An In Vitro Microfluidic Alveolus Model to Study Lung Biomechanics.

The gas exchange units of the lung, the alveoli, are mechanically active and undergo cyclic deformation during breathing. The epithelial cells that line the alveoli contribute to lung function by reducing surface tension via surfactant secretion, which is highly influenced by the breathing-associated mechanical cues. These spatially heterogeneous mechanical cues have been linked to several physiological and pathophysiological states. Here, we describe the development of a microfluidically assisted lung cell culture model that incorporates heterogeneous cyclic stretching to mimic alveolar respiratory motions. Employing this device, we have examined the effects of respiratory biomechanics (associated with breathing-like movements) and strain heterogeneity on alveolar epithelial cell functions. Furthermore, we have assessed the potential application of this platform to model altered matrix compliance associated with lung pathogenesis and ventilator-induced lung injury. Lung microphysiological platforms incorporating human cells and dynamic biomechanics could serve as an important tool to delineate the role of alveolar micromechanics in physiological and pathological outcomes in the lung.

Human adipose-derived stem cell spheroids incorporating platelet-derived growth factor (PDGF) and bio-minerals for vascularized bone tissue engineering.

Stem cells with mineralized materials have been used for bone regeneration; however, engineering the complex vascularized structure of the natural bone remains a challenge. Here, we developed platelet-derived growth factor (PDGF) and bio-mineral coated fibers which were then assembled with human adipose-derived stem cells (hADSCs) to form spheroids as building blocks for vascularized bone regeneration. The PDGF incorporated within the spheroid increased the proliferation of hADSCs, which was characterized by Ki-67 staining and DNA contents. Furthermore, the PDGF enhanced not only osteogenic differentiation, but also endothelial differentiation of hADSCs; the cells within the spheroids showed significantly greater gene expression by 2.46 ± 0.14 fold for osteocalcin (OCN) and by 12.85 ± 3.36 fold for von Willebrand factor (vWF) than those without PDGF. Finally, at two months following transplantation of PDGF-incorporated spheroids onto in vivo mouse calvarial defect, the regenerated bone area (42.48 ± 10.84%) was significantly enhanced and the greatest number of capillaries and arterioles with indication of transplanted hADSCs were observed. Moreover, millimeter-scale in vitro tissue prepared by fused assembly of the spheroids exhibited greater mRNA expression-associated to endothelial lineage. Taken together, these findings indicate that stem cell spheroids incorporating PDGF and bio-minerals could be used as a module for successful vascularized bone regeneration.

Surface engineering of titanium alloy using metal-polyphenol network coating with magnesium ions for improved osseointegration.

Although titanium-based implants are widely used in orthopedic and dental clinics, improved osseointegration at the bone-implant interface is still required. In this study, we developed a titanium alloy (Ti-6Al-4V, Ti) coated with epigallocatechin gallate (EGCG) and magnesium ions (Mg2+) in a metal-polyphenol network (MPN) formation. Specifically, Ti discs were coated with EGCG in MgCl2 by controlling their concentrations and pH, with the amount of coating increasing with the coating time. An in vitro culture of human adipose-derived stem cells (hADSCs) on the EGCG-Mg2+-coated Ti showed significantly enhanced ALP activity and mRNA expression of osteogenic markers. In addition, the EGCG-Mg2+-coated Ti enhanced the mineralization of hADSCs, significantly increasing the calcium content (22.2 ± 5.0 µg) compared with cells grown on Ti (13.5 ± 0.3 µg). Treatment with 2-APB, an inhibitor of Mg2+ signaling, confirmed that the enhancement of osteogenic differentiation in the hADSCs was caused by the synergistic influence of EGCG and Mg2+. The EGCG-Mg2+ coating significantly reduced the osteoclastic maturation of Raw264.7 cells, reducing tartrate-resistant acid phosphatase activity (5.4 ± 0.4) compared with that of cells grown on Ti (1.0 ± 0.5). When we placed Ti implants onto rabbit tibias, the bone-implant contact (%) was greater on the EGCG-Mg2+-coated Ti implants (8.1 ± 4.3) than on the uncoated implants (4.4 ± 2.0). Therefore, our MPN coating could be a reliable surface modification for orthopedic implants to enable the delivery of an osteoinductive metal ion (Mg2+) with the synergistic benefits of a polyphenol (EGCG).

