Your search keyword '"Diaz-Rodriguez, Patricia"' showing total 17 results

1. Harnessing extracellular vesicle membrane for gene therapy: EVs-biomimetic nanoparticles

Author

Briffault, Erik, Garcia-Garcia, Patricia, Martinez-Borrajo, Rebeca, Evora, Carmen, Delgado, Araceli, and Diaz-Rodriguez, Patricia

Published

2024

2. Screening strategies for surface modification of lipid-polymer hybrid nanoparticles

Author

Rouco, Helena, García-García, Patricia, Évora, Carmen, Díaz-Rodríguez, Patricia, and Delgado, Araceli

Published

2022

3. Targeting joint inflammation for osteoarthritis management through stimulus-sensitive hyaluronic acid based intra-articular hydrogels

Author

Diaz-Rodriguez, Patricia, Mariño, Cibrán, Vázquez, Jose Antonio, Caeiro-Rey, Jose Ramon, and Landin, Mariana

Published

2021

4. Amino-functionalized polymers by gamma radiation and their influence on macrophage polarization

Author

Pérez-Calixto, Mitzi, Diaz-Rodriguez, Patricia, Concheiro, Angel, Alvarez-Lorenzo, Carmen, and Burillo, Guillermina

Published

2020

5. New tools to design smart thermosensitive hydrogels for protein rectal delivery in IBD

Author

Garcia-del Rio, Lorena, Diaz-Rodriguez, Patricia, and Landin, Mariana

Published

2020

6. Anandamide-nanoformulation obtained by electrospraying for cardiovascular therapy

Author

Martín Giménez, Virna Margarita, Díaz-Rodríguez, Patricia, Sanz, Raúl Lelio, Vivero-Lopez, María, Concheiro, Angel, Diez, Emiliano, Prado, Natalia, Enrique Kassuha, Diego, Alvarez-Lorenzo, Carmen, and Manucha, Walter

Published

2019

7. Administration of the optimized β-Lapachone–poloxamer–cyclodextrin ternary system induces apoptosis, DNA damage and reduces tumor growth in a human breast adenocarcinoma xenograft mouse model

Author

Seoane, Samuel, Díaz-Rodríguez, Patricia, Sendon-Lago, Juan, Gallego, Rosalia, Pérez-Fernández, Román, and Landin, Mariana

Published

2013

8. Evaluation of human umbilical vein endothelial cells growth onto heparin-modified electrospun vascular grafts.

Author

Caracciolo, Pablo C., Diaz-Rodriguez, Patricia, Ardao, Inés, Moreira, David, Montini-Ballarin, Florencia, Abraham, Gustavo A., Concheiro, Angel, and Alvarez-Lorenzo, Carmen

Subjects

*VASCULAR grafts, *UMBILICAL veins, *ENDOTHELIAL cells, *CELL growth, *AUTOTRANSPLANTATION

Abstract

One of the main challenges of cardiovascular tissue engineering is the development of bioresorbable and compliant small-diameter vascular grafts (SDVG) for patients where autologous grafts are not an option. In this work, electrospun bilayered bioresorbable SDVG based on blends of poly(L-lactic acid) (PLLA) and segmented polyurethane (PHD) were prepared and evaluated. The inner layer of these SDVG was surface-modified with heparin, following a methodology involving PHD urethane functional groups. Heparin was selected as anticoagulant agent, and also due to its ability to promote human umbilical vein endothelial cells (HUVECs) growth and to inhibit smooth muscle cells over-proliferation, main cause of neointimal hyperplasia and restenosis. Immobilized heparin was quantified and changes in SDVG microstructure were investigated through SEM. Tensile properties of the heparin-functionalized SDVG resembled those of saphenous vein. Vascular grafts were seeded with HUVECs and cultured on a flow-perfusion bioreactor to analyze the effect of heparin on graft endothelization under simulated physiological-like conditions. The analysis of endothelial cells attachment and gene expression (Real-Time PCR) pointed out that the surface functionalization with heparin successfully promoted a stable and functional endothelial cell layer. [ABSTRACT FROM AUTHOR]

