Raffaella De Piano

@article{Piano}2024,

title = {Drug release from hydrogel-based matrix systems partially coated: experiments and modeling},

author = {Raffaella {De Piano} and Diego Caccavo and Sara Cascone and Caterina Festa and Gaetano Lamberti and Anna Angela Barba },

url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85092403044\&doi=10.1016%2fj.jddst.2020.102146\&partnerID=40\&md5=e519d84642480478a063b4c7b4e2832e},

doi = {10.1016/j.jddst.2020.102146},

isbn = {17732247},

year  = {2024},

date = {2024-05-01},

journal = {Journal of Drug Delivery Science and Technology},

volume = {61},

number = {102146},

abstract = {Hydrogel-based matrix systems are largely used as controlled drug delivery systems, since it is possible to get the desired drug release profile properly designing the system in term of composition, drug loading and shape. Meanwhile, the mathematical modeling of the phenomena involved in the drug release process is a useful tool to understand and to predict the complex behavior of these systems, in term of water up-take, matrix swelling and erosion, drug diffusion and release. Furthermore, the coating of the matrix is used to provide certain characteristics such as enteric resistance, meanwhile making more complex the mathematical description of the process. In this work cylindrical tablets made of hydroxyl-propyl-methyl-cellulose (HPMC) loaded with theophylline (TP), as obtained or coated by an impermeable painting on the lateral surface were dissolved in a USP II apparatus, and the release of TP, as well as of HPMC and the shape changes were monitored in time, for several rotational speeds of the impeller. The experimental data gathered were used to tune a previously proposed mathematical model. The model was found able to correctly describe all the observed phenomena, confirming its usefulness as a tool in design and production of pharmaceutics.},

keywords = {drug release, Modeling, Tablets, Theophylline},

pubstate = {published},

tppubtype = {article}

}

@article{Piano}2023b,

title = {Polyelectrolyte hydrogels in biological systems: Modeling of swelling and deswelling behavior},

author = {Raffaella {De Piano} and Diego Caccavo and Anna Angela Barba and Gaetano Lamberti},

url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85161532217\&doi=10.1016%2fj.ces.2023.118959\&partnerID=40\&md5=a269515dd96617e9242f75711516e847},

doi = {10.1016/j.ces.2023.118959},

issn = {00092509},

year  = {2023},

date = {2023-09-05},

journal = {Chemical Engineering Science},

volume = {279},

number = {118959},

abstract = {Polyelectrolyte hydrogels are a particular class of hydrogel whose behavior is connected to the variation of pH in the surrounding solution. Their behavior is influenced by the ionizable groups present on their chain. These groups could be acid or basic and polyelectrolytes could be anionic or cationic. To fully understand their behavior mathematical modeling has been widely used over many years. In this work a model based on a monophasic approach will be used to describe a general behavior of anionic hydrogels in a steady state condition at pH lower (or equal) to seven. Free swelling experiments and constrained swelling experiments have been simulated varying the parameters of the model to highlight the properties of the material. From a comparison with experimental data, it results that the proposed model can describe the general behavior of the system as described in the literature.},

keywords = {Biological systems, Equilibrium, Hydrogels, Modeling, Polyelectrolytes},

pubstate = {published},

tppubtype = {article}

}

@article{Piano}2023,

title = {Hydrogel: pH Role on Polyelectrolyte Behaviour in Aqueous Media},

author = {Raffaella {De Piano} and Diego Caccavo and Anna Angela Barba and Gaetano Lamberti},

doi = {10.3303/CET23100067},

issn = {22839216},

year  = {2023},

date = {2023-06-30},

journal = {Chemical Engineering Transactions},

volume = {100},

pages = {397-402},

abstract = {Polyelectrolytes are a class of polymer whose swelling depends on the external condition of pH. The dissociation of the ionizable groups is strongly depended on the concentration of the H+ ions in solution and this leads to different swelling behaviour changing the external pH. Since these materials are versatile and used in various fields, an in-depth knowledge of their behaviour becomes important to use them appropriately. The present work aims to offer an overview of the behaviour of these materials in solution through an experimental and a steady state modelling part. The results serve as a fundamental basis to understand the behaviour of these systems, including transient periods, leading to a comprehensive and predictable description.},

