Effects of normal saline versus lactated Ringer's solution on organ function and inflammatory responses to heatstroke in rats

Heatstroke is a life-threatening condition characterized by severe hyperthermia and multiple organ dysfunction. Both normal saline (NS) and lactated Ringer's solution (LR) are commonly used for cooling and volume resuscitation in heatstroke patients; however, their specific impacts on patient outcomes during heatstroke management are poorly understood. Given that the systemic inflammatory response and multiple-organ damage caused by heat toxicity are the main pathophysiological features of heatstroke, the

NS resuscitation in heat-exposed rats significantly promotes metabolic acidosis and the inflammatory response, leading to greater functional and structural organ damage than does LR. These findings underscore the necessity of selecting appropriate resuscitation fluids for heatstroke management to minimize organ damage and improve outcomes.

Fifty-five male Sprague‒Dawley rats were randomly divided into four groups: cold NS or LR infusion postheatstroke (4 ℃, 4 ml/100 g, over 10 min) and NS or LR infusion without heatstroke induction (control groups). Vital signs, arterial blood gases, inflammatory cytokines, and renal and cardiac function indicators, such as serum creatinine and cTnI, were monitored after treatment. Tissue samples were analysed via HE staining, electron microscopy, and fluorescence staining for apoptosis markers, and protein lysates were used for Western blotting of pyroptosis-related proteins.

Compared with LR-treated heatstroke rats, NS-treated heatstroke rats presented lower mean arterial pressures, worsened metabolic acidosis, and higher levels of IL-6 and TNF-α in both the serum and tissue. These rats also presented increased serum creatinine, troponin, catecholamines, and NGAL and reduced renal clearance. Histological and ultrastructural analyses revealed more severe tissue damage in NS-treated rats, with increased apoptosis and increased expression of NLRP3/caspase-1/GSDMD signalling molecules. Similar differences were not observed between the control groups receiving either NS or LR infusion. One NS-treated heatstroke rat died within 24 h, whereas all the LR-treated and control rats survived. Conclusions: NS resuscitation in heat-exposed rats significantly promotes metabolic acidosis and the inflammatory response, leading to greater functional and structural organ damage than does LR. These findings underscore the necessity of selecting appropriate resuscitation fluids for heatstroke management to minimize organ damage and improve outcomes.