Published

2021

9. Design of novel orotransmucosal vaccine-delivery platforms using artificial intelligence.

Author

Garcia-del Rio, Lorena, Diaz-Rodriguez, Patricia, and Landin, Mariana

Subjects

*ARTIFICIAL intelligence, *MUCOUS membranes, *TEMPERATURE control, *HYDROGELS, *MOUTH

Abstract

The linings of the oral cavity are excellent needle-free vaccination sites, able to induce immune responses at distal sites and confer systemic protection. However, owing to the mucosal tissues' intrinsic characteristics, the design of effective antigen-delivery systems is not an easy task. In the present work, we propose to develop and characterize thermosensitive and mucoadhesive hydrogels for orotransmucosal vaccination taking advantage of artificial intelligence tools (AIT). Hydrogels of variable composition were obtained combining Pluronic® F127 (PF127), Hybrane® S1200 (HS1200) and Gantrez® AN119 (AN119) or S97 (S97). Systems were characterized in terms of physicochemical properties, adhesion capacity to mucosal tissues and antigen-like microspheres release. Additionally, polymers biocompatibility and their immune-stimulation capacity was assessed in human macrophages. Interestingly, cells treated with HS1200 exhibited a significant proliferation enhancement compared to control. The use of AIT allowed to determine the effect of each polymer on formulations properties. The proportions of PF127 and Gantrez® are mainly the factors controlling gelation temperature, mucoadhesion, adhesion work and gel strength. Meanwhile, cohesion and short-term microsphere release are dependent on the PF127 concentration. However, long-term microsphere release varies depending on the Gantrez® variety and the PF127 concentration used. Hydrogels prepared with S97 showed slower microsphere release. The use of AIT allowed to establish the conditions able to produce ternary hydrogels with immune-stimulatory properties together with adequate mucoadhesion capacity and antigen-like microspheres release. [ABSTRACT FROM AUTHOR]

Published

2021

10. Influence of the carbon source on the properties of poly-(3)-hydroxybutyrate produced by Paraburkholderia xenovorans LB400 and its electrospun fibers.

Author

Sanhueza, Claudia, Diaz-Rodriguez, Patricia, Villegas, Pamela, González, Ángela, Seeger, Michael, Suárez-González, Javier, Concheiro, Angel, Alvarez-Lorenzo, Carmen, and Acevedo, Francisca

Subjects

*POLYHYDROXYBUTYRATE, *3-Hydroxybutyric acid, *BUTYRATES, *MOLECULAR weights, *CARBON, *CELL growth, *FIBERS, *SUGAR

Abstract

Poly-3-hydroxybutyrate (PHB) is a biocompatible polymer produced by a wide variety of bacteria from different carbon sources. However, the carbon source effects on PHB properties are largely unknown. This study aimed to characterize PHB produced by Paraburkholderia xenovorans LB400 supplied with glucose (PHB g), mannitol (PHB m), or xylose (PHB x) as sole carbon sources and to evaluate their potential application as the main component of scaffolds obtained by electrospinning. The PHBs produced by strain LB400 had different molecular weights; the largest value corresponded to PHB m. The XRD-spectra revealed that PHB produced by strain LB400 from the three carbon sources are less crystalline than the commercially available polymer (PHB c). Moreover, the electrospinning process decreases even further their degree of crystallinity, which could lead to an improvement in the mechanical properties of the polymers. Relevantly, PHB x -microfibers exhibited mechanical characteristics similar to those of human skin. None of the scaffolds made of PHBs from strain LB400 grown in different carbon sources showed adverse effects on fibroblast cell growth. Thus, modifying the sugar used as the carbon source may be useful to tune the structural properties of PHB and its performance as a component of electrospun scaffolds, which may better fit specific biomedical applications. [ABSTRACT FROM AUTHOR]

Published

2020

11. Incorporation of a silicon-based polymer to PEG-DA templated hydrogel scaffolds for bioactivity and osteoinductivity.

