Polymeric hollow fiber membranes for bioartificial organs and tissue engineering applications

Diban, Nazely; Stamatialis, Dimitrios

doi:10.1002/jctb.4300

Cited by 38 publications

(44 citation statements)

References 122 publications

(317 reference statements)

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“…The last one concerns the mechanical properties of the NGC, which should match the same properties of nerve tissue . As referred above, a NGC should provide a pathway for nerve regeneration, resist tearing from sutures and provide a mechanically stable architecture for the new tissue . Therefore it should remain intact during the first stages of regeneration.…”

Section: Ideal Nerve Guide Conduit Propertiesmentioning

confidence: 99%

Peripheral Nerve Regeneration: Current Status and New Strategies Using Polymeric Materials

Pinho

Fonseca

Serra

et al. 2016

Adv Healthcare Materials

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Experiments concerning peripheral nerve regeneration have been reported since the end of the 19th century. The need to implement an effective surgical procedure in terms of functional recovery has resulted in the appearance of several approaches to solve this problem. Nerve autograft was the first approach studied and is still considered the gold standard. Since autografts require donor harvesting, other strategies involving the use of natural materials have also been studied. Nevertheless, the results were not very encouraging and attention has moved towards the use of nerve conduits made from polymers, whose properties can be easily tailored and which allow the nerve conduit to be easily processed into a variety of shapes and forms. Some of these materials are already approved by the US Food and Drug Administration (FDA), as is presented here. Furthermore, polymers with conductive properties have very recently been subject to intensive study in this field, since it is believed that such properties have a positive influence in the regeneration of the new axons. This manuscript intends to give a global view of the mechanisms involved in peripheral nerve regeneration and the main strategies used to recover motor and sensorial function of injured nerves.

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Section: Ideal Nerve Guide Conduit Propertiesmentioning

confidence: 99%

Peripheral Nerve Regeneration: Current Status and New Strategies Using Polymeric Materials

Pinho

Fonseca

Serra

et al. 2016

Adv Healthcare Materials

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“…Moreover, on the one hand, HFs have to act as an immunoisolation barrier, but on the other hand, they have to allow mass exchange between the fluid and the cell phase. Hence, the pore size of the HF membranes must be small enough to isolate the embedded exogenous cells but sufficiently large to allow appropriate mass transfer of nutrients to cells and removal of waste metabolites (23,(31)(32)(33)(34).…”

Section: Bioartificial Organsmentioning

confidence: 99%

Hollow Fiber Bioreactor Technology for Tissue Engineering Applications

et al. 2016

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Hollow fiber bioreactors are the focus of scientific research aiming to mimic physiological vascular networks and engineer organs and tissues in vitro. The reason for this lies in the interesting features of this bioreactor type, including excellent mass transport properties. Indeed, hollow fiber bioreactors allow limitations to be overcome in nutrient transport by diffusion, which is often an obstacle to engineer sizable constructs in vitro. This work reviews the existing literature relevant to hollow fiber bioreactors in organ and tissue engineering applications. To this purpose, we first classify the hollow fiber bioreactors into 2 categories: cylindrical and rectangular. For each category, we summarize their main applications both at the tissue and at the organ level, focusing on experimental models and computational studies as predictive tools for designing innovative, dynamic culture systems. Finally, we discuss future perspectives on hollow fiber bioreactors as in vitro models for tissue and organ engineering applications.

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“…Fibrous media are a class of versatile materials that offer functionalities both in natural systems such as keeping warm, [1] directional wetting, [2] providing ultrahigh adhesion, [3][4][5] and in practical application from textile products, [6,7] filtration, [8] microfludics, [9][10][11] as well as flexible electronics. [12][13][14] Wetting behaviors on the fibers are different from the counterpart on the planes due to the existence of capillary forces contributed by the fiber gaps.…”

Section: Introductionmentioning

confidence: 99%

Stretchable‐Fiber‐Confined Wetting Conductive Liquids as Wearable Human Health Monitors

Guan

Nilghaz

et al. 2016

Adv Funct Materials

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Wetting behaviors on stretchable supports are very common in our daily lives, however, received limited attention even they show promising potentials in flexible electronics and other fields. In this study, stretchable wetting behaviors of conductive liquids deposited onto two horizontal rubber fibers are investigated. A firm liquid/solid interaction during the stretching process can contribute to a stable liquid bridge between the fibers even under extremely stretching, showing their proof‐to‐principle ability to monitor human movement toward early diagnosis of Parkinson's disease or sports injury prevention.

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Polymeric hollow fiber membranes for bioartificial organs and tissue engineering applications

Cited by 38 publications

References 122 publications

Peripheral Nerve Regeneration: Current Status and New Strategies Using Polymeric Materials

Peripheral Nerve Regeneration: Current Status and New Strategies Using Polymeric Materials

Hollow Fiber Bioreactor Technology for Tissue Engineering Applications

Stretchable‐Fiber‐Confined Wetting Conductive Liquids as Wearable Human Health Monitors

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