Bioactive Membrane Immobilized with Lactoferrin for Modulation of Bone Regeneration and Inflammation.

Guided bone regeneration refers to the process in which bone defects could be regenerated by facilitated healing through the use of membranes, potentially with the delivery of osteoinductive molecules, however, the regeneration often failed due to inflammation during bone formation. In this study, we developed a membrane immobilized with lactoferrin to modulate both bone regeneration and inflammatory responses. Lactoferrin was immobilized on electrospun nanofibers (LF50) by exploiting an adhesive polydopamine coating method. When human adipose-derived stem cells (hADSCs) were seeded onto the nanofibers, the LF50 significantly increased the osteogenic differentiation. For example, the gene expression of osteopontin was 6.9 ± 2.3 times greater in the cells on LF50 than the cells on unmodified nanofibers without lactoferrin. In addition, the gene expression of tumor necrosis factor-alpha (TNF-α) of the macrophage cell line (RAW264.7) cultured on the LF50 was 0.3 ± 0.1 times reduced, indicating the lactoferrin was able to reduce inflammatory response. With implantation of nanofibers on in vivo mouse calvarial defects, the LF50 resulted in 60.9% ± 4.5% of new bone formation, which was six times greater than the results of other groups. Furthermore, when the fibers were implanted onto the in vivo mouse subcutaneous model challenged with lipopolysaccharide and interferon-γ, the area of inflammatory tissue was significantly reduced in the LF50 implanted group as 0.6 ± 0.1 mm2 as compared with the control group (1.1 ± 0.1 mm2). Taken together, the lactoferrin immobilization onto the nanofiber by polydopamine chemistry may be an effective delivery method for improving bone regeneration while regulating the inflammation. Impact statement In vivo critical-sized bone reconstruction remains challenging due to the severe inflammation, which would be an unavoidable problem during surgical process. Therefore, the present study aims to develop a guided nanofibrous membrane immobilized with lactoferrin, which has dual functions with osteoinduction and anti-inflammation. The lactoferrin-immobilized fibers demonstrated significantly enhanced in vitro osteogenic differentiation of adipose-derived stem cells as well as decreased polarization of macrophage to M1 with relatively reduced amount than that reported from previous reports. We also found that the membrane improved in vivo bone regeneration and decreased inflammatory tissue formation. Taken together, this system would be a new platform for successful bone regeneration.

Polydopamine-assisted one-step modification of nanofiber surfaces with adenosine to tune the osteogenic differentiation of mesenchymal stem cells and the maturation of osteoclasts.

Adenosine and its receptors have emerged as alternative targets to control cellular functions for bone healing. However, the soluble delivery of adenosine has not proven effective because of its fast degradation in vivo. We therefore designed a stable coating of adenosine for biomaterial surfaces through polydopamine chemistry to control osteogenesis and osteoclastogenesis via A2bR signaling. First, we prepared electrospun poly (ι-lactic acid) (PLLA) nanofiber sheets, which were modified through a one-step adenosine polydopamine coating process. Scanning electron microscopy (SEM) revealed deposition of particles on the adenosine polydopamine-coated PLLA (AP-PL) sheets compared to the polydopamine-only sheets. Moreover, X-ray photoelectron spectroscopy analysis confirmed an increase in nitrogen signals due to adenosine. Furthermore, adenosine loading efficiency and retention were significantly enhanced in AP-PL sheets compared to polydopamine-only sheets. Human adipose-derived stem cells (hADSCs) cultured on AP-PL expressed A2bR (1.30 ± 0.19 fold) at significantly higher levels than those cultured on polydopamine-only sheets. This in turn significantly elevated the expression of Runx2 (16.94 ± 1.68 and 51.69 ± 0.07 fold), OPN (1.63 ± 0.16 and 30.56 ± 0.25 fold), OCN (1.16 ± 0.13 and 5.23 ± 0.16 fold), and OSX (10.01 ± 0.81 and 62.48 ± 0.25 fold) in cells grown in growth media on days 14 and 21, respectively. Similarly, mineral deposition was enhanced to a greater extent in the AP-PL group than the polydopamine group, while blocking of A2bR significantly downregulated osteogenesis. Finally, osteoclast differentiation of RAW 264.7 cells was significantly inhibited by growth on AP-PL sheets. However, osteoclast differentiation was significantly stimulated after A2bR was blocked. Taken together, we propose that polydopamine-assisted one-step coating of adenosine is a viable method for surface modification of biomaterials to control osteogenic differentiation of stem cells and bone healing.

