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Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_1 | Pages 91 - 91
2 Jan 2024
Graça A Rodrigues M Domingues R Gomes M Gomez-Florit M
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Macrophages play a critical role in innate immunity by promoting or inhibiting tissue inflammation and repair. Classically, macrophages can differentiate into either pro-inflammatory (M1) or pro-reparative (M2) phenotypes in response to various stimuli. Therefore, this study aimed to address how extracellular vesicles (EVs) derived from polarized macrophages can affect the inflammatory response of tendon cells.

For that purpose, human THP-1 cells were stimulated with lipopolysaccharide (LPS), and interleukins -4 and -13 (IL- 4, IL-13), to induce macrophages polarization into M1, M2, and hybrid M1/M2 phenotypes. Subsequently, the EVs were isolated from the culture medium by ultracentrifugation. The impact of these nanovesicles on the inflammation and injury scenarios of human tendon-derived cells (hTDCs), which had previously been stimulated with interleukin- 1 beta (IL-1ß) to mimic an inflammatory scenario, was assessed.

We were able to isolate three different nanovesicles populations, showing the typical shape, size and surface markers of EVs. By extensively analyzing the proteomic expression profiles of M1, M2, and M1/M2, distinct proteins that were upregulated in each type of macrophage-derived EVs were identified. Notably, most of the detected pro- inflammatory cytokines and chemokines had higher expression levels in M1-derived EVs and were mostly absent in M2-derived EVs. Hence, by acting as a biological cue, we observed that M2 macrophage-derived EVs increased the expression of the tendon-related marker tenomodulin (TNMD) and tended to reduce the presence of pro-inflammatory markers in hTDCs. Overall, these preliminary results show that EVs derived from polarized macrophages might be a potential tool to modulate the immune system responses becoming a valuable asset in the tendon repair and regeneration fields worthy to be further explored.


Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_1 | Pages 94 - 94
2 Jan 2024
Graça A Domingues R Docheva D Gomez-Florit M Gomes M
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Worldwide, tendon disorders are one of the main causes of disability that decrease the quality of life of individuals and represent a substantial economic burden on society. Currently, the main therapies used for tendon injuries are not able to restore tendon functionality, and due to tendons' hypovascular and hypocellular nature, they present a reduced healing capacity, which also limits the success of the available therapies. In order to discover new therapies, extracellular vesicles (EVs), key players in cell-cell communication, have been widely explored for tissue engineering and regenerative medicine applications. Thus, the aim of this study is to assess the role of EVs derived from platelets in stem cell tenogenic commitment using a bioengineered tendon in vitro model for potential use as tendon therapeutic agents. Biomimetic platelet-derived EVs were produced by freeze-thaw cycles of platelets and isolation at different centrifugation speed. To recreate the architecture of tendons, a 3D system consisting of electrospun anisotropic nanofiber scaffolds coated with collagen encapsulating human adipose stem cells (hASCs) and different types of platelet-derived EVs, were produced. Then, the influence of the tendon-mimetic constructs and the distinct EVs populations in the hASCs tenogenic differentiation were assessed over culture time. We observed that the hASCs on the nanofibrous tendon scaffolds, show high cytoskeleton anisotropic organization that is characteristic of tenocytes. Moreover, acting as biological cues, platelet-derived EVs boosted hASCs tenogenic commitment, supported by the increased gene expression of tendon-related markers (SCX and TNMD). Additionally, EVs enhanced the deposition of tendon like extracellular matrix (ECM), as evidenced by the increased gene expression of ECM-related markers such as COL1, COL3, DCN, TNC, and MMP-3, which are fundamental for ECM synthesis and degradation balance. Moreover, EVs induced lower collagen matrix contraction on hASCs, which has been related with lower myofibroblast differentiation. Overall, the results revealed that EVs are capable of modulating stem cells' behavior boosting their tenogenic commitment, through the increased expression of healthy tendon cell markers, potentiating ECM deposition and decreasing cell contractility. Therefore, platelet EVs are a promising biochemical tool, worthy to be further explored, as paracrine signaling that might potentiate tendon repair and regeneration.


Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_1 | Pages 13 - 13
2 Jan 2024
Teixeira S Pardo A Bakht S Gomez-Florit M Reis R Gomes M Domingues R
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Tendon diseases are prevalent health concerns for which current therapies present limited success, in part due to the intrinsically low regenerative ability of tendons. Therefore, tissue engineering presents a potential to improve this outcome. Here, we hypothesize that a concurrent control over both biophysical and biochemical stimuli will boost the tenogenic commitment of stem cells, thus promoting regeneration. To achieve this, we combine molecularly imprinted nanoparticles (MINPs), which act as artificial amplifiers for endogenous growth factor (GF) activity, with bioinspired anisotropic hydrogels2 to manufacture 3D tenogenic constructs. MINPs were solid phase-imprinted using a TGF-β3 epitope as template and their affinity for the target was assessed by SPR and dot blot. Magnetically-responsive microfibers were produced by cryosectioning electrospun meshes containing iron oxide nanoparticles. The constructs were prepared by encapsulating adipose tissue-derived stem cells (ASCs), microfibers, and MINPs within gelatin hydrogels, while aligning the microfibers with an external magnetostatic field during gelation. This allows an effective modulation of hydrogel fibrillar topography, mimicking the native tissue's anisotropic architecture. Cell responses were analyzed by multiplex immunoassay, quantitative polymerase chain reaction, and immunocytochemistry. MINPs showed an affinity for the template comparable to monoclonal antibodies. Encapsulated ASCs acquired an elongated shape and predominant orientation along the alignment direction. Cellular studies revealed that combining MINPs with aligned microfibers increased TGF-β signaling via non-canonical Akt/ERK pathways and upregulated tendon-associated gene expression, contrasting with randomly oriented gels. Immunostaining of tendon-related proteins presented analogous outcomes, corroborating our hypothesis.

Our results thus demonstrate that microstructural cues and biological signals synergistically direct stem cell fate commitment, suggesting that this strategy holds potential for improving tendon healing and might be adaptable for other biological tissues. The proposed concept highlights the GF-sequestering ability of MINPs which allows a cost-effective alternative to recombinant GF supplementation, potentially decreasing the translational costs of tissue engineering strategies.

Acknowledgements: The authors acknowledge the funding from the European Union's Horizon 2020 under grant No. 772817; from FCT/MCTES for scholarships PD/BD/143039/2018 & COVID/BD/153025/2022 (S.P.B.T.), and PD/BD/129403/2017 (S.M.B.), co-financed by POCH and NORTE 2020, under the Portugal 2020 partnership agreement through the European Social Fund, for contract 2020.03410.CEECIND (R.M.A.D.) and project 2022.05526.PTDC; and from Xunta de Galicia for grant ED481B2019/025 (A.P.).


Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_1 | Pages 31 - 31
2 Jan 2024
Negri S Yea J Gomez-Salazar M Onggo S Li Z Thottappillil N Cherief M Xing X Qin Q Tower R Fan C Levi B James A
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Heterotopic ossification (HO) is defined as aberrant bone formation in extraskeletal locations. In this process, local stromal cells of mesenchymal origin abnormally differentiate, resulting in pathologic cartilage and bone matrix deposition. However, the specific cell type and mechanisms beyond this process are not well understood, in part due to the heterogeneity of progenitor cells involved. Here, a combination of single cell RNA sequencing (scRNA-Seq) and lineage tracing, defined the extent to which synovial / tendon sheath progenitor cells contribute to HO. For this purpose, a Tppp3 (tubulin polymerization-promoting protein family member 3) inducible reporter model was used, in combination with either Scx (Scleraxis) or Pdgfra (Platelet derived growth factor receptor alpha) reporter animals. Both arthroplasty-induced and tendon injury-mouse experimental HO models were utilized. ScRNA-Seq of tendon-induced traumatic HO suggested that Tppp3 is a progenitor cell marker for either osteochondral or tendon or cells. After HO induction, Tppp3 reporter+ cell population expanded in number and contributed to cartilage and bone formation in tendon and joint-associated HO. Using double reporter animals, we found that both Pdgfra+Tppp3+ and Pdgfra+Tppp3- progenitor cells produced HO-associated cartilage. Finally, the examination of human samples showed a significant population of TPPP3+ cells overlapping with osteogenic markers in areas of HO. Overall, these results provide novel observations that peritenon and synovial progenitor cells undergo abnormal osteochondral differentiation and contribute to heterotopic bone formation after trauma.


Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_1 | Pages 36 - 36
2 Jan 2024
Bagur-Cardona S Perez-Romero K Stiliyanov K Calvo J Gayà A Barceló-Coblijn G Rodriguez RM Gomez-Florit M
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Macrophages (Mφ) are immune cells that play a crucial role in both innate and adaptive immunity as they are involved in a wide range of physiological and pathological processes. Depending on the microenvironment and signals present, Mφ can polarize into either M1 or M2 phenotypes, with M1 macrophages exhibiting pro-inflammatory and cytotoxic effects, while M2 macrophages having immunosuppressive and tissue repair properties. Macrophages have been shown to play key roles in the development and progression or inhibition of various diseases, including cancer. For example, macrophages can stimulate tumor progression by promoting immunosuppression, angiogenesis, invasion, and metastasis. This work aimed to investigate the effect of extracellular vesicles (EVs)-derived from polarized macrophages on an osteosarcoma cell line. Monocytes were extracted from buffy coats and cultured in RPMI medium with platelet lysate or M-CSF. After 6 days of seeding, Mφ were differentiated into M1 and M2 with INF-γ/LPS and IL-4/IL-13, respectively. The medium with M1 or M2 derived EVs was collected and EVs were isolated by differential centrifugation and size exclusion chromatography and its morphology and size were characterized with SEM and NTA, respectively. The presence of typical EVs markers (CD9, CD63) was assessed by Western Blot. Finally, EVs from M1 or M2-polarized Mφ were added onto osteosarcoma cell cultures and their effect on cell viability and cell cycle, proliferation, and gene expression was assessed. The EVs showed the typical shape, size and surface markers of EVs. Overall, we observed that osteosarcoma cells responded differentially to EVs isolated from the M1 and M2-polarized Mφ. In summary, the use of Mφ-derived EVs for the treatment of osteosarcoma and other cancers deserves further study as it could benefit from interesting traits of EVs such as low immunogenicity, nontoxicity, and ability to pass through tissue barriers.

Acknowledgements: Carlos III Health Institute and the European Social Fund for contract CP21/00136 and project PI22/01686.


Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_2 | Pages 15 - 15
2 Jan 2024
Monteiro R Bakht S Gomez-Florit M Reis R Gomes M Domingues R
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Relevant in vitro models emulating tendinopathies are highly needed to study these diseases and develop better treatments. We have recently proposed a new strategy that allows the automated 3D writing of microphysiological systems (MPS) embedded into its own biomimetic fibrillar support platform based on the self-assembling of cellulose nanocrystals (CNCs). Here, we explored this CNC platform for writing humanized in vitro tendon models using tendon decellularized extracellular matrix (dECM)-based bioinks to closely recapitulate the biophysical and biochemical cues of tendon cell niche and self-induce the tenogenic differentiation of stem cells. The proposed concept was further explored to study the crosstalk between the tendon core and vascular compartment.