Author

Frassica, Michael T., Jones, Sarah K., Diaz-Rodriguez, Patricia, Hahn, Mariah S., and Grunlan, Melissa A.

Subjects

HYDROGELS, POLYETHYLENE glycol, MACROPOROUS polymers, HUMAN cell culture, MESENCHYMAL stem cells, POLYMERS, FUSED salts, ETHYLENE glycol

Abstract

A scaffold that is inherently bioactive, osteoinductive and osteoconductive may guide mesenchymal stem cells (MSCs) to regenerate bone tissue in the absence of exogenous growth factors. Previously, we established that hydrogel scaffolds formed by crosslinking methacrylated star poly(dimethylsiloxane) (PDMS star -MA) with diacrylated poly(ethylene glycol) (PEG-DA) promote bone bonding by induction of hydroxyapatite formation ("bioactive") and promote MSC lineage progression toward osteoblast-like fate ("osteoinductive"). Herein, we have combined solvent induced phase separation (SIPS) with a fused salt template to create PDMS star -PEG hydrogel scaffolds with controlled PDMS star -MA distribution as well as interconnected macropores of a tunable size to allow for subsequent cell seeding and neotissue infiltration ("osteoconductive"). Scaffolds were prepared with PDMS star -MA of two number average molecular weights (M n s) (2k and 7k) with varying PDMS star -MA:PEG-DA ratios and template salt sizes. The distribution of PDMS star -MA within the hydrogels was examined as well as pore size, percent interconnectivity, dynamic and static moduli, hydration, degradation and in vitro bioactivity (i.e. mineralization when exposed to simulated body fluid, SBF). Finally, cell culture with seeded human bone marrow-derived MSCs (hBMSCs) was used to confirm non-cytotoxicity and characterize osteoinductivity. Tunable, interconnected macropores were achieved by utilization of a fused salt template of a specified salt size during fabrication. Distribution of PDMS star -MA within the PEG-DA matrix improved for the lower M n and contributed to differences in specific material properties (e.g. local modulus) and cellular response. However, all templated SIPS PDMS star -PEG hydrogels were confirmed to be bioactive, non-cytotoxic and displayed PDMS star -MA dose-dependent osteogenesis. A tissue engineering scaffold that can inherently guide mesenchymal stem cells (MSCs) to regenerate bone tissue without growth factors would be a more cost-effective and safe strategy for bone repair. Typically, glass/ceramic fillers are utilized to achieve this through their ability to induce hydroxyapatite formation ("bioactive") and promote MSC differentiation to an osteoblast-like fate ("osteoinductive"). Herein, we have fabricated an interconnected, macroporous PEG-DA hydrogel scaffold that utilizes PDMS star -MA as a bioactive and osteoinductive scaffold component. We were able to show that these PDMS star -PEG hydrogels maintain several key material characteristics for bone repair. Further, bioactivity and osteoinductivity were simultaneously achieved in human bone marrow-derived MSC culture, representing a notable achievement for an exclusively material-based strategy. [ABSTRACT FROM AUTHOR]

Published

2019

12. Elucidating the role of graft compliance mismatch on intimal hyperplasia using an ex vivo organ culture model.

Author

Post, Allison, Diaz-Rodriguez, Patricia, Balouch, Bailey, Paulsen, Samantha, Wu, Siliang, Miller, Jordan, Hahn, Mariah, and Cosgriff-Hernandez, Elizabeth

