Your search keyword '"Frith, Jessica E."' showing total 23 results

1. Organosilica Nanosensors for Monitoring Spatiotemporal Changes in Oxygen Levels in Bacterial Cultures.

Author

Huynh, Gabriel T., Tunny, Salma S., Frith, Jessica E., Meagher, Laurence, and Corrie, Simon R.

Published

2024

2. Substrate mechanical properties bias MSC paracrine activity and therapeutic potential.

Author

Vilar, Aeolus, Hodgson-Garms, Margeaux, Kusuma, Gina D., Donderwinkel, Ilze, Carthew, James, Tan, Jean L., Lim, Rebecca, and Frith, Jessica E.

Subjects

RECOMBINANT proteins, STROMAL cells, ADIPOGENESIS, NEOVASCULARIZATION, CLINICAL medicine, MACROPHAGES, BIOMATERIALS

Abstract

Mesenchymal stromal cells (MSCs) have significant therapeutic potential due to their ability to differentiate into musculoskeletal lineages suitable for tissue-engineering, as well as the immunomodulatory and pro-regenerative effects of the paracrine factors that these cells secrete. Cues from the extracellular environment, including physical stimuli such as substrate stiffness, are strong drivers of MSC differentiation, but their effects upon MSC paracrine activity are not well understood. This study, therefore sought to determine the impact of substrate stiffness on the paracrine activity of MSCs, analysing both effects on MSC fate and their effect on T-cell and macrophage activity and angiogenesis. The data show that conditioned medium (CM) from MSCs cultured on 0.2 kPa (soft) and 100 kPa (stiff) polyacrylamide hydrogels have differing effects on MSC proliferation and differentiation, with stiff CM promoting proliferation whilst soft CM promoted differentiation. There were also differences in the effects upon macrophage phagocytosis and angiogenesis, with the most beneficial effects from soft CM. Analysis of the media composition identified differences in the levels of proteins including IL-6, OPG, and TIMP-2. Using recombinant proteins and blocking antibodies, we confirmed a role for OPG in modulating MSC proliferation with a complex combination of factors involved in the regulation of MSC differentiation. Together the data confirm that the physical microenvironment has an important influence on the MSC secretome and that this can alter the differentiation and regenerative potential of the cells. These findings can be used to tailor the culture environment for manufacturing potent MSCs for specific clinical applications or to inform the design of biomaterials that enable the retention of MSC activity after delivery into the body. • MSCs cultured on 100 kPa matrices produce a secretome that boosts MSC proliferation • MSCs cultured on 0.2 kPa matrices produce a secretome that promotes MSC osteogenesis and adipogenesis, as well as angiogenesis and macrophage phagocytosis • IL-6 secretion is elevated in MSCs on 0.2 kPa substrates • OPG, TIMP-2, MCP-1, and sTNFR1 secretion are elevated in MSCs on 100 kPa substrates [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

3. Tendon tissue engineering: Current progress towards an optimized tenogenic differentiation protocol for human stem cells.

Author

Donderwinkel, Ilze, Tuan, Rocky S., Cameron, Neil R., and Frith, Jessica E.

Subjects

TENDONS (Prestressed concrete), HUMAN stem cells, TISSUE engineering, TENDON injury healing, TISSUE differentiation, CELL anatomy

Abstract

Tendons are integral to our daily lives by allowing movement and locomotion but are frequently injured, leading to patient discomfort and impaired mobility. Current clinical procedures are unable to fully restore the native structure of the tendon, resulting in loss of full functionality, and the weakened tissue following repair often re-ruptures. Tendon tissue engineering, involving the combination of cells with biomaterial scaffolds to form new tendon tissue, holds promise to improve patient outcomes. A key requirement for efficacy in promoting tendon tissue formation is the optimal differentiation of the starting cell populations, most commonly adult tissue-derived mesenchymal stem/stromal cells (MSCs), into tenocytes, the predominant cellular component of tendon tissue. Currently, a lack of consensus on the protocols for effective tenogenic differentiation is hampering progress in tendon tissue engineering. In this review, we discuss the current state of knowledge regarding human stem cell differentiation towards tenocytes and tendon tissue formation. Tendon development and healing mechanisms are described, followed by a comprehensive overview of the current protocols for tenogenic differentiation, including the effects of biochemical and biophysical cues, and their combination, on tenogenesis. Lastly, a synthesis of the key features of these protocols is used to design future approaches. The holistic evaluation of current knowledge should facilitate and expedite the development of efficacious stem cell tenogenic differentiation protocols with future impact in tendon tissue engineering. The lack of a widely-adopted tenogenic differentiation protocol has been a major hurdle in the tendon tissue engineering field. Building on current knowledge on tendon development and tendon healing, this review surveys peer-reviewed protocols to present a holistic evaluation and propose a pathway to facilitate and expedite the development of a consensus protocol for stem cell tenogenic differentiation and tendon tissue engineering. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

