Your search keyword '"Bottino, Marco C."' showing total 10 results

1. Natural monoterpenes-laden electrospun fibrous scaffolds for endodontic infection eradication

Author

de Souza Araújo, Isaac J., Patel, Tamannaben, Bukhari, Amal, Sanz, Carolina K., Fenno, J. Christopher, Ribeiro, Juliana S., and Bottino, Marco C.

Published

2023

2. Biodegradable electrospun poly(L‐lactide‐co‐ε‐caprolactone)/polyethylene glycol/bioactive glass composite scaffold for bone tissue engineering.

Author

de Souza, Joyce R., Cardoso, Lais M., de Toledo, Priscila T. A., Rahimnejad, Maedeh, Kito, Letícia T., Thim, Gilmar P., Campos, Tiago M. B., Borges, Alexandre L. S., and Bottino, Marco C.

Subjects

TISSUE scaffolds, TISSUE engineering, BIOACTIVE glasses, GLASS composites, ETHYLENE glycol

Abstract

The field of tissue engineering has witnessed significant advancements in recent years, driven by the pursuit of innovative solutions to address the challenges of bone regeneration. In this study, we developed an electrospun composite scaffold for bone tissue engineering. The composite scaffold is made of a blend of poly(L‐lactide‐co‐ε‐caprolactone) (PLCL) and polyethylene glycol (PEG), with the incorporation of calcined and lyophilized silicate‐chlorinated bioactive glass (BG) particles. Our investigation involved a comprehensive characterization of the scaffold's physical, chemical, and mechanical properties, alongside an evaluation of its biological efficacy employing alveolar bone‐derived mesenchymal stem cells. The incorporation of PEG and BG resulted in elevated swelling ratios, consequently enhancing hydrophilicity. Thermal gravimetric analysis confirmed the efficient incorporation of BG, with the scaffolds demonstrating thermal stability up to 250°C. Mechanical testing revealed enhanced tensile strength and Young's modulus in the presence of BG; however, the elongation at break decreased. Cell viability assays demonstrated improved cytocompatibility, especially in the PLCL/PEG+BG group. Alizarin red staining indicated enhanced osteoinductive potential, and fluorescence analysis confirmed increased cell adhesion in the PLCL/PEG+BG group. Our findings suggest that the PLCL/PEG/BG composite scaffold holds promise as an advanced biomaterial for bone tissue engineering. [ABSTRACT FROM AUTHOR]

Published

2024

3. The role of nanohydroxyapatite on the morphological, physical, and biological properties of chitosan nanofibers

Author

Sato, Tabata P., Rodrigues, Bruno V. M., Mello, Daphne C. R., Münchow, Eliseu A., Ribeiro, Juliana S., Machado, João Paulo B., Vasconcellos, Luana M. R., Lobo, Anderson O., Bottino, Marco C., and Borges, Alexandre L. S.

Published

2021

4. Functionalization of PCL-Based Fiber Scaffolds with Different Sources of Calcium and Phosphate and Odontogenic Potential on Human Dental Pulp Cells.

Author

Anselmi, Caroline, Mendes Soares, Igor Paulino, Mota, Rafaella Lara Maia, Leite, Maria Luísa, Ribeiro, Rafael Antonio de Oliveira, Fernandes, Lídia de Oliveira, Bottino, Marco C., de Souza Costa, Carlos Alberto, and Hebling, Josimeri

Subjects

DENTAL pulp, CALCIUM phosphate, POLYCAPROLACTONE, CALCIUM hydroxide, GENE expression, FIBERS, CELL adhesion, BIOACTIVE glasses

Abstract

This study investigated the incorporation of sources of calcium, phosphate, or both into electrospun scaffolds and evaluated their bioactivity on human dental pulp cells (HDPCs). Additionally, scaffolds incorporated with calcium hydroxide (CH) were characterized for degradation, calcium release, and odontogenic differentiation by HDPCs. Polycaprolactone (PCL) was electrospun with or without 0.5% w/v of calcium hydroxide (PCL + CH), nano-hydroxyapatite (PCL + nHA), or β-glycerophosphate (PCL + βGP). SEM/EDS analysis confirmed fibrillar morphology and particle incorporation. HDPCs were cultured on the scaffolds to assess cell viability, adhesion, spreading, and mineralized matrix formation. PCL + CH was also evaluated for gene expression of odontogenic markers (RT-qPCR). Data were submitted to ANOVA and Student's t-test (α = 5%). Added CH increased fiber diameter and interfibrillar spacing, whereas βGP decreased both. PCL + CH and PCL + nHA improved HDPC viability, adhesion, and proliferation. Mineralization was increased eightfold with PCL + CH. Scaffolds containing CH gradually degraded over six months, with calcium release within the first 140 days. CH incorporation upregulated DSPP and DMP1 expression after 7 and 14 days. In conclusion, CH- and nHA-laden PCL fiber scaffolds were cytocompatible and promoted HDPC adhesion, proliferation, and mineralized matrix deposition. PCL + CH scaffolds exhibit a slow degradation profile, providing sustained calcium release and stimulating HDPCs to upregulate odontogenesis marker genes. [ABSTRACT FROM AUTHOR]

