Browsing by Subject "Mesenchymal Stem Cells"

Now showing 1 - 6 of 6
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    Differentiation and Activity of Murine Derived Stromal Osteoblasts After Electromagnetic Wave Stimulation
    (2022) Wu, Jennifer L.; Spolnik, Kenneth; Bruzzaniti, Angela; Ehrlich, Ygal; Warner, Ned
    Introduction: Elimination of bacteria and active infection within an infected root canal system is one of the primary objectives of nonsurgical root canal treatment. One of the measures of successful root canal treatment is subsequent bone healing of periapical lesions caused by previous infection. A previous study by Yumoto et al. showed that electromagnetic wave stimulation can increase proliferation of osteoblastic cells with no cytotoxicity, and it can also up-regulate growth factors such as vascular endothelial growth factor and platelet-derived growth factor.18 They also showed increased proliferation of an immortalized osteoblastic MC3T3-E1 cell line 3 days following electromagnetic stimulation (EMS).18 Previously, Pauly et al. found increased alkaline phosphatase (ALP) activity with 10 mA EMS application to primary murine calvaria-derived osteoblastic cells with 5 pulses at 1 second per pulse, but no significant differences were found for MTS proliferation nor mineral deposition compared to a negative control group.82 Optimization of the different variables including post-treatment incubation time, current delivery, and number of pulses per treatment may be necessary to improve osteogenic activity. The use of mesenchymal stem cells from murine bone marrow may also offer a physiologically relevant model for osteoblastic regeneration of periapical lesions. Objectives: The goal of this study was to investigate and optimize the effects of electromagnetic wave stimulation (EMS) on murine bone marrow mesenchymal stem cells (MSCs) by evaluating the proliferation and differentiation of the cells after exposure to different EMS treatment regimens. Materials and Methods: 5 x104 stromal osteoblasts (SOBs) were cultured in 24-well plates in α-MEM containing 10% fetal bovine serum. Cells were then subjected to pulsed EMS treatments of 1 mA, 10 mA, and 50 mA. EMS was generated using an electromagnetic apical treatment (EMAT) device created by J. Morita MFG Corp. Proliferation was assessed via MTS assay 1 days after treatment. For osteogenic differentiation, ascorbic acid and β-glycerol phosphate were added to the culture media, and SOBs were cultured for 14 days. Afterwards, alkaline phosphatase (ALP) activity and Alizarin-red S mineral deposition were quantified as measures of osteoblast activity. Cells grown in osteogenic media without EMS treatment served as the negative control. Results: Although MSC proliferation was unaffected by different EMS treatment regimens, 50 mA EMS resulted in a decrease in ALP activity and mineral deposition by osteoblasts. Conclusions: Our findings suggest bone healing by EMS may involve a different cellular mechanism, that is not reproduced in vitro in our studies. Utilizing different amperage and EMS regimens may improve osteogenic differentiation.
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    Dynamic Control of Hydrogel Properties via Enzymatic Reactions
    (2019-05) Moore, Dustin M.; Lin, Chien-Chi; Xie, Dong; Li, Jiliang
    Dynamic changes to the extracellular matrix (ECM) impact many cell fate pro- cesses. The ECM can experience changes in sti ness as well as changes in composi- tion in response to injury, development, and diseases. To better understand the role that these dynamic processes have on the cells residing within the environment, re- searchers have turned towards 4-dimensional (4D) hydrogel designs. These 4D hydro- gels re-capitulate not only 3-dimensional (3D) matrix architectures, but also temporal changes in the physicochemical properties. The goal of this thesis was to design a unify chemistry (i.e., Sortase A (SrtA)-mediated transpeptidation) for dynamic tun- ing hydrogel sti ness and the presence of bioactive ligands. The rst objective was to establish a tunable and cytocompatible enzymatic scheme for softening cell-laden hydrogels. Brie y, the e ects of SrtA-mediated matrix cleavage were investigated us- ing poly(ethylene glycol) (PEG)-peptide hydrogels crosslinked by SrtA-sensitive and insensitive peptides. Initially, the e ects of various parameters with respect to cat- alytic reactions of SrtA were characterized rheologically, including enzyme and sub- strate concentrations, macromer content, peptide composition, and treatment time. Gel moduli pre- and post-enzyme treatment were measured to verify SrtA-mediated hydrogel softening. The cytocompatibility of SrtA-mediated gel softening system was investigated using human mesenchymal stem cell (hMSC). Upon treatment with SrtA and an oligoglycine substrate, encapsulated hMSCs exhibited extensive spreading in comparison to those within statically sti matrices. The second objective was to es- tablish a reversible ligand exchange system utilizing SrtA-mediated transpeptidation. SrtA-sensitive pendant ligands were immobilized within PEG hydrogels, which were treated with SrtA and an oligoglycine substrate to a ord tunable removal of the pen- dant ligand. Through measurement of the liberated pendant peptide concentration, it was found that higher concentrations of SrtA or extending treatment times led to higher ligand removal e ciency. Finally, the e ect of peptide ligand removal on cell behaviors were evaluated using NIH 3T3 broblasts. Fibroblasts were culture both on and within hydrogels containing SrtA-cleavable cell adhesion peptide. After treatment, both conditions led to a decrease in broblast spreading in comparison to non-treated gels. Overall, the utility of SrtA as versatile agent for controlling the mechanical properties and the presence of biologically active components within a hydrogel system was demonstrated. These systems could be further explored with natural-based materials to better mimic the physiological environment experienced by cells.