Subjects

ORGAN culture, VASCULAR grafts, SHEAR flow, HYPERPLASIA, LEGAL compliance

Abstract

Graphical abstract Abstract There is a growing clinical need to address high failure rates of small diameter (<6 mm) synthetic vascular grafts. Although there is a strong empirical correlation between low patency rates and low compliance of synthetic grafts, the mechanism by which compliance mismatch leads to intimal hyperplasia is poorly understood. To elucidate this relationship, synthetic vascular grafts were fabricated that varied compliance independent of other graft variables. A computational model was then used to estimate changes in fluid flow and wall shear stress as a function of graft compliance. The effect of compliance on arterial remodeling in an ex vivo organ culture model was then examined to identify early markers of intimal hyperplasia. The computational model prediction of low wall shear stress of low compliance grafts and clinical control correlated well with alterations in arterial smooth muscle cell marker, extracellular matrix, and inflammatory marker staining patterns at the distal anastomoses. Conversely, high compliance grafts displayed minimal changes in fluid flow and arterial remodeling, similar to the sham control. Overall, this work supports the intrinsic link between compliance mismatch and intimal hyperplasia and highlights the utility of this ex vivo organ culture model for rapid screening of small diameter vascular grafts. Statement of Significance We present an ex vivo organ culture model as a means to screen vascular grafts for early markers of intimal hyperplasia, a leading cause of small diameter vascular graft failure. Furthermore, a computational model was used to predict the effect of graft compliance on wall shear stress and then correlate these values to changes in arterial remodeling in the organ culture model. Combined, the ex vivo bioreactor system and computational model provide insight into the mechanistic relationship between graft-arterial compliance mismatch and the onset of intimal hyperplasia. [ABSTRACT FROM AUTHOR]

Published

2019

13. Refined assessment of the impact of cell shape on human mesenchymal stem cell differentiation in 3D contexts.

Author

Jimenez-Vergara, Andrea C., Zurita, Rodrigo, Jones, Abigail, Diaz-Rodriguez, Patricia, Qu, Xin, Kusima, Kenneth L., Hahn, Mariah S., and Munoz-Pinto, Dany J.

Subjects

MESENCHYMAL stem cell differentiation, CELL morphology, HUMAN stem cells, POLYMER networks, TISSUE scaffolds, MESENCHYMAL stem cells

Abstract

Graphical abstract Abstract Numerous studies have demonstrated that the differentiation potential of human mesenchymal stem cells (hMSCs) can be modulated by chemical and physical cues. In 2D contexts, inducing different cell morphologies, by varying the shape, area and/or curvature of adhesive islands on patterned surfaces, has significant effects on hMSC multipotency and the onset of differentiation. In contrast, in vitro studies in 3D contexts have suggested that hMSC differentiation does not directly correlate with cell shape. However, in 3D, the effects of cell morphology on hMSC differentiation have not yet been clearly established due to the chemical and physical properties being intertwined in 3D matrices. In this work, we studied the effects of round or elongated cell morphologies on hMSC differentiation independently of scaffold composition, modulus, crosslink density and cell-mediated matrix remodeling. The effects of cell shape on hMSC lineage progression were studied using three different cell culture media compositions and two values of scaffold rigidity. Differences in cell shape were achieved using interpenetrating polymer networks (IPNs). The mechanical and diffusional properties of the scaffolds and cell-matrix interactions were characterized. In addition, cell responses were evaluated in terms of cell spreading via gene and protein expression of differentiation markers. Cumulative results support, and extend upon previous work indicating that cell shape alone in 3D contexts does not significantly modulate hMSC differentiation, at least for the scaffold chemistry, range of modulus and culture conditions explored in this study. Statement of Significance In 2D contexts, inducing different cell shapes, by varying the curvature, area size and shape of a patterned surface, has significant effects on hMSC multipotency and the onset of cell differentiation. In contrast, in vitro studies in 3D contexts have suggested that hMSC differentiation does not directly correlate with cell shape. However, in 3D, the effects of cell morphology on hMSC differentiation have not yet been clearly established due to the chemical and physical properties being intertwined in 3D matrices. In this work, we studied the effects of round or elongated cell morphologies on the differentiation of hMSCs independently of scaffold composition, modulus, crosslink density and cell mediated matrix remodeling. Cumulative results support, and extend upon previous work indicating that cell shape alone in 3D contexts does not significantly modulate hMSCs differentiation commitment. [ABSTRACT FROM AUTHOR]

Published

2019

14. Delimiting the knowledge space and the design space of nanostructured lipid carriers through Artificial Intelligence tools.

