The Application of Microfluidic Techniques on Tissue Engineering in Orthopaedics

2019 ◽  
Vol 24 (45) ◽  
pp. 5397-5406 ◽  
Author(s):  
Lingtian Wang ◽  
Dajun Jiang ◽  
Qiyang Wang ◽  
Qing Wang ◽  
Haoran Hu ◽  
...  
Keyword(s):  
Tissue Engineering ◽  
Cell Culture ◽  
Bone Metastasis ◽  
Microfluidic Devices ◽  
Cartilage Defects ◽  
Extensive Literature ◽  
Microfluidic Platforms ◽  
Scaffold Fabrication ◽  
Interstitial Fluid Flows

Background: Tissue engineering (TE) is a promising solution for orthopaedic diseases such as bone or cartilage defects and bone metastasis. Cell culture in vitro and scaffold fabrication are two main parts of TE, but these two methods both have their own limitations. The static cell culture medium is unable to achieve multiple cell incubation or offer an optimal microenvironment for cells, while regularly arranged structures are unavailable in traditional cell-laden scaffolds, which results in low biocompatibility. To solve these problems, microfluidic techniques are combined with TE. By providing 3-D networks and interstitial fluid flows, microfluidic platforms manage to maintain phenotype and viability of osteocytic or chondrocytic cells, and the precise manipulation of liquid, gel and air flows in microfluidic devices leads to the highly organized construction of scaffolds. Methods: In this review, we focus on the recent advances of microfluidic techniques applied in the field of tissue engineering, especially in orthropaedics. An extensive literature search was done using PubMed. The introduction describes the properties of microfluidics and how it exploits the advantages to the full in the aspects of TE. Then we discuss the application of microfluidics on the cultivation of osteocytic cells and chondrocytes, and other extended researches carried out on this platform. The following section focuses on the fabrication of highly organized scaffolds and other biomaterials produced by microfluidic devices. Finally, the incubation and studying of bone metastasis models in microfluidic platforms are discussed. Conclusion: The combination of microfluidics and tissue engineering shows great potentials in the osteocytic cell culture and scaffold fabrication. Though there are several problems that still require further exploration, the future of microfluidics in TE is promising.

scholarly journals A Modular Toolkit to Fabricate Microfluidic Devices for 3D Cell Culture and Near Real-time Measurements

2020 ◽  
Author(s):  
Giraso Kabandana ◽  
Adam Michael Ratajczak ◽  
Chengpeng Chen
Keyword(s):  
Cell Culture ◽  
Real Time ◽  
Low Cost ◽  
New Technology ◽  
Microfluidic Channel ◽  
3D Cell Culture ◽  
Microfluidic Devices ◽  
In Vitro Cell Cultures ◽  
Scoring Tools

Microfluidic technology has tremendously facilitated the development of in vitro cell cultures and studies. Conventionally, microfluidic devices are fabricated with extensive facilities by well-trained researchers, which hinders the widespread adoption of the technology for broader applications. Enlightened by the fact that low-cost microbore tubing is a natural microfluidic channel, we developed a series of adaptors in a toolkit that can twine, connect, organize, and configure the tubing to produce functional microfluidic units. Three subsets of the toolkit were thoroughly developed: the tubing and scoring tools, the flow adaptors, and the 3D cell culture suite. To demonstrate the usefulness and versatility of the toolkit, we assembled a microfluidic device and successfully applied it for 3D macrophage cultures, flow-based stimulation, and automated near real-time quantitation with new knowledge generated. Overall, we present a new technology that allows simple, fast, and robust assembly of customizable and scalable microfluidic devices with minimal facilities, which is broadly applicable to research that needs or could be enhanced by microfluidics.

scholarly journals An Assessment of Cell Culture Plate Surface Chemistry for in Vitro Studies of Tissue Engineering Scaffolds

2015 ◽  
Vol 6 (4) ◽  
pp. 1054-1063 ◽  
Author(s):  
Alexander Röder ◽  
Elena García-Gareta ◽  
Christina Theodoropoulos ◽  
Nikola Ristovski ◽  
Keith Blackwood ◽  
...  
Keyword(s):  
Tissue Engineering ◽  
Cell Culture ◽  
Surface Chemistry ◽  
In Vitro Studies ◽  
Plate Surface ◽  
Tissue Engineering Scaffolds ◽  
Culture Plate

Preliminary testing of silicone-urethane elastomers as substrates in human cell culture

e-Polymers ◽  
2007 ◽  
Vol 7 (1) ◽  
Author(s):  
Malgorzata Lewandowska-Szumieł ◽  
Janusz Kozakiewicz ◽  
Piotr Mrówka ◽  
Agnieszka Jurkowska ◽  
Edyta Sienkiewicz-Łatka ◽  
...  
Keyword(s):  
Tissue Engineering ◽  
Cell Culture ◽  
Blood Platelets ◽  
Human Fibroblasts ◽  
Medical Implants ◽  
Tissue Engineering Scaffolds ◽  
Xtt Assay ◽  
In Vitro Biocompatibility ◽  
Different Types