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    The Mechanotransduction of Hydrostatic Pressure by Mesenchymal Stem Cells
    (2018-12) Hosseini, Seyedeh Ghazaleh; Wagner, Diane R.; Na, Sungsoo; Ji, Julie
    Mesenchymal stem cells (MSCs) are responsive to mechanical stimuli that play an essential role in directing their differentiation to the chondrogenic lineage. A better understanding of the mechanisms that allow MSCs to respond to mechanical stimuli is important to improving cartilage tissue engineering and regenerative medicine. Hydrostatic pressure (HP) in particular is known to be a primary mechanical force in joints. However, little is known about the underlying mechanisms that facilitate HP mechanotransduction. Understanding the signaling pathways in MSCs in transducing HP to a beneficial biologic response and their interrelationship were the focus of this thesis. Studies used porcine marrow-derived MSCs seeded in agarose gel. Calcium ion Ca++ signaling, focal adhesion kinase (FAK) involvement, and sirtuin1 activity were investigated in conjunction with HP application. Intracellular Ca++ concentration was previously shown to be changed with HP application. In our study a bioreactor was used to apply a single application of HP to the MSC-seeded gel structures and observe Ca++ signaling via live imaging of a fluorescent calcium indicator in cells. However, no fluctuations in Ca++ concentrations were observed with 10 minutes loading of HP. Additionally a problem with the biore actor design was discovered. First the gel was floating around in the bioreactor even without loading. After stabilizing the gel and stopping it from floating, there were still about 16 µm of movement and deformation in the system. The movement and deformation was analyzed for the gel structure and different parts of the bioreactor. Furthermore, we investigated the role of FAK in early and late chondrogenesis and also its involvement in HP mechanotransduction. A FAK inhibitor was used on MSCs from day 1 to 21 and showed a dose-dependent suppression of chondrogenesis. However, when low doses of FAK inhibitor added to the MSC culture from day 21 to 42, chondrogenesis was not inhibited. With 4 hour cyclic HP, FAK phosphorylation increased. The beneficial effect of HP was suppressed with overnight addition of the FAK inhibitor to MSC medium, suggesting FAK involvement in HP mechanotransd ucation by MSCs. Moreover, sirtuin1 participation in MSC chondrogenesis and mechanotransduc tion was also explored. The results indicated that overnight sirtuin1 inhibition in creased chondrogenic gene expression (Agc, Col2, and Sox9) in MSCs. Additionally, the activity of sirtuin1 was decreased with both 4 hour cyclic hydrostatic pressure and inhibitor application. These two together demonstrated that sirtuin1 inhibition enhances chondrogenesis. In this research we have investigated the role of Ca++ signaling, FAK involvement, and sirtuin1 activity in the mechanotransduction of HP in MSCs. These understand ings about the mechanisms regulating the chondrogenesis with respect to HP could have important implications for cartilage tissue engineering and regenerative studies.
