@article{ozpinar_frey_arthur_mora-navarro_biehl_snider_cruse_freytes_2021, title={Dermal Extracellular Matrix-Derived Hydrogels as an In Vitro Substrate to Study Mast Cell Maturation}, volume={27}, ISSN={["1937-335X"]}, url={http://www.scopus.com/inward/record.url?eid=2-s2.0-85110277858&partnerID=MN8TOARS}, DOI={10.1089/ten.tea.2020.0142}, abstractNote={Mast cells (MCs) are pro-inflammatory tissue-resident immune cells that play a key role in inflammation. MCs circulate in peripheral blood as progenitors and undergo terminal differentiation in the tissue microenvironment where they can remain for many years. This in situ maturation results in tissue- and species-specific MC phenotypes, culminating in significant variability in response to environmental stimuli. There are many challenges associated with studying mature tissue-derived MCs, particularly in humans. In cases where cultured MCs are able to differentiate in two-dimensional in vitro cultures, there remains an inability for full maturation. Extracellular matrix (ECM) scaffolds provide for a more physiologically relevant environment for cells in vitro and have been shown to modulate the response of other immune cells such as T cells, monocytes, and macrophages. To improve current in vitro testing platforms of MCs and to assess future use of ECM scaffolds for MC regulation, we studied the in vitro response of human MCs cultured on decellularized porcine dermis hydrogels (dermis extracellular matrix hydrogel [dECM-H]). This study investigated the effect of dECM-H on cellular metabolic activity, cell viability, and receptor expression compared to collagen type I hydrogel (Collagen-H). Human MCs showed different metabolic activity when cultured in the dECM-H and also upregulated immunoglobulin E (IgE) receptors associated with MC maturation/activation compared to collagen type I. These results suggest an overall benefit in the long-term culture of human MCs in the dECM-H compared to Collagen-H providing important steps toward a model that is more representative of in vivo conditions. Graphical abstract [Formula: see text] Impact statement Mast cells (MCs) are difficult to culture in vitro as current culture conditions and substrates fail to promote similar phenotypic features observed in vivo. Extracellular matrix (ECM)-based biomaterials offer three-dimensional, tissue-specific environments that more closely resemble in vivo conditions. Our study explores the use of dermal ECM hydrogels for MC culture and shows significant upregulation of metabolic activity, cell viability, and gene expression of markers associated with MC maturation or activation compared to collagen type I-hydrogel and tissue culture plastic controls at 7 days. These results are among the first to describe MC behavior in response to ECM hydrogels.}, number={15-16}, journal={TISSUE ENGINEERING PART A}, author={Ozpinar, Emily W. and Frey, Ariana L. and Arthur, Greer K. and Mora-Navarro, Camilo and Biehl, Andreea and Snider, Douglas B. and Cruse, Glenn and Freytes, Donald O.}, year={2021}, month={Aug}, pages={1008–1022} }
 @article{gaffney_davis_mora-navarro_fisher_freytes_2021, title={Extracellular Matrix Hydrogels Promote Expression of Muscle-Tendon Junction Proteins}, volume={11}, ISSN={["1937-335X"]}, DOI={10.1089/ten.tea.2021.0070}, abstractNote={Muscle and tendon injuries are prevalent and range from minor sprains and strains to traumatic, debilitating injuries. However, the interactions between these tissues during injury and recovery remain unclear. Three-dimensional tissue models that incorporate both tissues and a physiologically relevant junction between muscle and tendon may help understand how the two tissues interact. Here, we use tissue specific extracellular matrix (ECM) derived from muscle and tendon to determine how cells of each tissue interact with the microenvironment of the opposite tissue, resulting in junction-specific features. The ECM materials were derived from the Achilles tendon and gastrocnemius muscle, decellularized, and processed to form tissue-specific pre-hydrogel digests. The ECM materials were unique in respect to protein composition and included many types of ECM proteins, not just collagens. After digestion and gelation, ECM hydrogels had similar complex viscosities that were less than type I collagen hydrogels at the same concentration. C2C12 myoblasts and tendon fibroblasts were cultured in tissue-specific ECM conditioned media or encapsulated in tissue-specific ECM hydrogels to determine cell-matrix interactions and the effects on a muscle-tendon junction marker, paxillin. The ECM conditioned media had only a minor effect on the upregulation of paxillin in cells cultured in monolayer. However, cells cultured within ECM hydrogels had 50-70% higher paxillin expression than cells cultured in type I collagen hydrogels. Contraction of the ECM hydrogels varied by the type of ECM used. Subsequent experiments with a varying density of type I collagen (and thus contraction) showed no correlation between paxillin expression and the amount of gel contraction, suggesting that a constituent of the ECM was the driver of paxillin expression in the ECM hydrogels. In addition, another junction marker, type XXII collagen, had similar expression patterns as paxillin, with smaller effect sizes. Using tissue-specific ECM allowed for the de-construction of the cell-matrix interactions similar to muscle-tendon junctions to study the expression of myotendinous junction-specific proteins. Impact statement The muscle-tendon junction is an important feature of muscle-tendon units; however, despite crosstalk between the two tissue types, the junction is often overlooked in current research. Deconstructing the cell-matrix interactions will provide the opportunity to study significant junction-specific features and markers that should be included in tissue models of the muscle-tendon unit, while gaining a deeper understanding of the natural junction. This research aims at informing future methods to engineer a more relevant multi-tissue platform to study the muscle-tendon unit.}, journal={TISSUE ENGINEERING PART A}, author={Gaffney, Lewis S. and Davis, Zachary G. and Mora-Navarro, Camilo and Fisher, Matthew B. and Freytes, Donald O.}, year={2021}, month={Nov} }
 @article{mora-navarro_ozpinar_sze_martin_freytes_2021, title={Transcriptome-targeted analysis of human peripheral blood-derived macrophages when cultured on biomaterial meshes}, volume={16}, ISSN={["1748-605X"]}, url={http://dx.doi.org/10.1088/1748-605x/abdbdb}, DOI={10.1088/1748-605X/abdbdb}, abstractNote={Surgical meshes are commonly used to repair defects and support soft tissues. Macrophages (Mφs) are critical cells in the wound healing process and are involved in the host response upon foreign biomaterials. There are various commercially available permanent and absorbable meshes used by surgeons for surgical interventions. Polypropylene (PP) meshes represent a permanent biomaterial that can elicit both inflammatory and anti-inflammatory responses. In contrast, poly-4-hydroxybutyrate (P4HB) based meshes are absorbable and linked to positive clinical outcomes but have a poorly characterized immune response. This study evaluated the in vitro targeted transcriptomic response of human Mφs seeded for 48 h on PP and P4HB surgical meshes. The in vitro measured response from human Mφs cultured on P4HB exhibited inflammatory and anti-inflammatory gene expression profiles typically associated with wound healing, which aligns with in vivo animal studies from literature. The work herein provides in vitro evidence for the early transcriptomic targeted signature of human Mφs upon two commonly used surgical meshes. The findings suggest a transition from an inflammatory to a non-inflammatory phenotype by P4HB as well as an upregulation of genes annotated under the pathogen response pathway.}, number={2}, journal={BIOMEDICAL MATERIALS}, publisher={IOP Publishing}, author={Mora-Navarro, Camilo and Ozpinar, Emily W. and Sze, Daphne and Martin, David P. and Freytes, Donald O.}, year={2021}, month={Mar} }