4. The Bumpy Road to Stem Cell Therapies: Rational Design of Surface Topographies to Dictate Stem Cell Mechanotransduction and Fate.

Author

Carthew, James, Taylor, Jason B. J., Garcia-Cruz, Maria R., Kiaie, Nasim, Voelcker, Nicolas H., Cadarso, Victor J., and Frith, Jessica E

Published

2022

5. The ChemoArchiChip: Interrogating the response of macrophages to the chemistry and geometry of microscale 3D objects

Author

Frith, Jessica E.

Abstract

Effective integration of biomedical implants requires understanding and control of interactions between cells and the implant surface. High-throughput screening and modeling can identify properties that elicit desired cell behaviors and reveal patterns to underpin the future development of general design rules. Recently in Matter, Vassey et al. developed the ChemoArchiChip to investigate effects of microscale 3D objects with varied material chemistry on the adhesion and polarization of macrophages. The study shows the power of screening and modeling to generate understanding of cell-biomaterial interactions and provides specific knowledge of conditions to modulate the macrophage response.

Published

2023

6. Delivery of miRNAs Using Porous Silicon Nanoparticles Incorporated into 3D Hydrogels Enhances MSC Osteogenesis by Modulation of Fatty Acid Signaling and Silicon Degradation

Author

Shrestha, Surakshya, Tieu, Terence, Wojnilowicz, Marcin, Voelcker, Nicolas H., Forsythe, John S., and Frith, Jessica E.

Abstract

Strategies incorporating mesenchymal stromal cells (MSC), hydrogels and osteoinductive signals offer promise for bone repair. Osteoinductive signals such as growth factors face challenges in clinical translation due to their high cost, low stability and immunogenicity leading to interest in microRNAs as a simple, inexpensive and powerful alternative. The selection of appropriate miRNA candidates and their efficient delivery must be optimised to make this a reality. This study evaluated pro‐osteogenic miRNAs and used porous silicon nanoparticles modified with polyamidoamine dendrimers (PAMAM‐pSiNP) to deliver these to MSC encapsulated within gelatin‐PEG hydrogels. miR‐29b‐3p, miR‐101‐3p and miR‐125b‐5p are strongly pro‐osteogenic and are shown to target FASN and ELOVL4 in the fatty acid biosynthesis pathway to modulate MSC osteogenesis. Hydrogel delivery of miRNA:PAMAM‐pSiNP complexes enhanced transfection compared to 2D. The osteogenic potential of hBMSC in hydrogels with miR125b:PAMAM‐pSiNP complexes is evaluated. Importantly, a dual‐effect on osteogenesis occurred, with miRNAs increasing expression of alkaline phosphatase (ALP) and Runt‐related transcription factor 2 (RUNX2) whilst the pSiNPs enhanced mineralisation, likely via degradation into silicic acid. Overall, this work presents insights into the role of miRNAs and fatty acid signalling in osteogenesis, providing future targets to improve bone formation and a promising system to enhance bone tissue engineering. Hydrogel delivery of miRNAs to promote mesenchymal stromal cell (MSC) osteogenesis shows great promise for tissue engineering, but challenges with the selection of appropriate miRNAs and their efficient delivery must be overcome. This study develops and characterizes a new system in which pro‐osteogenic miRNAs are complexed with porous silicon nanoparticles and encapsulated alongside MSCs in gelatin‐PEG hydrogels. Findings highlight miRNA modulation of fatty acid signaling as an important pathway in osteogenesis while the overall system enhances bone formation by two mechanisms, miRNA modulation of gene expression, and via the beneficial effects of silicon nanoparticle degradation on mineralization.