Porcine flexor tendons were decellularized to produce the dECM bioink hydrogel. hASCs were used as cell source and the bioink was directly printed within the CNC fluid gel. Tendon constructs were co-printed with compartmentalized microvascular structures to evaluate the cellular crosstalk with endothelial cells. The tendon-on-chip models showed high cell viability and proliferation during culture up to 21 days, and the synergy between dECM cues and printed patterns induced anisotropic cell organization similar to tendon tissues. Gene and protein analysis showed upregulation of the most important tendon related markers on tendon constructs, demonstrating that the biophysical and biochemical cues of dECM induced hASCs commitment toward tenogenic phenotype. In co-culture system, chemotaxis induced endothelial cells migration toward the tendon compartment, but without significant infiltration. Gene and protein expression results suggest that the cellular crosstalk established in this MPS with endothelial cells boosted hASCs tenogenesis, emulating tendon development stages.

Overall, the proposed system might be promising for the automated fabrication of organotypic tendon-on-chip models that will be a valuable new tool to study tendon physiology, pathology, or the effect of drugs for the treatment of tendinopathy.

Acknowledgments: EU H2020 for ERC-2017-CoG-772817; ERC-PoC-BioCHIPs-101069302; FCT/MCTES for 2022.05526.PTDC, 2020.03410.CEECIND, and PD/BD/129403/2017


Orthopaedic Proceedings
Vol. 103-B, Issue SUPP_4 | Pages 13 - 13
1 Mar 2021
Gomez-Sierra M Lackington W Alini M Thompson K
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Although 80% of fractures typically heal without any problems, there is a small proportion (<20%) that suffer complications such as delayed healing and potential progression to non-union. In patients with healing complications, the coordinated regulation between pro- and anti-inflammatory cytokines, such as interleukin-1β (IL-1β) and interleukin-1 receptor antagonist (IL-1Ra) respectively, is often dysregulated. The aim of this study is to develop a therapeutic strategy based on the local delivery of genes to reparative mesenchymal stromal cells (MSCs) migrating into the local fracture microenvironment, thereby promoting a more favourable healing environment to enhance fracture repair. Our approach involves the local delivery of nanoparticles complexing the non-viral vector polyethyleneimine (PEI) with therapeutic plasmid DNA (pDNA) encoding for IL-1Ra.

pDNA encoding green fluorescent protein and Gaussia luciferase were used as reporter genes to determine the transfection efficiency of both rat and human MSCs using flow cytometry and to assess the transgene expression profile using a luciferase expression assay. The effect of transfection with PEI on the viability of MSCs was assessed using the metabolic assay Cell Titer Blue and dsDNA quantification. Levels of IL-1Ra produced by cells following transfection with nanoparticles encoding IL-1Ra was assessed using enzyme-linked immunosorbent assays (ELISA). HEK-Blue IL-1β reporter cells, which secrete alkaline phosphatase in response to IL-1β stimulation, were used to confirm that the IL-1Ra produced by transfected cells is functionally active, i.e. the successful antagonism of IL-1β bioactivity.

We have determined that using PEI-based nanoparticles we can achieve a transfection efficiency of 14.8 + 1.8% in rat MSCs. Transgene expression was found to be transient, with a peak in expression at 7 days post-transfection and a gradual decrease over time, which was maintained for up to 4 weeks. Using an optimized concentration of PEI, the impact of the nanoparticles on MSC viability was limited, with no significant difference in cellular metabolic activity compared to non-transfected cells at 10 days post-transfection. We have additionally demonstrated the capacity to successfully transfect both rat and human MSCs with pDNA encoding for IL-1Ra, resulting in enhanced levels of IL-1Ra, which is functionally active.

The use of non-viral gene therapy to locally deliver immunomodulatory genes, such as IL-1Ra, to MSCs presents a promising strategy to enhance bone healing. Specifically, the transgene expression levels achieved with such an approach can remain therapeutically effective and are transient in nature, presenting an advantage over other methods such as recombinant protein delivery and viral-based gene delivery methodologies.