Oxidative Epigallocatechin Gallate Coating on Polymeric Substrates for Bone Tissue Regeneration.

Plant derived flavonoids have not been well explored in tissue engineering applications due to difficulties in efficient formulations with biomaterials for controlled presentation. Here, the authors report that surface coating of epigallocatechin gallate (EGCG) on polymeric substrates including poly (L-lactic acid) (PLLA) nanofibers can be performed via oxidative polymerization of EGCG in the presence of cations, enabling regulation of biological functions of multiple cell types implicated in bone regeneration. EGCG coating on the PLLA nanofiber promotes osteogenic differentiation of adipose-derived stem cells (ADSCs) and is potent to suppress adipogenesis of ADSCs while significantly reduces osteoclastic maturation of murine macrophages. Moreover, EGCG coating serves as a protective layer for ADSCs against oxidative stress caused by hydrogen peroxide. Finally, the in vivo implantation of EGCG-coated nanofibers into a mouse calvarial defect model significantly promotes the bone regeneration (61.52 ± 28.10%) as compared to defect (17.48 ± 11.07%). Collectively, the results suggest that EGCG coating is a simple bioinspired surface modification of polymeric biomaterials and importantly can thus serve as a promising interface for tuning activities of multiple cell types associated with bone fracture healing.

Current Advances in Immunomodulatory Biomaterials for Bone Regeneration.

Biomaterials with suitable surface modification strategies are contributing significantly to the rapid development of the field of bone tissue engineering. Despite these encouraging results, utilization of biomaterials is poorly translated to human clinical trials potentially due to lack of knowledge about the interaction between biomaterials and the body defense mechanism, the "immune system". The highly complex immune system involves the coordinated action of many immune cells that can produce various inflammatory and anti-inflammatory cytokines. Besides, bone fracture healing initiates with acute inflammation and may later transform to a regenerative or degenerative phase mainly due to the cross-talk between immune cells and other cells in the bone regeneration process. Among various immune cells, macrophages possess a significant role in the immune defense, where their polarization state plays a key role in the wound healing process. Growing evidence shows that the macrophage polarization state is highly sensitive to the biomaterial's physiochemical properties, and advances in biomaterial research now allow well controlled surface properties. This review provides an overview of biomaterial-mediated modulation of the immune response for regulating key bone regeneration events, such as osteogenesis, osteoclastogenesis, and inflammation, and it discusses how these strategies can be utilized for future bone tissue engineering applications.

Harnessing biochemical and structural cues for tenogenic differentiation of adipose derived stem cells (ADSCs) and development of an in vitro tissue interface mimicking tendon-bone insertion graft.

Tendon-bone interface tissue is extremely challenging to engineer because it exhibits complex gradients of structure, composition, biologics, and cellular phenotypes. As a step toward engineering these transitional zones, we initially analyzed how different (topographical or biological) cues affect tenogenic differentiation of adipose-derived stem cells (ADSCs). We immobilized platelet-derived growth factor - BB (PDGF-BB) using polydopamine (PD) chemistry on random and aligned nanofibers and investigated ADSC proliferation and tenogenic differentiation. Immobilized PDGF greatly enhanced the proliferation and tenogenic differentiation of ADSCs; however, nanofiber alignment had no effect. Interestingly, the PDGF immobilized aligned nanofiber group showed a synergistic effect with maximum expression of tenogenic markers for 14 days. We also generated a nanofiber surface with spatially controlled presentation of immobilized PDGF on an aligned architecture, mimicking native tendon tissue. A gradient of immobilized PDGF was able to control the phenotypic differentiation of ADSCs into tenocytes in a spatially controlled manner, as confirmed by analysis of the expression of tenogenic markers and immunofluorescence staining. We further explored the gradient formation strategy by generation of a symmetrical gradient on the nanofiber surface for the generation of a structure mimicking bone-patellar-tendon-bone with provision for gradient immobilization of PDGF and controlled mineralization. Our study reveals that, together with biochemical cues, favorable topographical cues are important for tenogenic differentiation of ADSCs, and gradient presentation of PDGF can be used as a tool for engineering stem cell-based bone-tendon interface tissues.