Published

2024

7. The Bumpy Road to Stem Cell Therapies: Rational Design of Surface Topographies to Dictate Stem Cell Mechanotransduction and Fate

Author

Carthew, James, Taylor, Jason B. J., Garcia-Cruz, Maria R., Kiaie, Nasim, Voelcker, Nicolas H., Cadarso, Victor J., and Frith, Jessica E

Abstract

Cells sense and respond to a variety of physical cues from their surrounding microenvironment, and these are interpreted through mechanotransductive processes to inform their behavior. These mechanisms have particular relevance to stem cells, where control of stem cell proliferation, potency, and differentiation is key to their successful application in regenerative medicine. It is increasingly recognized that surface micro- and nanotopographies influence stem cell behavior and may represent a powerful tool with which to direct the morphology and fate of stem cells. Current progress toward this goal has been driven by combined advances in fabrication technologies and cell biology. Here, the capacity to generate precisely defined micro- and nanoscale topographies has facilitated the studies that provide knowledge of the mechanotransducive processes that govern the cellular response as well as knowledge of the specific features that can drive cells toward a defined differentiation outcome. However, the path forward is not fully defined, and the “bumpy road” that lays ahead must be crossed before the full potential of these approaches can be fully exploited. This review focuses on the challenges and opportunities in applying micro- and nanotopographies to dictate stem cell fate for regenerative medicine. Here, key techniques used to produce topographic features are reviewed, such as photolithography, block copolymer lithography, electron beam lithography, nanoimprint lithography, soft lithography, scanning probe lithography, colloidal lithography, electrospinning, and surface roughening, alongside their advantages and disadvantages. The biological impacts of surface topographies are then discussed, including the current understanding of the mechanotransductive mechanisms by which these cues are interpreted by the cells, as well as the specific effects of surface topographies on cell differentiation and fate. Finally, considerations in translating these technologies and their future prospects are evaluated.

Published

2022

8. Stability and Performance Study of Fluorescent Organosilica pH Nanosensors.

Author

Huynh, Gabriel T., Henderson, Edward C., Frith, Jessica E., Meagher, Laurence, and Corrie, Simon R.

Published

2021

9. Osteogenic Potential of Additively Manufactured TiTa Alloys.

Author

Brodie, Erin G., Robinson, Kye J., Sigston, Elizabeth, Molotnikov, Andrey, and Frith, Jessica E.

Published

2021

10. Interplay of Hydrogel Composition and Geometry on Human Mesenchymal Stem Cell Osteogenesis.

Author

Shrestha, Surakshya, Li, Fanyi, Truong, Vinh X., Forsythe, John S., and Frith, Jessica E.

Published

2020

11. Stability and Performance Study of Fluorescent Organosilica pH Nanosensors

Author

Huynh, Gabriel T., Henderson, Edward C., Frith, Jessica E., Meagher, Laurence, and Corrie, Simon R.

Abstract

Long-term stability and function are key challenges for optical nanosensors operating in complex biological environments. While much focus is rightly placed on issues related to specificity, sensitivity, reversibility, and response time, many nanosensors are not capable of transducing accurate results over prolonged time periods. Sensors could fail over time due to the degradation of scaffold material, degradation of signaling dyes and components, or a combination of both. It is critical to investigate how such degradative processes affect sensor output, as the consequences could be severe. Herein, we used fluorescent core–shell organosilica pH nanosensors as a model system, incubating them in a range of common aqueous solutions over time at different temperatures, and then searched for changes in fluorescence signal, particle size, and evidence of silica degradation. We found that these ratiometric nanosensors produced stable optical signals after aging for 30 days at 37 °C in standard saline buffers with and without 10% fetal bovine serum, and without any evidence of material degradation. Next, we evaluated their performance as real-time pH nanosensors in bacterial suspension cultures, observing a close agreement with a pH electrode for control nanosensors, yet observing obvious deviations in signal based on the aging conditions. The results show that while the organosilica scaffold does not degrade appreciably over time, careful selection of dyes and further systematic investigations into the effects of salt and protein levels are required to realize long-term stable nanosensors.