Published

2024

5. Current and Future Views on Biomaterial Use in Regenerative Endodontics

Author

Münchow, Eliseu A., Bottino, Marco C., Duncan, Henry F., editor, and Cooper, Paul Roy, editor

Published

2019

6. Unveiling the potential of melt electrowriting in regenerative dental medicine.

Author

Daghrery, Arwa, de Souza Araújo, Isaac J., Castilho, Miguel, Malda, Jos, and Bottino, Marco C.

Subjects

REGENERATIVE medicine, DENTISTRY, BIOPRINTING, TISSUE mechanics, CELL determination, TISSUE scaffolds, GUIDED tissue regeneration

Abstract

For nearly three decades, tissue engineering strategies have been leveraged to devise effective therapeutics for dental, oral, and craniofacial (DOC) regenerative medicine and treat permanent deformities caused by many debilitating health conditions. In this regard, additive manufacturing (AM) allows the fabrication of personalized scaffolds that have the potential to recapitulate native tissue morphology and biomechanics through the utilization of several 3D printing techniques. Among these, melt electrowriting (MEW) is a versatile direct electrowriting process that permits the development of well-organized fibrous constructs with fiber resolutions ranging from micron to nanoscale. Indeed, MEW offers great prospects for the fabrication of scaffolds mimicking tissue specificity, healthy and pathophysiological microenvironments, personalized multi-scale transitions, and functional interfaces for tissue regeneration in medicine and dentistry. Excitingly, recent work has demonstrated the potential of converging MEW with other AM technologies and/or cell-laden scaffold fabrication (bioprinting) as a favorable route to overcome some of the limitations of MEW for DOC tissue regeneration. In particular, such convergency fabrication strategy has opened great promise in terms of supporting multi-tissue compartmentalization and predetermined cell commitment. In this review, we offer a critical appraisal on the latest advances in MEW and its convergence with other biofabrication technologies for DOC tissue regeneration. We first present the engineering principles of MEW and the most relevant design aspects for transition from flat to more anatomically relevant 3D structures while printing highly-ordered constructs. Secondly, we provide a thorough assessment of contemporary achievements using MEW scaffolds to study and guide soft and hard tissue regeneration, and draw a parallel on how to extrapolate proven concepts for applications in DOC tissue regeneration. Finally, we offer a combined engineering/clinical perspective on the fabrication of hierarchically organized MEW scaffold architectures and the future translational potential of site-specific, single-step scaffold fabrication to address tissue and tissue interfaces in dental, oral, and craniofacial regenerative medicine. Melt electrowriting (MEW) techniques can further replicate the complexity of native tissues and could be the foundation for novel personalized (defect-specific) and tissue-specific clinical approaches in regenerative dental medicine. This work presents a unique perspective on how MEW has been translated towards the application of highly-ordered personalized multi-scale and functional interfaces for tissue regeneration, targeting the transition from flat to anatomically-relevant three-dimensional structures. Furthermore, we address the value of convergence of biofabrication technologies to overcome the traditional manufacturing limitations provided by multi-tissue complexity. Taken together, this work offers abundant engineering and clinical perspectives on the fabrication of hierarchically MEW architectures aiming towards site-specific implants to address complex tissue damage in regenerative dental medicine. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

7. Recent advances in the development of GTR/GBR membranes for periodontal regeneration—A materials perspective

Author

Bottino, Marco C., Thomas, Vinoy, Schmidt, Gudrun, Vohra, Yogesh K., Chu, Tien-Min Gabriel, Kowolik, Michael J., and Janowski, Gregg M.

