costa, Elisabete; Ferreira, Paula; Correia, I.J.Gold-core mesoporous silica shell (AuMSS) nanorods unique physicochemical properties makes them versatile and promising nanomedicines for cancer photothermal therapy. Nevertheless, these nanomaterials present a reduced half-life in the blood and poor specificity towards the tumor tissue. Herein, d-α-Tocopherol polyethylene glycol 1000 succinate (TPGS) and Hyaluronic Acid (HA) were combined for the first time to improve the AuMSS nanorods biological performance. The obtained results revealed that AuMSS surface functionalization induced the surface charge neutralization, from -28 ± 10 mV to −3 ± 5 mV and −10 ± 4 mV for AuMSS-TPGS-HA (1:1) and (4:1) formulations, without impacting on nanomaterials’ photothermal capacity. Moreover, the AuMSS functionalization improved the nanomaterials hemocompatibility and selectivity towards the cancer cells, particularly in the AuMSS-TPGS-HA (4:1) formulation. Furthermore, both formulations were able to mediate an on-demand photothermal effect, that induced the HeLa cancer cells death, confirming its potential for being applied as targeted multifunctional theragnostic nanomedicines.
- Poly (vinyl alcohol)/chitosan layer-by-layer microneedles for cancer chemo-photothermal therapyPublication . Moreira, André F.; Rodrigues, Ana Carolina Félix; Jacinto, Telma A.; Miguel, Sónia P.; Costa, Elisabete; Correia, I.J.The combination of photothermal and chemo- therapies displays a high potential to increase the efficacy of the cancer treatments or even promote their eradication. In this study, the micromoulding and electrospraying techniques were combined to produce polyvinylpyrrolidone microneedles coated with chitosan and poly (vinyl alcohol) for mediating the delivery of doxorubicin and AuMSS nanorods (Dox@MicroN) to cancer cells. The microneedles' physicochemical characterization demonstrated that the electrospraying technique can be used to produce a layer-by-layer coating consisting of layers of doxorubicin-loaded chitosan and AuMSS enriched poly (vinyl alcohol). Further, the Dox@MicroN patches presented a good photothermal capacity leading to a temperature increase of 12 °C under near-infrared irradiation (808 nm, 1.7 W/cm-2 for 5 min), which in conjugation with the chitosan' pH sensitivity could be used to control the doxorubicin release. Moreover, the microneedles were able to penetrate the tumor-mimicking agarose gel and promote a layer dependent drug release. Additionally, the Dox@MicroN patches' capacity to simultaneously mediate the chemo- and photothermal-therapies rendered a superior cytotoxic effect against the cervical cancer cells. Overall, the Dox@MicroN patches demonstrated to be a simple macroscale delivery device that can be used to mediate the local administration of new drug-photothermal combinations, avoiding all the issues related to the systemic administration of anti-cancer therapeutics.
- Injectable in situ forming thermo-responsive graphene based hydrogels for cancer chemo-photothermal therapy and NIR light-enhanced antibacterial applicationsPublication . Sousa, Rita Lima; Diogo, Duarte de Melo; Alves, Cátia; Cabral, Cátia S. D.; Miguel, Sónia P.; Mendonça, António; Correia, I.J.Functionalized graphene oxide (GO) and reduced GO (rGO) based nanomaterials hold a great potential for cancer photothermal therapy. However, their systemic administration has been associated with an accelerated blood clearance and/or with suboptimal tumor uptake. To address these limitations, the local delivery of GO/rGO to the tumor site by 3D matrices arises as a promising strategy. In this work, injectable chitosan-agarose in situ forming thermo-responsive hydrogels incorporating GO (thermogel-GO) or rGO (thermogel-rGO) were prepared for the first time. The hydrogels displayed suitable injectability and gelation time, as well as good physicochemical properties and cytocompatibility. When irradiated with near infrared (NIR) light, the thermogel-rGO produced a 3.8-times higher temperature increase than thermogel-GO, thus decreasing breast cancer cells' viability to 60%. By incorporating an optimized molar ratio of the Doxorubicin:Ibuprofen combination on thermogel-rGO, this formulation mediated a chemo-photothermal effect that further diminished cancer cells' viability to 34%. In addition, the hydrogels' antibacterial activity was further enhanced upon NIR laser irradiation, which is an important feature considering the possible risk of infection at the site of administration. Overall, thermogel-rGO is a promising injectable in situ forming hydrogel for combinatorial chemo-photothermal therapy of breast cancer cells and NIR light enhanced antibacterial applications.
- Functionalization of AuMSS nanorods towards more effective cancer therapiesPublication . Rodrigues, Ana Carolina Félix; Jacinto, Telma A.; Moreira, André; Costa, Elisabete C.; Miguel, Sónia P.; Correia, I.J.The application of nanoparticles as selective drug delivery platforms arises as one the most promising therapeutic strategies in the biomedical field. Such systems can encapsulate drugs, prevent its premature degradation, transport and promote the drugs specific delivery to the target site. Among the different nanostructures, gold-core mesoporous silica shell (AuMSS) nanorods have been one of the most explored due to their unique physical and chemical properties. The mesoporous silica biocompatibility, high surface area that can be easily functionalized, tubular pores that can store the drugs, conjugated with the intrinsic capacity of gold nanorod to absorb near-infrared radiation, allows the combination of hyperthermia (i.e., photothermal effect) with drug delivery, making them a nanoplatforms with a huge potential for cancer therapy. Nevertheless, the successful application of AuMSS nanoparticles as an effective cancer nanomedicine is hindered by the uncontrolled release of the therapeutic payloads, limited blood circulation time and unfavorable pharmacokinetics. In this review, an overview of the modifications performed to improve the AuMSS nanorods application in nanomedicine is provided, highlighting the practical approaches that enhanced the AuMSS nanorods targeting, responsiveness to different stimuli, and blood circulation time. Further, the basics of AuMSS nanorods synthesis procedures, general properties, and its application in cancer therapy are also described.