In the mouth, salivary glands (SSGs) play a crucial role; they produce a translucent, alkaline liquid that is secreted in the oral cavity for several purposes. The submandibular, sublingual, and parotid glands are the three primary salivary glands that produce 95% of the saliva, with more minor salivary glands producing the remaining 5%. An acinar cell in the salivary gland secretes saliva. Mucous acinar cells and serous acinar cells produce saliva. Thick mucus is made in the vacuoles of mucous cells, while water and enzymes are made in the vacuoles of serous cells [1].
Saliva contains mostly water (approximately 99%) and other compounds, such as electrolytes, immunoglobulins, digestive enzymes, and viscosity proteins [2]. Producing saliva serves multiple functions, including moisturizing the mucosal surface, adjusting the pH level to become more alkaline, managing the microbiota, initiating food digestion, and creating the food bolus [3]. There are two categories of saliva: serous and mucosal. The former primarily comprises enzymes and fluids, focusing on the amylase enzyme to break down carbohydrates [3][4]. The second type, mucosal saliva, is identified by a high concentration of mucin, which causes it to appear thick and sticky. This aids in binding the partially chewed food particles together before swallowing them [5]. If the structure and integrity of the glands are altered, it affects the function and activity of the glands, as well as the flow and composition of saliva [6]. As a result, altered gland morphology directly impacts blood glucose levels, affecting overall health [7].
The ketogenic diet (KD), a daily dietary plan, relies on increased fat intake, moderate protein consumption, and reduced carbohydrates. It has proven to be an effective therapeutic approach for conditions with metabolic factors, effectively reducing seizures in persistent cases of childhood epilepsy [8], reducing blood glucose levels in type 2 diabetes mellitus [9] and assisting in weight loss [10]. However, it should be noted that in the liver, regardless of weight loss, a KD can induce liver fibrosis and nonalcoholic steatohepatitis by increasing liver cholesterol, interleukin-6, and phospho-Jun N-terminal kinase. Additionally, it can exacerbate diet-induced glucose intolerance and hepatic insulin resistance compared to a high-fat diet [11].
While the brain typically relies on carbohydrates as its main energy source, it is less efficient at metabolizing lipids, despite adipose tissue serving as a larger energy store than muscle and liver glycogen. However, during starvation, the liver utilizes lipids to generate ketone bodies, which act as an alternative fuel for the brain. The production of ketone bodies, including D-b-hydroxybutyrate and acetoacetate, gradually increases due to macronutrient availability (low glucose and high free fatty acids) and hormonal signaling (low insulin, high glucagon, and cortisol). Although the body continuously produces ketone bodies under normal physiological conditions, their blood concentrations rise during, following KD, or after prolonged exercise [12].
Chitosan, a dietary fiber derived from shrimp and lobster shells, is a novel feed additive that is not widely utilized. It has been found to exhibit several beneficial biological properties, including antibacterial, anticancer, antioxidant, and hepatoprotective effects. Adding chitosan and its derivatives to diets could aid in reducing cholesterol and glucose levels, making it a viable option for promoting weight loss [13][14]. Chitosan helps the salivary glands make new tissue structures by controlling the components of the basement membrane. In an environment with chitosan, basement membrane components were more active in space and time [15]. A primary function of chitosan is regulating basement membrane dynamics by enhancing Col IV expression and assisting dystroglycan localization, which is necessary for submandibular gland formation [16]. By interacting with glycosaminoglycans (GAGs), which are extracellular matrix constituents, the existing or changed functional groups of chitosan facilitate the regulation of signals and factors needed for tissue regeneration. Growth factors, nucleic acids, and cytokines are negatively charged compounds that protonated chitosan binds to both in vivo and in vitro. As a result, chitosan enables the integration of numerous bioactive substances that may promote the growth of certain cells or cause stem cells to differentiate into functional differentiated cells, which is frequently a requirement for regeneration [17]. The potential of chitosan to support growth and differentiation in salivary gland epithelium has also been investigated [18]. Yang et al. (2012) [15] revealed that submandibular gland explants exhibited enhanced growth when cultured with chitosan: FGF7. This finding suggests that chitosan could function as a growth stimulator for factors derived from the mesenchyme. This study investigated the effect of KD and dietary chitosan supplementation on rat submandibular salivary glands.