Author

Rouco, Helena, Diaz-Rodriguez, Patricia, Rama-Molinos, Santiago, Remuñán-López, Carmen, and Landin, Mariana

Subjects

*LIPIDS, *ARTIFICIAL intelligence, *BIOCOMPATIBILITY, *CONTROLLED release drugs, *ZETA potential

Abstract

Graphical abstract Abstract Nanostructured lipid carriers (NLC) are biocompatible and biodegradable nanoscale systems with extensive application for controlled drug release. However, the development of optimal nanosystems along with a reproducible manufacturing process is still challenging. In this study, a two-step experimental design was performed and databases were successfully modelled using Artificial Intelligence techniques as an innovative method to get optimal, reproducible and stable NLC. The initial approach, including a wide range of values for the different variables, was followed by a second set of experiments with variable values in a narrower range, more suited to the characteristics of the system. NLC loaded with rifabutin, a hydrophobic drug model, were produced by hot homogenization and fully characterized in terms of particle size, size distribution, zeta potential, encapsulation efficiency and drug loading. The use of Artificial Intelligence tools has allowed to elucidate the key parameters that modulate each formulation property. Stable nanoparticles with low sizes and polydispersions, negative zeta potentials and high drug loadings were obtained when the proportion of lipid components, drug, surfactants and stirring speed were optimized by FormRules® and INForm®. The successful application of Artificial Intelligence tools on NLC formulation optimization constitutes a pioneer approach in the field of lipid nanoparticles. [ABSTRACT FROM AUTHOR]

Published

2018

15. Introduction of sacrificial bonds to hydrogels to increase defect tolerance during suturing of multilayer vascular grafts.

Author

Post, Allison, Kishan, Alysha P., Diaz-Rodriguez, Patricia, Tuzun, Egemen, Hahn, Mariah, and Cosgriff-Hernandez, Elizabeth

Subjects

SUTURING, HYDROGELS, VASCULAR grafts, CORONARY artery bypass, POLYURETHANES

Abstract

Small-caliber vascular grafts used in coronary artery bypass procedures typically fail due to the development of intimal hyperplasia or thrombosis. Our laboratory has developed a multilayered vascular graft with an electrospun polyurethane outer layer with improved compliance matching and a hydrogel inner layer that is both thromboresistant and promotes endothelialization. Initial in vivo studies showed that hydrogel particulates were dislodged from the hydrogel layer of the grafts during suturing. To address this problem, we developed and characterized a new hydrogel formulation that resists damage during suturing. Introduction of sacrificial, hydrogen bonds to poly(ethylene glycol)-based hydrogels via co-polymerization with n -vinyl pyrrolidone (NVP) increased the fracture energy as determined by single edge notch testing. This enhanced defect tolerance resulted in a hydrogel layer that was resistant to suture-induced damage with no dislodged particles observed. Importantly, the incorporation of NVP did not affect the thromboresistance, bioactivity, or biostability of the hydrogel layer. In addition to eliminating complications due to hydrogel particle generation in our multilayer graft design, this defect tolerant hydrogel formulation has broad potential use in many cardiovascular and soft tissue applications. Statement of Significance Small-caliber vascular grafts used in coronary artery bypass procedures typically fail due to development of intimal hyperplasia or thrombosis. Our laboratory has developed a multilayered vascular graft with an electrospun polyurethane outer layer with improved compliance matching and a hydrogel inner layer that is both thromboresistant and promotes endothelialization. However, hydrogel particulates were dislodged from the hydrogel layer during suturing in vivo . This work describes a hydrogel formulation based on poly(ethylene glycol) that is resistant to suture-induced damage. The introduction of sacrificial, hydrogen bonds by co-polymerization with n -vinyl pyrrolidone (NVP) resulted in an increase fracture energy without affecting the thromboresistance, bioactivity, or biostability. This defect-tolerant hydrogel formulation and the methodology to assess hydrogel defect tolerance has broad potential use in cardiovascular and soft tissue applications. [ABSTRACT FROM AUTHOR]

