Pneumonia, an acute inflammatory condition of the lung tissue, imposes a significant burden on global health and is characterized by a high rate of illness and death. The pathogenesis of the disease extends beyond infection to breakdown of redox hemostasis, where the excessive reactive oxygen species produced during the immune response inflict damage on the alveolar tissues and hence promote varying complications. This dual role of oxygen and oxidative mechanisms makes the management of pneumonia challenging, as the very oxygen that is vital for host defense, when not regulated, imposes severe lung damage. Antioxidant administration and oxygen therapy offer limited efficacy, mostly due to their non-specific action and iatrogenic harm from oxygen oversupply. These limitations are overcome by the use of emerging therapeutic strategies, which primarily focus on precision-targeted approaches. These include inhalable antioxidants, nanoparticle-based systems and biomaterials that are engineered to respond to local ROS concentrations, which aim to deliver the therapeutic agent directly to the inflamed regions of the lung. Calcium peroxide- and manganese dioxide-incorporating materials are being designed to modulate the oxygen levels, either by releasing it in hypoxic zones or scavenging it in hyperoxic microenvironments. This approach simultaneously addresses hypoxia and oxidative stress. Despite showing promising results in experimental and preclinical studies, complications related to product stability, regulatory compliance, and manufacturing scalability need to be addressed. Personalized treatment protocols, guided by biomarkers, involve the future generation of treatments, aiming to achieve a delicate recalibration of the lung’s oxidative environment for improved patient outcomes.
Sasikumar et al. (Mon,) studied this question.