Hyaluronic acid slows down collagen membrane degradation in uncontrolled diabetic rats

Abstract: Aim To examine the in vitro biokinetics of hyaluronic acid (HA) from a collagen membrane (CM) and to evaluate the in vivo effect of immersion of the CM in HA solution on its degradation in streptozotocin (STZ)‐induced diabetes conditions in a rat calvaria subcutaneous model. Background CM degradation is accelerated in uncontrolled diabetic rats. Immersion of CM in HA has been suggested to decrease their resorption rate without interfering with their tissue integration and structural degradation. However, it is… Show more

“…[26][27][28][29] In support of our contention that DM results in enhancement of inflammation/collagenolysis around the membranes, we found that immersion of the membranes in tetracycline (TC) or hyaluronic acid (HA) prior to implantation mitigated their resorption in diabetic rats, probably because of the anticollagenolytic/anti-inflammatory properties, respectively, of these additives. [26][27][28][29] Therefore, the present study was performed to compare the local expression and production of several pro-inflammatory molecules at the membrane implantation site between diabetic and normoglycemic rats and provide a better understanding of the molecules that drive the exaggerated inflammation shown histologically in and around the membranes. We analyzed the presence of IL-6, TNF , MMP-9, MIP-1 , MIP-2 , and MIF, representing different aspects of the inflammatory process, namely cytokines, chemokines, and MMPs.…”

“…These time points were selected based on our previous studies showing accelerated membrane resorption in this model. [26][27][28][29] Dermal tissues were dissected away leaving the periosteum undisturbed and the membrane including overlying and underlying tissues was retrieved. Six samples from each group were immediately frozen in liquid nitrogen and then transferred to −80 • C for RNA/protein isolation.…”

“…This analysis was done only to confirm the reduced thickness and increased presence of inflammatory cells in and around the membranes of the diabetic rats, as described in our previous studies. [26][27][28][29] The thickness of the residual biotin-avidin stained membrane was determined with a ×10 objective in an Olympus microscope as an average of six measurements in each section.…”

“…We have recently shown that DM similar to type 1, induced in rats via injection of streptozotocin, results in an accelerated degradation of collagen membranes implanted subcutaneously. [26][27][28][29] This rapid degradation was associated with an increased inflammatory infiltrate in and around the membranes and specifically with a greater number of putative M1 macrophages (CD-68 positive cells). [26][27][28][29] In support of our contention that DM results in enhancement of inflammation/collagenolysis around the membranes, we found that immersion of the membranes in tetracycline (TC) or hyaluronic acid (HA) prior to implantation mitigated their resorption in diabetic rats, probably because of the anticollagenolytic/anti-inflammatory properties, respectively, of these additives.…”

“…[26][27][28][29] This rapid degradation was associated with an increased inflammatory infiltrate in and around the membranes and specifically with a greater number of putative M1 macrophages (CD-68 positive cells). [26][27][28][29] In support of our contention that DM results in enhancement of inflammation/collagenolysis around the membranes, we found that immersion of the membranes in tetracycline (TC) or hyaluronic acid (HA) prior to implantation mitigated their resorption in diabetic rats, probably because of the anticollagenolytic/anti-inflammatory properties, respectively, of these additives. [26][27][28][29] Therefore, the present study was performed to compare the local expression and production of several pro-inflammatory molecules at the membrane implantation site between diabetic and normoglycemic rats and provide a better understanding of the molecules that drive the exaggerated inflammation shown histologically in and around the membranes.…”

Accelerated degradation of collagen membranes in type 1 diabetic rats is associated with increased expression and production of several inflammatory molecules

“…[26][27][28][29] In support of our contention that DM results in enhancement of inflammation/collagenolysis around the membranes, we found that immersion of the membranes in tetracycline (TC) or hyaluronic acid (HA) prior to implantation mitigated their resorption in diabetic rats, probably because of the anticollagenolytic/anti-inflammatory properties, respectively, of these additives. [26][27][28][29] Therefore, the present study was performed to compare the local expression and production of several pro-inflammatory molecules at the membrane implantation site between diabetic and normoglycemic rats and provide a better understanding of the molecules that drive the exaggerated inflammation shown histologically in and around the membranes. We analyzed the presence of IL-6, TNF , MMP-9, MIP-1 , MIP-2 , and MIF, representing different aspects of the inflammatory process, namely cytokines, chemokines, and MMPs.…”

“…These time points were selected based on our previous studies showing accelerated membrane resorption in this model. [26][27][28][29] Dermal tissues were dissected away leaving the periosteum undisturbed and the membrane including overlying and underlying tissues was retrieved. Six samples from each group were immediately frozen in liquid nitrogen and then transferred to −80 • C for RNA/protein isolation.…”

“…This analysis was done only to confirm the reduced thickness and increased presence of inflammatory cells in and around the membranes of the diabetic rats, as described in our previous studies. [26][27][28][29] The thickness of the residual biotin-avidin stained membrane was determined with a ×10 objective in an Olympus microscope as an average of six measurements in each section.…”

“…We have recently shown that DM similar to type 1, induced in rats via injection of streptozotocin, results in an accelerated degradation of collagen membranes implanted subcutaneously. [26][27][28][29] This rapid degradation was associated with an increased inflammatory infiltrate in and around the membranes and specifically with a greater number of putative M1 macrophages (CD-68 positive cells). [26][27][28][29] In support of our contention that DM results in enhancement of inflammation/collagenolysis around the membranes, we found that immersion of the membranes in tetracycline (TC) or hyaluronic acid (HA) prior to implantation mitigated their resorption in diabetic rats, probably because of the anticollagenolytic/anti-inflammatory properties, respectively, of these additives.…”

“…[26][27][28][29] This rapid degradation was associated with an increased inflammatory infiltrate in and around the membranes and specifically with a greater number of putative M1 macrophages (CD-68 positive cells). [26][27][28][29] In support of our contention that DM results in enhancement of inflammation/collagenolysis around the membranes, we found that immersion of the membranes in tetracycline (TC) or hyaluronic acid (HA) prior to implantation mitigated their resorption in diabetic rats, probably because of the anticollagenolytic/anti-inflammatory properties, respectively, of these additives. [26][27][28][29] Therefore, the present study was performed to compare the local expression and production of several pro-inflammatory molecules at the membrane implantation site between diabetic and normoglycemic rats and provide a better understanding of the molecules that drive the exaggerated inflammation shown histologically in and around the membranes.…”

Accelerated degradation of collagen membranes in type 1 diabetic rats is associated with increased expression and production of several inflammatory molecules

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