Oxygen transmission; Natural rubber

Oxygen transmission; Natural rubber; Poly (lactic acid); Chitosan; Porous
Oxygen is a significant factor being essential to provide the additional energy source for the wound repairing process. Many polymeric materials have been employed recently in wound dressing such as natural rubber (NR) [1], poly (lactic acid) (PLA) and chitosan [2] because of their biocompatibility and biodegradability. In this study, the oxygen transmission rate (OTR) of modified NR, PLA and chitosan porous structure was determined. The comparison for their OTR was investigated.

NR porous films (NRTX) were fabricated by solvent casting method. NR solution was prepared by dissolving NR (STR 5L) in dichloromethane prior to addition of xanthan gum which was previously dispersed in triethyl citrate and then mixed homogenously. The mixture was poured onto the petri dish and then placed in laminar hood in order to allow dichloromethane to evaporate overnight at room temperature. PLA porous film (PPEG) was prepared using temperature change technique by solvent casting method. The 10%w/w PLA was dissolved in dichloromethane. Polyethylene glycol 400 (PEG) at 150 %w/w of polymer was mixed with the PLA solution. The mixtures were poured onto the petri dish and suddenly placed at -20°C for 24 h and then allowed to dry at 60°C for 24 h. The 4%w/w chitosan solution (CL) was prepared by dissolving chitosan in 2%w/v lactic acid solution. Aluminum monostearate (Alst) (0, 0.5 and 2.5 %w/w) was added into the previous mixture and then homogenized at 8,000 Hz for 5 min using homogenizer. Subsequently, the mixtures were stirred for another 24 h using magnetic stirrer at 1000 rpm. Thereafter, the obtained mixtures were fabricated by using lyophilization techniqueby freezing at -20°C for 24 h prior to drying with freeze dryer. The lyophilized chitosan sponges were then treated by dehydrothermal treatment (DHT) at 110°C for 24 h in vacuum oven. The chitosan sponges containing 0, 0.5 and 2.5 %w/w Alst were named as CD, CD05 and CD25, respectively. OTR was performed using method modified from ASTM1434-82. The samples were cut to fit and placed between the silicone rubber rings on two open 4 cm glass bottles volume 500 ml. Dry nitrogen gas was swept through a chamber, where the test sample acted as the membrane separating this stream from an oxygen stream on the other side, and the gas rate was 100 ml/min. The test condition was 25°C, 70±10 %RH. The amount of oxygen was determined in the outgoing stream of the nitrogen side using gas chromatography (GC) until a constant amount of oxygen was achieved. The oxygen transmission rate (OTR) of films was then calculated in the unit of g m-2 day-1 (n=3).

OTR of all test samples was shown in Table 1. Plain NR, NRTX and plain PLA films exhibited the low OTR, similarly.Because, plain NR and PLA exhibited the dense and hydrophobic structure that oxygen gas could permeate difficulty. Even though, NRTX was a porous inner-layer structure but it exhibited the thick dense-top layer that was an oxygen barrier. PPEG showed the higher OTR than those films because of its whole porous structure and hydrophilicity of PEG in the structure. CD0, CD05 and CD25 displayed the similar highest OTR. The hydrophobic Alst contained in the CD05 and CD25 structure, however the OTR was not different that of CD0 owing to high porous topography therefore the oxygen gas could freely permeate through this unique structure. The optimal conditions for oxygen for wound treatment have not been determined. However, the oxygen-impermeable dressings may be useful only in the early stages of healing, before granulation tissue formation, but the wound will be better healed by the oxygen-permeable dressings at 3 weeks [3]. The OTR of porous NR, PLA and chitosan structures were compared. Chitosan sponge exhibited the higher OTR than PLA porous film and NR porous film, respectively.