Poly( l -lactic acid) and polyurethane nanofibers fabricated by solution blow spinning as potential substrates for cardiac cell culture

Tomecka, Ewelina; Wojasiński, Michał; Jastrzębska, Elżbieta; Chudy, M.; Ciach, Tomasz; Brzózka, Zbigniew

doi:10.1016/j.msec.2017.02.055

Cited by 68 publications

(39 citation statements)

References 45 publications

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“…При использовании метода АЭРДФ струя прядильного раствора ускоряется и растягивается высокоскоростным газовым потоком. В зоне газового потока, отличающегося высокой турбу-лентностью, происходит изгиб и запутывание струи, что увеличивает вероятность перепутывания соседних струй [14,15]. Это приводит к образованию волокон сложной пространственной организации.…”

Section: Discussionunclassified

Comparative Assessment of the Possibility of Cellular Material Collection to Matrixes Obtained by Methods of Electrospinning and Aerodynamic Formation in a Turbulent Gas Flow

Afanasiev¹,

Муслимова²,

Nashchekina³

et al. 2017

Sib. med. ž. (Tomsk)

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Section: Discussionunclassified

Comparative Assessment of the Possibility of Cellular Material Collection to Matrixes Obtained by Methods of Electrospinning and Aerodynamic Formation in a Turbulent Gas Flow

Afanasiev¹,

Муслимова²,

Nashchekina³

et al. 2017

Sib. med. ž. (Tomsk)

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“…Poly (ε- caprolactone) in combination with other biomaterials have also been proven to be efficient composite for cardiac tissue repair. They have been used in combination with PLLA alone ( Tomecka et al, 2017 ; Sharifpanah et al, 2017 ), PLLA and collagen ( Centola et al, 2010 ), polypyrrole and gelatin ( Mukherjee et al, 2011 ), polyglycolic acid ( Kai et al, 2011 ), poly (hydroxymethyl glycolide) ( Sugiura et al, 2016 ), chitosan and gelatin ( Castilho et al, 2017 ).…”

Section: Congenital Heart Disease: Types Malformations Presentationmentioning

confidence: 99%

Recent advances and challenges on application of tissue engineering for treatment of congenital heart disease

Mantakaki¹,

Fakoya

Sharifpanah

2018

PeerJ

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Congenital heart disease (CHD) affects a considerable number of children and adults worldwide. This implicates not only developmental disorders, high mortality, and reduced quality of life but also, high costs for the healthcare systems. CHD refers to a variety of heart and vascular malformations which could be very challenging to reconstruct the malformed region surgically, especially when the patient is an infant or a child. Advanced technology and research have offered a better mechanistic insight on the impact of CHD in the heart and vascular system of infants, children, and adults and identified potential therapeutic solutions. Many artificial materials and devices have been used for cardiovascular surgery. Surgeons and the medical industry created and evolved the ball valves to the carbon-based leaflet valves and introduced bioprosthesis as an alternative. However, with research further progressing, contracting tissue has been developed in laboratories and tissue engineering (TE) could represent a revolutionary answer for CHD surgery. Development of engineered tissue for cardiac and aortic reconstruction for developing bodies of infants and children can be very challenging. Nevertheless, using acellular scaffolds, allograft, xenografts, and autografts is already very common. Seeding of cells on surface and within scaffold is a key challenging factor for use of the above. The use of different types of stem cells has been investigated and proven to be suitable for tissue engineering. They are the most promising source of cells for heart reconstruction in a developing body, even for adults. Some stem cell types are more effective than others, with some disadvantages which may be eliminated in the future.

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“…Enhanced seeding efficiency was further noted [ 152 ]. A comparative study also showed that poly(L-lactic acid) and polyurethane nanofibrous mats fabricated by solution blow spinning were better substrates for cardiac cell culture than polystyrene was [ 153 ]. The role of carbon nanotubes has been described in this review [ 32 , 79 , 81 ].…”

Section: Biomaterials For Cardiac Regenerationmentioning

confidence: 99%

Current Trends in Biomaterial Utilization for Cardiopulmonary System Regeneration

Fakoya

Otohinoyi

Yusuf

2018

Stem Cells International

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The cardiopulmonary system is made up of the heart and the lungs, with the core function of one complementing the other. The unimpeded and optimal cycling of blood between these two systems is pivotal to the overall function of the entire human body. Although the function of the cardiopulmonary system appears uncomplicated, the tissues that make up this system are undoubtedly complex. Hence, damage to this system is undesirable as its capacity to self-regenerate is quite limited. The surge in the incidence and prevalence of cardiopulmonary diseases has reached a critical state for a top-notch response as it currently tops the mortality table. Several therapies currently being utilized can only sustain chronically ailing patients for a short period while they are awaiting a possible transplant, which is also not devoid of complications. Regenerative therapeutic techniques now appear to be a potential approach to solve this conundrum posed by these poorly self-regenerating tissues. Stem cell therapy alone appears not to be sufficient to provide the desired tissue regeneration and hence the drive for biomaterials that can support its transplantation and translation, providing not only physical support to seeded cells but also chemical and physiological cues to the cells to facilitate tissue regeneration. The cardiac and pulmonary systems, although literarily seen as just being functionally and spatially cooperative, as shown by their diverse and dissimilar adult cellular and tissue composition has been proven to share some common embryological codevelopment. However, necessitating their consideration for separate review is the immense adult architectural difference in these systems. This review also looks at details on new biological and synthetic biomaterials, tissue engineering, nanotechnology, and organ decellularization for cardiopulmonary regenerative therapies.

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Poly( l -lactic acid) and polyurethane nanofibers fabricated by solution blow spinning as potential substrates for cardiac cell culture

Cited by 68 publications

References 45 publications

Comparative Assessment of the Possibility of Cellular Material Collection to Matrixes Obtained by Methods of Electrospinning and Aerodynamic Formation in a Turbulent Gas Flow

Comparative Assessment of the Possibility of Cellular Material Collection to Matrixes Obtained by Methods of Electrospinning and Aerodynamic Formation in a Turbulent Gas Flow

Recent advances and challenges on application of tissue engineering for treatment of congenital heart disease

Current Trends in Biomaterial Utilization for Cardiopulmonary System Regeneration

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