Subjects

*GUIDED tissue regeneration, *GUIDED bone regeneration, *REGENERATION (Biology), *PERIODONTITIS, *INFLAMMATION, *CURETTAGE, *DEBRIDEMENT

Abstract

Abstract: Periodontitis is a major chronic inflammatory disorder that can lead to the destruction of the periodontal tissues and, ultimately, tooth loss. To date, flap debridement and/or flap curettage and periodontal regenerative therapy with membranes and bone grafting materials have been employed with distinct levels of clinical success. Current resorbable and non-resorbable membranes act as a physical barrier to avoid connective and epithelial tissue down-growth into the defect, favoring the regeneration of periodontal tissues. These conventional membranes possess many structural, mechanical, and bio-functional limitations and the “ideal” membrane for use in periodontal regenerative therapy has yet to be developed. Based on a graded-biomaterials approach, we have hypothesized that the next-generation of guided tissue and guided bone regeneration (GTR/GBR) membranes for periodontal tissue engineering will be a biologically active, spatially designed and functionally graded nanofibrous biomaterial that closely mimics the native extra-cellular matrix (ECM). Objective: This review is presented in three major parts, including (1) a brief overview of the periodontium and its pathological conditions, (2) currently employed therapeutics used to regenerate the distinct periodontal tissues, and (3) a review of commercially available GTR/GBR membranes as well as the recent advances on the processing and characterization of GTR/GBR membranes from a materials perspective. Significance: Studies of spatially designed and functionally graded membranes (FGM) and in vitro antibacterial/cell-related research are addressed. Finally, as a future outlook, the use of hydrogels in combination with scaffold materials is highlighted as a promising approach for periodontal tissue engineering. [Copyright &y& Elsevier]

Published

2012

8. Photocrosslinkable methacrylated gelatin hydrogel as a cell-friendly injectable delivery system for chlorhexidine in regenerative endodontics.

Author

Ribeiro, Juliana S., Sanz, Carolina K., Münchow, Eliseu A., Kalra, Nikhil, Dubey, Nileshkumar, Suárez, Carlos Enrique C., Fenno, J. Christopher, Lund, Rafael G., and Bottino, Marco C.

Subjects

*REGENERATION (Biology), *HYDROGELS, *CHLORHEXIDINE, *GELATIN, *ENDODONTICS, *METHACRYLATES

Abstract

This work sought to formulate photocrosslinkable chlorhexidine (CHX)-laden methacrylated gelatin (CHX/GelMA) hydrogels with broad spectrum of action against endodontic pathogens as a clinically viable cell-friendly disinfection therapy prior to regenerative endodontics procedures. CHX/GelMA hydrogel formulations were successfully synthesized using CHX concentrations between 0.12 % and 5 % w/v. Hydrogel microstructure was evaluated by scanning electron microscopy (SEM). Swelling and enzymatic degradation were assessed to determine microenvironmental effects. Compression test was performed to investigate the influence of CHX incorporation on the hydrogels' biomechanics. The antimicrobial and anti-biofilm potential of the formulated hydrogels were assessed using agar diffusion assays and a microcosms biofilm model, respectively. The cytocompatibility was evaluated by exposing stem cells from human exfoliated deciduous teeth (SHEDs) to hydrogel extracts (i.e. , leachable byproducts obtained from overtime hydrogel incubation in phosphate buffer saline). The data were analyzed using One- and Two-way ANOVA and Tukey's test (α = 0.05). CHX/GelMA hydrogels were effectively prepared. NMR spectroscopy confirmed the incorporation of CHX into GelMA. The addition of CHX did not change the micromorphology (pore size) nor the swelling profile (p > 0.05). CHX incorporation reduced the degradation rate of the hydrogels (p < 0.001); whereas, it contributed to increased compressive modulus (p < 0.05). Regarding the antimicrobial properties, the incorporation of CHX showed a statistically significant decrease in the number of bacteria colonies at 0.12 % and 0.5 % concentration (p < 0.001) and completely inhibited the growth of biofilm at concentration levels 1 %, 2 %, and 5 %. Meanwhile, the addition of CHX, regardless of the concentration, did not lead to cell toxicity, as cell viability values were above 70 %. The addition of CHX into GelMA showed significant antimicrobial action against the pathogens tested, even at low concentrations, with the potential to be used as a cell-friendly injectable drug delivery system for root canal disinfection prior to regenerative endodontics. [Display omitted] • Chlorhexidine-laden gelatin methacrylate hydrogel (CHX/GelMA) was synthesized. • CHX/GelMA showed significant antimicrobial action against endodontic pathogens. • CHX/GelMA holds potential for infection eradication prior to regenerative procedures. [ABSTRACT FROM AUTHOR]

Published

2022

9. Effects of ciprofloxacin-containing antimicrobial scaffolds on dental pulp stem cell viability—In vitro studies.

Author

Kamocki, Krzysztof, Nör, Jacques E., and Bottino, Marco C.