Published

2018

16. Fighting antibiotic resistance in the local management of bovine mastitis.

Author

Touza-Otero, Lara, Landin, Mariana, and Diaz-Rodriguez, Patricia

Subjects

*BOVINE mastitis, *DRUG resistance in bacteria, *BIOMIMETICS, *BACTERIAL adhesion, *DRUG delivery systems

Abstract

Bovine mastitis is a widespread infectious disease with a significant economic burden, accounting for 80 % of the antibiotic usage in dairy animals. In recent years, extensive research has focused on using biomimetic approaches such as probiotics, bacteriocins, bacteriophages, or phytochemicals as potential alternatives to antibiotics. The local administration of therapeutic molecules through the intramammary route is one of the most commonly strategies to manage bovine mastitis. This review highlights the most important findings in this field and discusses their local application in mastitis therapy. In contrast to antibiotics, the proposed alternatives are not limited to promote bacterial death but consider other factors associated to the host microenvironments. To this end, the proposed biomimetic strategies can modulate different stages of infection by modifying the local microbiota, preventing oxidative stress, reducing bacterial adhesion to epithelial cells, modulating the immune response, or mediating the inflammatory process. Numerous in vitro studies support the antimicrobial, antibiofilm or antioxidant properties of these alternatives. However, in vivo studies incorporating these components within pharmaceutical formulations with potential clinical application are limited. The development of secure, stable, and effective drug delivery systems based on the proposed options is necessary to achieve real alternatives to antibiotics in the clinic. [Display omitted] • Non-antibiotic strategies are being considered in bovine mastitis to reduce resistance. • Probiotics, bacteriocins, phytochemicals and bacteriophages are the most studied. • In vivo testing in bovine hosts is limited, hindering their progress to the clinic. • Intramammary pharmaceutical formulations including them need to be developed. [ABSTRACT FROM AUTHOR]

Published

2024

17. Micelle-nanogel platform for ferulic acid ocular delivery.

Author

Grimaudo, Maria Aurora, Amato, Giovanni, Carbone, Claudia, Diaz-Rodriguez, Patricia, Musumeci, Teresa, Concheiro, Angel, Alvarez-Lorenzo, Carmen, and Puglisi, Giovanni

Subjects

*FERULIC acid, *ZETA potential, *WOUND healing, *MICELLAR solutions, *DRUG solubility, *MICELLES, *HYALURONIC acid, *CORNEA

Abstract

Corneal wound healing after a trauma or a chemical injury has been shown to correlate with antioxidant levels at the ocular surface. However, ocular bioavailability of efficient antioxidants (e.g. ferulic acid) after topical administration is limited by their poor solubility, low stability and short residence time. The aim of this work was to formulate ferulic acid in a nanocomposite platform composed of nanogels and micelles for efficient delivery to cornea. Solubility enhancement factor of ferulic acid was found to be equal to 1.9 ± 0.3 and 3.4 ± 0.3 for 50 and 100 mg/ml Pluronic® F68 micellar solutions. Hyaluronan was added to blank and ferulic acid loaded micelles, and then cross-linked with ε-polylysine. Hyaluronan nanogels showed dimensions of ~300 nm with positive zeta potential values. The formulations were characterized in terms of rheological behavior, biocompatibility, wound healing properties, ferulic acid release pattern and penetration into excised bovine corneas. In comparison to Pluronic® micelles that released ferulic acid rapidly, micelle-nanogel composites sustained the release up to 2 days. Furthermore, the micelle-nanogel formulation favored in vitro wound closure promoting fibroblasts growth and ex vivo accumulation of ferulic acid into both healthy and damaged corneas (>100 µg/cm2). [ABSTRACT FROM AUTHOR]

Published

2020