The affinity of cellulose nanoparticle toward hydrogel based on chitosan/tragacanth for radiation protection: Study of pulmonary damages on rats

In order to overcome the harmful effects of radiation exposure on lung tissue in radiation therapy, a complete comparative analysis was performed between the injectable pure hydrogel and a novel composite hydrogel, taking into account the addition of cellulose nanoparticles in varying ratios. Initially, both chitosan and tragacanth hydrogels were chemically were modified, and then characterized by FTIR spectroscopy and rheology measurement. For in vivo studies, 42 rats were divided into seven groups. Rats in group 1, were not exposed to radiation, and no injection was done. Rats in group 2 were exposed to a radiation dose of 15 Gy without any injection. Rats in groups 3, 4, and 5 got injectable chitosan/ tragacanth hydrogel containing nanocellulose 25, 50, and 75 mg/kg BW, respectively, along with a radiation dose of 15 Gy. Rats in group 6 got a radiation dose of 15 Gy and an IP injection optimal dose of cellulose nanoparticle and PBS. Rat in group 7 got a radiation dose of 15 Gy and an IP injection of hydrogel containing only chitosan–tragacanth. The pathological results demonstrated that the 25 mg/kg BW dose of nanocellulose-contained hydrogel possessed less inflammation, mucus secretion, bleeding in lung tissue, and air sac wall thickening than other groups. In addition, a biochemistry assessment was conducted by examining the activity of three enzymes of malondialdehyde (MDA), superoxide dismutase (SOD), and glutathione peroxide (GPx), which findings confirmed the hydrogel incorporated with 25 mg/kg BW dose of nanocellulose decreased cell death in a lung tissue damaged by radiation which was 52 IU/mL, 37 IU/mL, and 10 μM in comparison with 63 IU/mL, 40 IU/mL, and 1 μM for the control sample.