Molecular bionics – engineering biomaterials at the molecular level using biological principles

Rodríguez‐Arco, Laura; Poma, Alessandro; Ruiz‐Pérez, Lorena; Scarpa, Edoardo; Ngamkham, Kamolchanok; Battaglia, Giuseppe

doi:10.1016/j.biomaterials.2018.10.044

Cited by 39 publications

(37 citation statements)

References 371 publications

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“…While features of biopolymers such as hydrophilicity, biodegradability, biocompatibility, porosity, and non-toxicity make them attractive materials in many biomedical applications; hydrophobicity combined with biocompatibility and non-toxicity could be determinant in some selected applications where hydrophobicity is a key advantage [140][141][142]. On the other hand, the processing of the polymer and the device's design are equally critical for successful tissue engineering applications [143][144][145][146][147].…”

Section: Biodegradable Polymers As Devices For Tissue Engineeringmentioning

confidence: 99%

Recent Advances in Bioplastics: Application and Biodegradation

et al. 2020

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The success of oil-based plastics and the continued growth of production and utilisation can be attributed to their cost, durability, strength to weight ratio, and eight contributions to the ease of everyday life. However, their mainly single use, durability and recalcitrant nature have led to a substantial increase of plastics as a fraction of municipal solid waste. The need to substitute single use products that are not easy to collect has inspired a lot of research towards finding sustainable replacements for oil-based plastics. In addition, specific physicochemical, biological, and degradation properties of biodegradable polymers have made them attractive materials for biomedical applications. This review summarises the advances in drug delivery systems, specifically design of nanoparticles based on the biodegradable polymers. We also discuss the research performed in the area of biophotonics and challenges and opportunities brought by the design and application of biodegradable polymers in tissue engineering. We then discuss state-of-the-art research in the design and application of biodegradable polymers in packaging and emphasise the advances in smart packaging development. Finally, we provide an overview of the biodegradation of these polymers and composites in managed and unmanaged environments.

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Section: Biodegradable Polymers As Devices For Tissue Engineeringmentioning

confidence: 99%

Recent Advances in Bioplastics: Application and Biodegradation

et al. 2020

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“…LP EM imaging of samples in liquid have been reported for electrochemical reactions [15, 16], nanocrystal growth [17, 18], whole cells[19, 20], and to-mography reconstruction of particles in liquid state [21]. Soft materials such as micelles and vesicles form in water, or any other selective solvent, as a result of counteracting interactions in-cluding hydrophobic effects, steric hydrophilic interactions, hydrogen bonds and electrostatic interactions [22]. Such relatively weak forces give rise to highly dynamical assemblies that exist in solution where the solvent plays a critical role in the integrity of such structural assemblies.…”

Section: Introductionmentioning

confidence: 99%

4D imaging of soft matter in liquid water

Battaglia

Marchello

et al. 2021

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Water is a critical component for both function and structure of soft matter and it is what bestows the adjective soft. Imaging samples in liquid state is thus paramount to gathering structural and dynamical information of any soft materials. Herein we propose the use of liquid phase electron microscopy to expand ultrastructural analysis into dynamical investigations. We imaged two soft matter examples: a polymer micelle and a protein in liquid phase using transmission electron microscopy and demonstrate that the inherent Brownian motion associated with the liquid state can be exploited to gather three-dimensional information of the materials in their natural state. We call such an approach brownian tomography (BT). We combine BT with single particle analysis (Brownian particle analysis BPA) to image protein structures with a spatial resolution close that achievable using cryogenic TEM. We show that BPA allows sub-nanometer resolution of soft materials and enables to gather information on conformational changes, hydration dynamics, and the effect of thermal fluctuations.Abstract Figure

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“…We focus on polymeric compartments because they allow the encapsulation of hydrophilic cargoes, the insertion of hydrophobic molecules, or even the simultaneous encapsulation and insertion thereof. 2,10,28,36,[45][46][47][48] Moreover, the efficacy of polymer compartments can be increased by localizing them via targeting moieties to specific sites in the body. 15,29,45,49 Specifically, we present how polymer biosensors can be tailored to change their properties in response to the presence of stimuli in a bioinspired manner based on the behavior of natural organelles inside cells or cells that respond to specific intracellular or intercellular signals while preserving their integrity.…”

Section: Introductionmentioning

confidence: 99%