Published

2021

12. Interplay of Hydrogel Composition and Geometry on Human Mesenchymal Stem Cell Osteogenesis

Author

Shrestha, Surakshya, Li, Fanyi, Truong, Vinh X., Forsythe, John S., and Frith, Jessica E.

Abstract

Microgels are emerging as an outstanding platform for tissue regeneration because they overcome issues associated with conventional bulk/macroscopic hydrogels such as limited cell–cell contact and cell communication and low diffusion rates. Owing to the enhanced mass transfer and injectability via a minimally invasive procedure, these microgels are becoming a promising approach for bone regeneration applications. Nevertheless, there still remains a huge gap between the understanding of how the hydrogel matrix composition can influence cell response and overall tissue formation when switching from bulk formats to microgel format, which is often neglected or rarely studied. Here, we fabricated polyethylene glycol-based microgels and bulk hydrogels incorporating gelatin and hyaluronic acid (HA), either individually or together, and assessed the impact of both hydrogel composition and format upon the osteogenic differentiation of encapsulated human bone marrow-derived mesenchymal stem cells (hBMSCs). Osteogenesis was significantly greater in microgels than bulk hydrogels for both gelatin alone (Gel) and gelatin HA composite (Gel:HA) hydrogels, as determined by the expression of Runt-related transcription factor (Runx2) and alkaline phosphatase (ALP) genes and mineral deposition. Interestingly, Gel and Gel:HA hydrogels behaved differently between bulk and microgel format. In bulk format, overall osteogenic outcomes were better in Gel:HA hydrogels, but in microgel format, while the level of osteogenic gene expression was equivalent between both compositions, the degree of mineralization was reduced in Gel:HA microgels. Investigation into the affinity of hydroxyapatite for the different matrix compositions indicated that the decreased mineralization of Gel:HA microgels was likely due to a low affinity of hydroxyapatite to bind to HA and support mineral deposition, which has a greater impact on microgels than bulk hydrogels. Together, these findings suggest that both hydrogel composition and format can determine the success of tissue formation and that there is a complex interplay of these two factors on both cell behavior and matrix deposition. This has important implications for tissue engineering, showing that hydrogel composition and geometry must be evaluated together when optimizing conditions for cell differentiation and tissue formation.

Published

2020

13. Microencapsulation improves chondrogenesis in vitroand cartilaginous matrix stability in vivocompared to bulk encapsulationElectronic supplementary information (ESI) available. See DOI: 10.1039/c9bm01524h

Author

LiThese authors contributed equally., Fanyi, Levinson, Clara, Truong, Vinh X., Laurent-Applegate, Lee Ann, Maniura-Weber, Katharina, Thissen, Helmut, Forsythe, John S., Zenobi-Wong, Marcy, and Frith, Jessica E.

Abstract

The encapsulation of cells into microgels is attractive for applications in tissue regeneration. While cells are protected against shear stress during injection, the assembly of microgels after injection into a tissue defect also forms a macroporous scaffold that allows effective nutrient transport throughout the construct. However, in most of current strategies that form microgel-based macroporous scaffold or higher-order structures, cells are seeded during or post the assembly process and not microencapsulated in situ. The objective of this study is to investigate the chondrogenic phenotype of microencapsulated fetal chondrocytes in a biocompatible, assembled microgel system vs. bulk gels and to test the stability of the constructs in vivo. Here, we demonstrate that cell microencapsulation leads to increased expression of cartilage-specific genes in a TGF-β1-dependent manner. This correlates, as shown by histological staining, with the ability of microencapsulated cells to deposit cartilaginous matrix after migrating to the surface of the microgels, while keeping a macroscopic granular morphology. Implantation of precultured scaffolds in a subcutaneous mouse model results in vessel infiltration in bulk gels but not in assembled microgels, suggesting a higher stability of the matrix produced by the cells in the assembled microgel constructs. The cells are able to remodel the microgels as demonstrated by the gradual disappearance of the granular structure in vivo. The biocompatible microencapsulation and microgel assembly system presented in this article therefore hold great promise as an injectable system for cartilage repair.

Published

2020

14. Comparison of the Microstructure and Biocorrosion Properties of Additively Manufactured and Conventionally Fabricated near β Ti-25Nb-3Zr-3Mo-2Sn Alloy.