AbstractSilicone-urethanes, polymers combining the characteristics of two widely used biomaterials, i.e. polyurethanes and silicones, are highly valued in many applications, including medical implants. To assess properties of these materials in contact with living cells, a set of different silicone-urethane materials, candidates for tissue engineering scaffolds, was synthesized and characterized. Two different oligomeric siloxane diols: Tegomer-2111 (Teg) and KF-6001 (KF), and two different types of diisocyanate, MDI and IPDI, were used in synthesis. Blood platelets adhesion to surfaces of selected materials showed a higher thrombogenicity of material based on Teg. Human fibroblasts were used in in vitro biocompatibility tests. The viability of cells cultured on silicone-urethanes was tested by XTT assay. Teg-based silicone-urethanes showed a significantly higher biocompatibility than those based on KF. Materials based on MDI compared to IPDI were found to be significantly more favoured by cells, not necessarily due to the type of diisocyanate but maybe also because of the necessity of using potentially toxic catalyst which accompanies the use of IPDI. Our studies indicate that silicone-urethanes are potent materials for tissue engineering products development. On the basis of the observations performed in cell culture, Tegomer- 2111 as oligomeric siloxane diol and MDI as diisocyanate are recommended as starting materials for silicone-urethane scaffolds synthesis.

Mechanically Enhanced Precipitation of Phase-Inversion Sprayed Polyurethane Scaffold May Be Used to Match Tissue Specific Anisotropy

2009 ◽  
Author(s):  
James P. Kennedy ◽  
Robert W. Hitchcock
Keyword(s):  
Mechanical Properties ◽  
Tissue Engineering ◽  
Cell Culture ◽  
Pore Size ◽  
Phase Inversion ◽  
Anisotropy Ratio ◽  
Material Anisotropy ◽  
Polyurethane Scaffold ◽  
Stiffness Anisotropy

Methods of creating a scaffold for tissue engineering that allow for modification of properties such as pore size, porosity, and anisotropy are essential for tissue engineering applications. For example the pore size and material anisotropy have been shown to affect cardiomyocyte elongation and alignment [1]. Phase-inversion spray polymerization (PISP) is a method for rapidly precipitating polymers onto a surface by depositing the polymer solution simultaneously with a nonsolvent, and may be used to create biocompatible scaffolds of engineered morphological and mechanical properties by varying the solubility of the polymer in the nonsolvent [2]. We report here on the fabrication of scaffolds using different nonsolvents and methods of in-process elongation that allow for control of stiffness, anisotropy ratio, porosity, and in vitro cell culture.

Improvement of Bioactivity of Collagen/Alginate Scaffolds by Hydroxyapatite for Tissue Engineering Cartilage

2008 ◽  
Vol 396-398 ◽  
pp. 445-448 ◽  
Author(s):  
J. Sun ◽  
R. Wang ◽  
L. Zheng ◽  
Yan Fei Tan ◽  
Yu Mei Xiao ◽  
...  
Keyword(s):  
Mechanical Property ◽  
Tissue Engineering ◽  
Cell Culture ◽  
Composite Film ◽  
Cartilage Tissue Engineering ◽  
Cartilage Tissue ◽  
The Poor ◽  
Pure Collagen ◽  
Good Biocompatibility

With good biocompatibility, collagen is often used in cartilage tissue engineering. Collagen/alginate composite was hoped to improve the poor mechanical property of pure collagen but the biocompatibity was decreased. In this study, hydroxyapatite (HA) particles were used to get collagen/alginate/HA (CAHA) composite film to enhance the bioactivity properties. The bioactivity of the composite was investigated by in vitro co-culture with chondrocytes. During the 6-day cell culture in vitro, the composite showed a significant improvement in promoting proliferation and maintaining morphology/phenotype of the chondrocytes over collagen/alginate composite by MTT, SEM, fluorescent and immunohistochemical assays. Cytocompatibility and cytoviablility of CAHA even come up to that of collagen film alone. The results indicated that the composite film may provide an appropriate environment for the proliferation and maintaining the morphology and phenotype of chondrocytes and have a potential clinical application in the cartilage tissue engineering field.

scholarly journals A Review of Current Regenerative Medicine Strategies that Utilize Nanotechnology to Treat Cartilage Damage

2016 ◽  
Vol 10 (1) ◽  
pp. 862-876 ◽  
Author(s):  
R. Kumar ◽  
M. Griffin ◽  
P.E. Butler
Keyword(s):  
Tissue Engineering ◽  
Regenerative Medicine ◽  
Cartilage Damage ◽  
Bioactive Molecules ◽  
Cartilage Defects ◽  
Biomimetic Scaffolds ◽  
Cartilage Reconstruction ◽  
Biomaterial Science