Subjects

*CIPROFLOXACIN, *ANTI-infective agents, *DENTAL pulp, *STEM cells, *IN vitro studies, *ANTIBIOTICS

Abstract

Objective A combination of antibiotics, including but not limited to metronidazole (MET) and ciprofloxacin (CIP), has been indicated to eradicate bacteria in necrotic immature permanent teeth prior to regenerative procedures. It has been shown clinically that antibiotic pastes may lead to substantial stem cell death. The aim of this study was to synthesise scaffolds containing various concentrations of CIP to enhance cell viability while preserving antimicrobial properties . Design Polydioxanone (PDS)-based electrospun scaffolds were processed with decreasing CIP concentrations (25–1 wt.%) and morphologically evaluated using scanning electron microscopy (SEM). Cytotoxicity assays were performed to determine whether the amount of CIP released from the scaffolds would lead to human dental pulp stem cell (hDPSC) toxicity. Similarly, WST-1 assays were performed to evaluate the impact of CIP release on hDPSC proliferation. Pure PDS scaffolds and saturated double antibiotic solution MET/CIP (DAP) served as both positive and negative controls, respectively. Antibacterial efficacy against E. faecalis ( Ef ) was tested. Results A significant decrease in hDPSC’ viability at concentrations 5–25 wt.% was observed. However, concentrations below 5 wt.% did not impair cell viability. Data from the WST-1 assays indicated no detrimental impact on cell proliferation for scaffolds containing 2.5 wt.% CIP or less. Significant antimicrobial properties were seen for CIP-scaffolds at lower concentrations ( i.e. , 1 and 2.5 wt.%). Conclusion The obtained data demonstrated that a reduced concentration of CIP incorporated into PDS-based scaffolds maintains its antimicrobial properties while enhancing viability and proliferation of dental pulp stem cells. [ABSTRACT FROM AUTHOR]

Published

2015

10. Three-dimensional printing of clinical scale and personalized calcium phosphate scaffolds for alveolar bone reconstruction.

Author

Anderson, Margaret, Dubey, Nileshkumar, Bogie, Kath, Cao, Chen, Li, Junying, Lerchbacker, Joseph, Mendonça, Gustavo, Kauffmann, Frederic, Bottino, Marco C., and Kaigler, Darnell

Subjects

*ALVEOLAR process, *THREE-dimensional printing, *CALCIUM phosphate, *CELLULAR mechanics, *CONE beam computed tomography

Abstract

Alveolar bone defects can be highly variable in their morphology and, as the defect size increases, they become more challenging to treat with currently available therapeutics and biomaterials. This investigation sought to devise a protocol for fabricating customized clinical scale and patient-specific, bioceramic scaffolds for reconstruction of large alveolar bone defects. Two types of calcium phosphate (CaP)-based bioceramic scaffolds (alginate/β-TCP and hydroxyapatite/α-TCP, hereafter referred to as hybrid CaP and Osteoink™, respectively) were designed, 3D printed, and their biocompatibility with alveolar bone marrow stem cells and mechanical properties were determined. Following scaffold optimization, a workflow was developed to use cone beam computed tomographic (CBCT) imaging to design and 3D print, defect-specific bioceramic scaffolds for clinical-scale bone defects. Osteoink™ scaffolds had the highest compressive strength when compared to hybrid CaP with different infill orientation. In cell culture medium, hybrid CaP degradation resulted in decreased pH (6.3) and toxicity to stem cells; however, OsteoInk™ scaffolds maintained a stable pH (7.2) in culture and passed the ISO standard for cytotoxicity. Finally, a clinically feasible laboratory workflow was developed and evaluated using CBCT imaging to engineer customized and defect-specific CaP scaffolds using OsteoInk™. It was determined that printed scaffolds had a high degree of accuracy to fit the respective clinical defects for which they were designed (0.27 mm morphological deviation of printed scaffolds from digital design). From patient to patient, large alveolar bone defects are difficult to treat due to high variability in their complex morphologies and architecture. Our findings shows that Osteoink™ is a biocompatible material for 3D printing of clinically acceptable, patient-specific scaffolds with precision-fit for use in alveolar bone reconstructive procedures. Collectively, emerging digital technologies including CBCT imaging, 3D surgical planning, and (bio)printing can be integrated to address this unmet clinical challenge. [ABSTRACT FROM AUTHOR]

Published

2022