Author

Dargusch, Matthew S., Gui Wang, Kent, Damon, Bermingham, Michael, Venezuela, Jeffrey, Frith, Jessica E., Yu, Zhentao, Yu, Sen, and Shi, Zhiming

Published

2019

15. Five Piconewtons: The Difference between Osteogenic and Adipogenic Fate Choice in Human Mesenchymal Stem Cells.

Author

Pingping Han, Frith, Jessica E., Gomez, Guillermo A., Yap, Alpha S., O'Neill, Geraldine M., and Cooper-White, Justin J.

Published

2019

16. Cartilage tissue formation through assembly of microgels containing mesenchymal stem cells.

Author

Li, Fanyi, Truong, Vinh X., Fisch, Philipp, Levinson, Clara, Glattauer, Veronica, Zenobi-Wong, Marcy, Thissen, Helmut, Forsythe, John S., and Frith, Jessica E.

Subjects

MESENCHYMAL stem cells, CARTILAGE, GLYCOSAMINOGLYCANS, MUCOPOLYSACCHARIDES, MICROGELS

Abstract

Current clinical approaches to treat articular cartilage degeneration provide only a limited ability to regenerate tissue with long-term durability and functionality. In this application, injectable bulk hydrogels and microgels containing stem cells can provide a suitable environment for tissue regeneration. However insufficient cell–cell interactions, low differentiation efficiency and poor tissue adhesion hinder the formation of high-quality hyaline type cartilage. Here, we have designed a higher order tissue-like structure using injectable cell-laden microgels as the building blocks to achieve human bone marrow-derived mesenchymal stem cell (hBMSC) long-term maintenance and chondrogenesis. We have demonstrated that a 4-arm poly(ethylene glycol)- N -hydroxysuccinimide (NHS) crosslinker induces covalent bonding between the microgel building blocks as well as the surrounding tissue mimic. The crosslinking process assembles the microgels into a 3D construct and preserves the viability and cellular functions of the encapsulated hBMSCs. This assembled microgel construct encourages upregulation of chondrogenic markers in both gene and glycosaminoglycan (GAG) expression levels. In addition, the regenerated tissue in the assembled microgels stained positively with Alcian blue and Safranin O exhibiting unique hyaline-like cartilage features. Furthermore, the immunostaining showed a favourable distribution and significantly higher content of type II collagen in the assembled microgels when compared to both the bulk hydrogel and pellet cultures. Collectively, this tissue adhesive hBMSC-laden microgel construct provides potential clinical opportunities for articular cartilage repair and other applications in regenerative medicine. Statement of Significance A reliable approach to reconstruct durable and fully functional articular cartilage tissue is required for effective clinical therapies. Here, injectable hydrogels together with cell-based therapies offer new treatment strategies in cartilage repair. For effective cartilage regeneration, the injectable hydrogel system needs to be bonded to the surrounding tissue and at the same time needs to be sufficiently stable for prolonged chondrogenesis. In this work, we utilised injectable hBMSC-laden microgels as the building blocks to create an assembled construct via N -hydroxysuccinimide-amine coupling. This crosslinking process also allows for rapid bonding between the assembled microgels and a surrounding tissue mimic. The resultant assembled microgel-construct provides both a physically stable and biologically dynamic environment for hBMSC chondrogenesis, leading to the production of a mature hyaline type cartilage structure. [ABSTRACT FROM AUTHOR]

Published

2018

17. Comparison of the Microstructure and Biocorrosion Properties of Additively Manufactured and Conventionally Fabricated near β Ti–25Nb–3Zr–3Mo–2Sn Alloy

Author

Dargusch, Matthew S., Wang, Gui, Kent, Damon, Bermingham, Michael, Venezuela, Jeffrey, Frith, Jessica E., Yu, Zhentao, Yu, Sen, and Shi, Zhiming

Abstract

The microstructure and biodegradability of a near β Ti–25Nb–3Zr–3Mo–2Sn alloy produced by laser engineered net shaping have been compared to those of alloys produced via casting and cold rolling in order to identify the key effects of processing pathways on the development of microstructure and biocorrosion properties. Results confirm the significant influence of processing technique on microstructure and concomitant biocompatibility of the alloy. Tests using mesenchymal stem cells confirm the ability of the additively manufactured alloy to support cell adhesion and spreading.