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    New directions in necrotizing enterocolitis with early-stage investigators
    (Springer Nature, 2020-08) Markel, Troy A.; Martin, Colin A.; Chaaban, Hala; Canvasser, Jennifer; Tanner, Heather; Denchik, Heather; Good, Misty; Surgery, School of Medicine
    The 2019 Necrotizing Enterocolitis (NEC) Symposium expanded upon the NEC Society's goals of bringing stakeholders together to discuss cutting-edge science, potential therapeutics and preventative measures, as well as the patient-family perspectives of NEC. The Symposium facilitated discussions and shared knowledge with the overarching goal of creating "A World Without NEC." To accomplish this goal, new research to advance the state of the science is necessary. Over the last decade, several established investigators have significantly improved our understanding of the pathophysiology of NEC and they have paved the way for the next generation of clinician-scientists funded to perform NEC research. This article will serve to highlight the contributions of these young clinician-scientists that seek to elucidate how immune, microbial and nervous system dysregulation contributes to the pathophysiology of NEC.
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    Preventing tumor progression to the bone by induced tumor-suppressing MSCs
    (Ivyspring International, 2021-03-05) Sun, Xun; Li, Kexin; Zha, Rongrong; Liu, Shengzhi; Fan, Yao; Wu, Di; Hase, Misato; Aryal, Uma K.; Lin, Chien-Chi; Li, Bai-Yan; Yokota, Hiroki; Biomedical Engineering, School of Engineering and Technology
    Background: Advanced breast cancer metastasizes to many organs including bone, but few effective treatments are available. Here we report that induced tumor-suppressing (iTS) MSCs protected bone from metastases while un-induced MSCs did not. Methods: iTS MSCs were generated by overexpressing Lrp5, β-catenin, Snail, or Akt. Their tumor-suppressing capability was tested using a mouse model of mammary tumors and bone metastasis, human breast cancer tissues and cancer cell lines. Results: In a mouse model, the induced MSC-derived conditioned medium (MSC CM) reduced mammary tumors and suppressed tumor-induced osteolysis. Tumor-promoting genes such as CXCL2 and LIF, as well as PDL1, a blocker of T-cell-based immune responses were downregulated. Proteomics analysis revealed that heat shock protein 90 (Hsp90ab1), calreticulin (Calr) and peptidylprolyl isomerase B (Ppib), which are highly expressed intracellular proteins in many cancers, were enriched in MSC CM as atypical tumor suppressors. Thus, overexpressing selected genes that were otherwise tumorigenic rendered MSCs the tumor-suppressing capability through the atypical suppressors, as well as p53 and Trail. Notably, the inhibitory effect of Lrp5- and Akt-overexpressing MSC CMs, Hsp90ab1 and Calr presented selective inhibition to tumor cells than non-tumor cells. The development of bone-resorbing osteoclasts was also suppressed by MSC CMs. Conclusion: Collectively, the results showed an anti-tumor effect of iTS MSCs and suggested novel therapeutic approaches to suppress the progression of tumors into the bone.
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    Scaffold-free bioprinting of mesenchymal stem cells with the regenova printer: Optimization of printing parameters
    (Elsevier, 2019-03-23) Aguilar, Izath Nizeet; Smith, Lester J.; Olivos, David J.; Chu, Tien-Min Gabriel; Kacena, Melissa A.; Wagner, Diane R.; Radiology and Imaging Sciences, School of Medicine
    The Kenzan bioprinting method provides a high-resolution biofabrication process by facilitating the fusion of submillimeter cell aggregates (spheroids) into larger tissue constructs on a needle array that is removed upon spheroid fusion. Although the method is relatively straightforward in principle, Kenzan method bioprinting relies on a complex 3D bioprinter (Regenova Bio 3D Printer, Cyfuse, K.K., Japan) implementing an advanced vision system to verify the microscopic spheroids’ geometry and high-precision mechatronics to aseptically manipulate the spheroids into position. Due to the complexity of the operation, the need for aseptic conditions, and the size of the spheroids, proficiency with the Regenova Bio 3D Printer and the Kenzan method requires development of best practices and troubleshooting techniques to ensure a robust print and minimize the use of resources. In addition, managing the construct post-bioprinting both in culture and for surgical implantation requires careful consideration and workflow design. Here, we describe methods for generating a competent tissue construct and optimizing the bioprinting process. Optimization resulted in a 4-fold reduction in print times, a 20-fold reduction in the use of bioprinting nozzles, and more robust constructs. The results and procedures described herein will have potential applications for tissue engineering, research, and clinical uses in the future.