Azadeh Haghighitalab; Mahboubeh Kazemi Noughabi; Shima Minaee; Ahmad Amin; Ahmad Reza Bahrami
Abstract
Acute myocardial infarction (MI) describes as an irreversible death of heart muscle which is initiated by a shortage of myocardium oxygen supply and accompanies by a complex of pro- and anti-inflammatory events. During the last decades, innate and adaptive immune responses are considered ...
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Acute myocardial infarction (MI) describes as an irreversible death of heart muscle which is initiated by a shortage of myocardium oxygen supply and accompanies by a complex of pro- and anti-inflammatory events. During the last decades, innate and adaptive immune responses are considered more serious for controlling myocardial infarction. As, it was confirmed that deregulated immune system which triggers excessive local and systemic inflammatory events is responsible for serious adverse effects associated with acute MI. Bone marrow activation, spleen monocytopoiesis, a remarkable increase of circulating cytokines and adhesion molecules, in addition to elevated levels of active peripheral leukocytes and platelets are playing significant roles in determining the clinical outcome of patients with MI. The previous experience demonstrated the failure of traditional harsh anti-inflammatory strategies. High mortality rate and poor quality of life observed for survivors of MI despite current progress in the field highlight the urgent need for such interdisciplinary studies in the context of molecular cardiology. Hence, unraveling the cellular and molecular events which are involved in the management of inflammatory responses post-MI is of special focus. The concept of immune regulation after myocardial infarction is not new, but our perception for dealing with the challenge has been changed during the last decades with gaining more in-depth molecular/immunological knowledge. It seems that fine-tuning the interplay between innate and adaptive immune responses and regulating their cross-talk should be in special focus to establish effective therapeutic strategies.
Azadeh Haghighitalab; Maryam M. Matin; Fatemeh Khakrah; Ahmad Asoodeh; Ahmad Reza Bahrami
Abstract
Despite the prominent therapeutic potentials of stem cells, their use in cell therapy has been challenged with some unreproducible and inconsistent outcomes in addition to the risk of rejection and tumorigenesis. Gaining novel insights to the importance of the conditioned medium, ...
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Despite the prominent therapeutic potentials of stem cells, their use in cell therapy has been challenged with some unreproducible and inconsistent outcomes in addition to the risk of rejection and tumorigenesis. Gaining novel insights to the importance of the conditioned medium, secretory factors and extracellular vesicles as the functional components of the cultured stem cells, suggested the idea of substituting the cells with their cell-free counterparts. Biological properties of these products are influenced by the cues received from their microenvironment. Hence, providing optimal and fully defined culture conditions is essential for their preparation. Fetal bovine serum (FBS), one of the most routine supplements of cell culture, is enriched by endogenous extracellular vesicles (EVs). These EVs will affect the yield, purity and functional features of the cell-free products. Here, we endeavored to examine and compare three different methods including ultrasonication, ultrafiltration and polymer-based precipitation, to deplete EVs from FBS. We chose easy to perform and fast methods with the capacity for high-throughput applications. Based on our observations, although all examined methods were able to deplete EVs from FBS to some extent, polymer-based precipitation could be considered as the method of choice with minimal consequences on the biological requirements of FBS to support cell growth and characteristics. Due to similarities between FBS and some other biological solutions, this strategy would be suitable for EV-depletion from other liquids with high concentrations of proteins and nutrients. Moreover, it could be applied for preparation of optimal culture conditions for nanoparticle applications.