Abstract
Introduction and Objective
Hyaluronic acid (HA) is an effective option for the treatment of osteoarthritis (OA) patients due to several properties such as normalization of the mechanical and rheological properties of the synovial fluid and amelioration of OA symptoms and joints function by promoting cartilage nutrition. Since OA progression is also significantly related to oxidative stress and reactive oxygen species (ROS), sodium succinate (SS) is envisioned as a promising compound for cartilage treatment by providing antioxidant defense able to normalize intracellular metabolism and tissue respiration via mitochondrial mechanism of action. The scope of this study was to investigate on an in vitro inflammatory model the efficacy of Diart® product, a combination of HA and SS.
Materials and Methods
Donor-matched chondrocytes and synoviocytes were obtained from KL 3–4 OA patients undergoing total knee replacement. At passage 4, inflammation was promoted with 1 ng/ml IL-1B for 48 hours in absence and presence of Diart® at 1:3 dilution rate. Nitric oxide (NO) from cell culture supernatant was measured by Griess reaction. Mitochondrial and cytoplasmatic ROS evaluation was assessed by flow cytometry with MitoSox and dichlorodihydrofluorescein diacetate (DCFDA) assays. Gene expression of inflammation/oxidative stress-related transcripts (MMP1/MMP3/INOS/COX2) was evaluated by qRT-PCR using TBP as reference.
Results
NO was detected only in inflamed chondrocytes and Diart® was able to abolish its levels. NO was not detected in synoviocytes in all conditions. IL-1B reduced both cytoplasmic (−66%) and mitochondrial (−68%) ROS in chondrocytes, with Diart® partially restoring (+40%) mitochondrial levels. In synoviocytes, IL-1B did not alter ROS, with Diart® modestly increasing (+27%) mitochondrial levels. Inflammation was able to increase transcript levels of all tested markers, with the exception of INOS in synoviocytes. In chondrocytes, Diart® significantly (p < 0.05) reduced COX2 (−75%) and MMP1 (−33%). In synoviocytes, Diart® significantly reduced COX2 (−77%) and MMP3 (−84%), with MMP1 53% decreased albeit without reaching statistical significance.
Conclusions
Diart® biochemical and physiologic properties in the tested in vitro model of inflammation on donor-matched chondrocytes and synoviocytes allowed reducing inflammation and oxidative stress-related markers, prompting the use of this combination as successful strategy to manage OA-related symptoms.