Background: Cartilage is an important tissue found in a variety of anatomical locations. Damage to cartilage is particularly detrimental, owing to its intrinsically poor healing capacity. Current reconstructive options for cartilage repair are limited, and alternative approaches are required. Biomaterial science and Tissue engineering are multidisciplinary areas of research that integrate biological and engineering principles for the purpose of restoring premorbid tissue function. Biomaterial science traditionally focuses on the replacement of diseased or damaged tissue with implants. Conversely, tissue engineering utilizes porous biomimetic scaffolds, containing cells and bioactive molecules, to regenerate functional tissue. However, both paradigms feature several disadvantages. Faced with the increasing clinical burden of cartilage defects, attention has shifted towards the incorporation of Nanotechnology into these areas of regenerative medicine. Methods: Searches were conducted on Pubmed using the terms “cartilage”, “reconstruction”, “nanotechnology”, “nanomaterials”, “tissue engineering” and “biomaterials”. Abstracts were examined to identify articles of relevance, and further papers were obtained from the citations within. Results: The content of 96 articles was ultimately reviewed. The literature yielded no studies that have progressed beyond in vitro and in vivo experimentation. Several limitations to the use of nanomaterials to reconstruct damaged cartilage were identified in both the tissue engineering and biomaterial fields. Conclusion: Nanomaterials have unique physicochemical properties that interact with biological systems in novel ways, potentially opening new avenues for the advancement of constructs used to repair cartilage. However, research into these technologies is in its infancy, and clinical translation remains elusive.

Nanofibrous Substrate For Tissue Engineering Applications—A Review

2021 ◽  
Vol 8 (6) ◽  
pp. 13-21
Author(s):  
Odia Osemwegie ◽  
Lihua Lou ◽  
Ernest Smith ◽  
Seshadri Ramkumar
Keyword(s):  
Drug Delivery ◽  
Tissue Engineering ◽  
Cell Culture ◽  
Tissue Regeneration ◽  
Biomedical Applications ◽  
High Volume ◽  
Clinical Applications ◽  
Critical Factors ◽  
Engineering Applications

Nanofiber substrates have been used for various biomedical applications, including tissue regeneration, drug delivery, and in-vitro cell culture. However, despite the high volume of studies in this field, current clinical applications remain minimal. Innovations for their applications continuously generate exciting prospects. In this review, we discuss some of these novel innovations and identify critical factors to consider before their adoption for biomedical applications.

Laser microstructured scaffolds for tissue engineering under dynamic cell culture conditions

2020 ◽  
Author(s):  
Ελευθερία Μπαμπαλιάρη
Keyword(s):  
Tissue Engineering ◽  
Cell Culture ◽  
Culture Conditions ◽  
Dynamic Cell ◽  
Cell Culture Conditions

Παρόλο που το περιφερικό νευρικό σύστημα εμφανίζει υψηλότερο ρυθμό αναγέννησης από εκείνο του κεντρικού νευρικού συστήματος μέσω αυθόρμητης αναγέννησης μετά από έναν τραυματισμό, η καθοδηγούμενη αξονική νευρική αναγέννηση και η λειτουργική αποκατάσταση είναι αρκετά σπάνια. Συνεπώς, η ανάπτυξη επιτυχημένων μεθόδων για την καθοδήγηση της νευρικής ανάπτυξης, «in vitro», είναι υψίστης σημασίας. Έχει αναφερθεί λεπτομερώς ότι η τοπογραφία του υποστρώματος επηρεάζει την ανάπτυξη, τον προσανατολισμό και τη διαφοροποίηση των νευρικών κυττάρων. Ωστόσο, η συνδυασμένη δράση της διατμητικής τάσης και της τοπογραφίας του υποστρώματος στην νευρική ανάπτυξη έχει ελάχιστα μελετηθεί, παρόλο που οι διατμητικές τάσεις είναι ευρέως γνωστό ότι διαδραματίζουν καθοριστικό ρόλο στην οργάνωση, ανάπτυξη και λειτουργία των ιστών. Σε αυτή τη μελέτη, ένα σύστημα μικροροών ακριβούς ελεγχόμενης ροής με συγκεκριμένους ειδικά σχεδιασμένους θαλάμους, που ενσωματώνουν μικροδομημένα υποστρώματα λέιζερ, αναπτύχθηκε για να μελετηθεί η συνδυασμένη δράση της διατμητικής τάσης και της τοπογραφίας υποστρώματος στην ανάπτυξη, στον προσανατολισμό, στην επιμήκυνση και στη διαφοροποίηση νευρικών κυττάρων. Πολυμερικά μικροδομημένα υποστρώματα, με ελεγχόμενη γεωμετρία και κανονικότητα μοτίβου, κατασκευάστηκαν με χρήση υπερβραχέων παλμών λέιζερ. Πραγματοποιήθηκε συγκριτική μελέτη μεταξύ στατικών και δυναμικών κυτταρικών καλλιεργειών για να αξιολογηθεί η συνεργατική ή ανταγωνιστική επίδραση της διατμητικής τάσης και της τοπογραφίας στη συμπεριφορά των νευρικών κυττάρων. Τα αποτελέσματα της κυτταρικής καλλιέργειας συμπληρώθηκαν με υπολογιστικές προσομοιώσεις ροής με σκοπό τον ακριβή υπολογισμό των αντίστοιχων τιμών διατμητικής τάσης.

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