Published

2019

18. Five Piconewtons: The Difference between Osteogenic and Adipogenic Fate Choice in Human Mesenchymal Stem Cells

Author

Han, Pingping, Frith, Jessica E., Gomez, Guillermo A., Yap, Alpha S., O’Neill, Geraldine M., and Cooper-White, Justin J.

Abstract

The ability of mesenchymal stem cells to sense nanoscale variations in extracellular matrix (ECM) compositions in their local microenvironment is crucial to their survival and their fate; however, the underlying molecular mechanisms defining how such fates are temporally modulated remain poorly understood. In this work, we have utilized self-assembled block copolymer surfaces to present nanodomains of an adhesive peptide found in many ECM proteins at different lateral spacings (from 30 to 60 nm) and studied the temporal response (2 h to 14 days) of human mesenchymal stem cells (hMSCs) using a panel of real-time localization and activity biosensors. Our findings revealed that within the first 4 to 24 h postadhesion and spreading, hMSCs on smaller nanodomain spacings recruit more activated FAK and Src proteins to produce larger, longer-lived, and increased numbers of focal adhesions (FAs). The adhesions formed on smaller nanospacings rapidly recruit higher amounts of nonmuscle myosin IIA and vinculin and experience tension forces (by >5 pN/FA) significantly higher than those observed on larger nanodomain spacings. The transmission of higher levels of tension into the cytoskeleton at short times was accompanied by higher Rac1, cytosolic β-catenin, and nuclear localization of YAP/TAZ and RUNX2, which together biased the commitment of hMSCs to an osteogenic fate. This investigation provides mechanistic insights to confirm that smaller lateral spacings of adhesive nanodomains alter hMSC mechanosensing and biases mechanotransduction at short times viadifferential coupling of FAK/Src/Rac1/myosin IIA/YAP/TAZ signaling pathways to support longer-term changes in stem cell differentiation and state.

Published

2019

19. Microfluidic Encapsulation of Human Mesenchymal Stem Cells for Articular Cartilage Tissue Regeneration

Author

Li, Fanyi, Truong, Vinh X., Thissen, Helmut, Frith, Jessica E., and Forsythe, John S.

Abstract

Stem cell injections for the treatment of articular cartilage damage are a promising approach to achieve tissue regeneration. However, this method is encumbered by high cell apoptosis rates, low retention in the cartilage lesion, and inefficient chondrogenesis. Here, we have used a facile, very low cost-based microfluidic technique to create visible light-cured microgels composed of gelatin norbornene (GelNB) and a poly(ethylene glycol) (PEG) cross-linker. In addition, we have demonstrated that the process enables the rapid in situmicroencapsulation of human bone marrow-derived mesenchymal stem cells (hBMSCs) under biocompatible microfluidic-processing conditions for long-term maintenance. The hBMSCs exhibited an unusually high degree of chondrogenesis in the GelNB microgels with chondro-inductive media, specifically toward the hyaline cartilage structure, with significant upregulation in type II collagen expression compared to the bulk hydrogel and “gold standard” pellet culture. Overall, we have demonstrated that these protein-based microgels can be engineered as promising therapeutic candidates for articular cartilage regeneration, with additional potential to be used in a variety of other applications in regenerative medicine.

Published

2017

20. Cell Microencapsulation within Gelatin-PEG Microgels Using a Simple Pipet Tip-Based Device

Author

Nguyen, Thuy P. T., Li, Fanyi, Hung, Brendan, Truong, Vinh Xuan, Thissen, Helmut, Forsythe, John S., and Frith, Jessica E.

Abstract

Microgels are microscale particles of hydrogel that can be laden with cells and used to create macroporous tissue constructs. Their ability to support cell–ECM and cell–cell interactions, along with the high levels of nutrient and metabolite exchange facilitated by their high surface area-to-volume ratio, means that they are attracting increasing attention for a variety of tissue regeneration applications. Here, we present methods for fabricating and modifying the structure of microfluidic devices using commonly available laboratory consumables including pipet tips and PTFE and silicon tubing to produce microgels. Different microfluidic devices realized the controlled generation of a wide size range (130–800 μm) of microgels for cell encapsulation. Subsequently, we describe the process of encapsulating mesenchymal stromal cells in microgels formed by photo-cross-linking of gelatin-norbornene and PEG dithiol. The introduced pipet-based chip offers simplicity, tunability, and versatility, making it easily assembled in most laboratories to effectively produce cell-laden microgels for various applications in tissue engineering.