Osteoinductive superparamagnetic Fe nanocrystal/calcium phosphate heterostructured microspheres.

Functional magnetic and biocompatible particles are of great interest because of their potential use in various bioapplications such as hyperthermia for cancer treatment, magnetic resonance imaging (MRI) contrast agents and drug delivery. Herein, we introduce a facile method for synthesizing magnetic Fe nanocrystal/Fe-substituted calcium phosphate (Fe/FeCaP) heterostructured microspheres using a two-step procedure: (1) one-pot hydrothermal synthesis to prepare uniform-sized FeCaP microspheres and (2) post-reduction annealing at 600 °C for Fe extraction from FeCaP. This approach results in the fabrication of Fe/FeCaP heterostructured microspheres that exhibit superparamagnetism with a saturation magnetization of 10.77 emu g-1. The Fe/FeCaP particles annealed at 600 °C show a much higher magnetic moment compared with the non-annealed FeCaP particles. Moreover, T2-weighted MRI phantom images reveal that the Fe/FeCaP heterostructured microspheres possess higher relaxivity than paramagnetic FeCaP, demonstrating their potential as superior and biocompatible MRI contrast agents. Moreover, the enhancement in osteoconductivity for Fe/FeCaP microspheres without any evidence of cytotoxicity was verified. Our results demonstrate the great potential of multi-functional Fe/FeCaP microspheres for use as biocompatible bone regeneration agents as well as MRI contrast agents.

Oxygen-dependent generation of a graded polydopamine coating on nanofibrous materials for controlling stem cell functions.

Substrates modified with gradient surface chemistry are of fundamental importance for designing a new bio-interface in biomaterial research and tissue engineering. However, current gradient fabrication strategies are not easily accessible to most laboratories due to complex, expensive, and expertise-requiring procedures. In this study, we generated a gradient of polydopamine (PD) coating on a PLLA nanofiber surface using a spatially restricted supply of oxygen in the reaction solution. Analysis of the oxygen distribution revealed that oxygen availability varied along different reaction solution depths during dopamine polymerization. We then extensively investigated the effects of different parameters, such as tilting angle, reaction time, pH of the reaction solution, and concentration of dopamine, on PD gradient formation, which should be appropriately modulated for PD gradient on nanofibers. Further, culturing of human mesenchymal stem cells (hMSCs) on the PD gradient nanofiber resulted in a gradient of adhesion and spreading from high to low PD coating. However, the proliferation rate was not affected by the PD gradient, with an approximately 3-fold change after 5 days of culture. Maintenance of the stem cell density gradient on the PD gradient nanofiber resulted in controlled osteogenic differentiation, which was greater in the higher PD-coated area. Interestingly, stemness analysis showed a reverse trend relative to osteogenic differentiation of hMSCs. In summary, the spatially controlled polymerization of dopamine can be a versatile tool to generate substrates with gradient surface chemistry, which holds promise to direct stem cell behavior.

Materials from Mussel-Inspired Chemistry for Cell and Tissue Engineering Applications.

Current advances in biomaterial fabrication techniques have broadened their application in different realms of biomedical engineering, spanning from drug delivery to tissue engineering. The success of biomaterials depends highly on the ability to modulate cell and tissue responses, including cell adhesion, as well as induction of repair and immune processes. Thus, most recent approaches in the field have concentrated on functionalizing biomaterials with different biomolecules intended to evoke cell- and tissue-specific reactions. Marine mussels produce mussel adhesive proteins (MAPs), which help them strongly attach to different surfaces, even under wet conditions in the ocean. Inspired by mussel adhesiveness, scientists discovered that dopamine undergoes self-polymerization at alkaline conditions. This reaction provides a universal coating for metals, polymers, and ceramics, regardless of their chemical and physical properties. Furthermore, this polymerized layer is enriched with catechol groups that enable immobilization of primary amine or thiol-based biomolecules via a simple dipping process. Herein, this review explores the versatile surface modification techniques that have recently been exploited in tissue engineering and summarizes polydopamine polymerization mechanisms, coating process parameters, and effects on substrate properties. A brief discussion of polydopamine-based reactions in the context of engineering various tissue types, including bone, blood vessels, cartilage, nerves, and muscle, is also provided.