keywords = {Hydrogel, Polyelectrolyte Behaviour},

pubstate = {published},

tppubtype = {article}

}

@article{Piano}2020,

title = {Drug release from hydrogel-based matrix systems partially coated: experiments and modeling},

author = {Raffaella {De Piano} and Diego Caccavo and Sara Cascone and Caterina Festa and Gaetano Lamberti and Anna Angela Barba},

url = {https://www.sciencedirect.com/science/article/abs/pii/S1773224720314350?via%3Dihub},

doi = {10.1016/j.jddst.2020.102146},

year  = {2020},

date = {2020-10-07},

journal = {Journal of Drug Delivery Science and Technology},

abstract = {Hydrogel-based matrix systems are largely used as controlled drug delivery systems, since it is possible to get the desired drug release profile properly designing the system in term of composition, drug loading and shape. Meanwhile, the mathematical modeling of the phenomena involved in the drug release process is a useful tool to understand and to predict the complex behavior of these systems, in term of water up-take, matrix swelling and erosion, drug diffusion and release. Furthermore, the coating of the matrix is used to provide certain characteristics such as enteric resistance, meanwhile making more complex the mathematical description of the process. In this work cylindrical tablets made of hydroxyl-propyl-methyl-cellulose (HPMC) loaded with theophylline (TP), as obtained or coated by an impermeable painting on the lateral surface were dissolved in a USP II apparatus, and the release of TP, as well as of HPMC and the shape changes were monitored in time, for several rotational speeds of the impeller. The experimental data gathered were used to tune a previously proposed mathematical model. The model was found able to correctly describe all the observed phenomena, confirming its usefulness as a tool in design and production of pharmaceutics.},

keywords = {drug release, Modeling, Tablets, Theophylline},

pubstate = {published},

tppubtype = {article}

}

@article{Caccavo2017b,

title = {Modeling the modified drug release from curved shape drug delivery systems - Dome Matrix®},

author = {Diego Caccavo and Anna Angela Barba and Matteo D'Amore and Raffaella {De Piano} and Gaetano Lamberti and Alessandra Rossi and Paolo Colombo},

url = {http://www.sciencedirect.com/science/article/pii/S0939641117308366},

doi = {10.1016/j.ejpb.2017.08.016},

issn = {0939-6411},

year  = {2017},

date = {2017-12-01},

journal = {European Journal of Pharmaceutics and Biopharmaceutics},

volume = {121},

pages = {24-31},

abstract = {The controlled drug release from hydrogel-based drug delivery systems is a topic of large interest for research in pharmacology. The mathematical modeling of the behavior of these systems is a tool of emerging relevance, since the simulations can be of use in the design of novel systems, in particular for complex shaped tablets. In this work a model, previously developed, was applied to complex-shaped oral drug delivery systems based on hydrogels (Dome Matrix®). Furthermore, the model was successfully adopted in the description of drug release from partially accessible Dome Matrix® systems (systems with some surfaces coated). In these simulations, the erosion rate was used as a fitting parameter, and its dependence upon the surface area/volume ratio and upon the local fluid dynamics was discussed. The model parameters were determined by comparison with the drug release profile from a cylindrical tablet, then the model was successfully used for the prediction of the drug release from a Dome Matrix® system, for simple module configuration and for module assembled (void and piled) configurations. It was also demonstrated that, given the same initial S/V ratio, the drug release is independent upon the shape of the tablets but it is only influenced by the S/V evolution. The model reveals itself able to describe the observed phenomena, and thus it can be of use for the design of oral drug delivery systems, even if complex shaped.},

keywords = {Hydrogel Characterization, Hydrogel Modeling},

pubstate = {published},

tppubtype = {article}

}