Published

2023

21. A systematic investigation of the effects of TGF-β3 and mechanical stimulation on tenogenic differentiation of mesenchymal stromal cells in a poly(ethylene glycol)/gelatin-based hydrogel

Author

Donderwinkel, Ilze, Tuan, Rocky S., Cameron, Neil R., and Frith, Jessica E.

Abstract

High post-surgical failure rates following tendon injury generate high medical costs and poor patient recovery. Cell-based tendon tissue engineering has the potential to produce fully functional replacement tissue and provide new strategies to restore tendon function and healing. In this endeavour, the application of mesenchymal stromal cells (MSCs) encapsulated in biomaterial scaffolds has shown great promise. However, a consensus on optimal promotion of tenogenic differentiation of MSCs has yet to be reached, although growth factors and mechanical cues are generally acknowledged as important factors.

Published

2023

22. Effect of Geometric Challenges on Cell Migration

Author

Mills, Richard J., Frith, Jessica E., Hudson, James E., and Cooper-White, Justin J.

Abstract

Cellular infiltration and colonization of three-dimensional (3D) porous scaffolds is influenced by many factors. One of the major factors is the internal architecture presented to the cells. In this work, we have developed and validated a microfluidic device that presents a multitude of geometric challenges to cells, mimicking the architectural aspects and characteristics of 3D porous scaffolds in a two-dimensional arrangement. This device has been utilized to investigate the influence of varying channel widths, degrees of channel tortuosity, the presence of contractions or expansions, and channel junctions on the migration of NIH 3T3 mouse fibroblasts and human bone marrow-derived mesenchymal stromal cell (hMSCs). These two cell types were observed to have vastly different migration characteristics; 3T3 fibroblasts migrate as a collective cell front, whereas hMSCs migrate as single cells. This resulted in 3T3 fibroblasts displaying significant differences in migration depending on the type of geometrical constraint, whereas hMSCs were only influenced by channel width when it approached that of the length scale of a single cell. The differences in migration characteristics were shown to be related to the expression of the intercellular junction protein N-cadherin. We observed that 3T3 fibroblasts express higher levels of N-cadherin than hMSCs and that N-cadherin inhibition modified the migration characteristics of the 3T3 fibroblasts, so that they were then similar to that of hMSCs. The results of this study both confirm the utility of the device and highlight that differences in migration characteristics of different cell types can be deterministic of how they may respond to geometric constraints within porous tissue engineering constructs.

Published

2011

23. Dynamic Three-Dimensional Culture Methods Enhance Mesenchymal Stem Cell Properties and Increase Therapeutic Potential

Author

Frith, Jessica E., Thomson, Brian, and Genever, Paul G.

Abstract

Mesenchymal stem cells (MSCs) are capable of self-renewal and differentiation along the osteogenic, chondrogenic, and adipogenic lineages and have potential applications in a range of therapies. MSCs can be cultured as monolayers on tissue culture plastic, but there are indications that they lose cell-specific properties with time in vitroand so poorly reflect in vivoMSC behavior. We developed dynamic three-dimensional (3D) techniques for in vitroMSC culture using spinner flasks and a rotating wall vessel bioreactor. We characterized the two methods for dynamic 3D MSC culture and compared the properties of these cultures with monolayer MSCs. Our results showed that under optimal conditions, MSCs form compact cellular spheroids and remain viable in dynamic 3D culture. We demonstrated altered cell size and surface antigen expression together with enhanced osteogenic and adipogenic differentiation potential in MSCs from dynamic 3D conditions. By microarray analysis of monolayer and spinner flask MSCs, we identified many differences in gene expression, including those confirming widespread changes to the cellular architecture and extracellular matrix. The upregulation of interleukin 24 in dynamic 3D cultures was shown to selectively impair the viability of prostate cancer cells cultured in medium conditioned by dynamic 3D MSCs. Overall, this work suggests a novel therapeutic application for dynamic 3D MSCs and demonstrates that these methods are a viable alternative to monolayer techniques and may prove beneficial for retaining MSC properties in vitro.

Published

2010