Ghrelin, a recently discovered peptide hormone, is primarily produced by endocrine cells in the oxyntic mucosa of rat and human stomachs [1] and [2]. Ghrelin has also been found in the small intestine, pancreas, liver, kidney, placenta, testis, ovary, pituitary gland and hypothalamus in both humans and rodents [2] and [3]. Ghrelin is the natural ligand for the growth hormone secretagogue receptor (GHSR) and its receptor is found all over the body including in the bowel, pancreas, stomach, heart, lungs and brain [1], [2] and [4]. Besides stimulating growth hormone secretion, studies show that ghrelin exerts a number of central and peripheral actions such as regulation of food intake, control of energy balance, glucose metabolism and insulin release, cardiovascular actions, stimulation of gastric Pyronaridine Tetraphosphate secretion, and motility [5], [6], [7], [8] and [9]. Because of the presence of ghrelin and its receptors in the stomach, it would be reasonable to expect its participation to gastric function. In fact, a number of studies have provided evidence of a close relationship between ghrelin and gastric motility [9], [10], [11] and [12]. Recent studies have indicated that ghrelin (5 μg/kg–50 μg/kg) enhances gastric motility and gastric emptying in rodents and dogs, stimulates small intestinal transit, and reverses postoperative gastric ileus [13], [14] and [15]. However, it has been also reported that ghrelin has no effect on gastric emptying in humans [6] and does not stimulate gastrointestinal motility in the dog [16]. In addition, Masuda et al. [9] reported that the increasing effect of ghrelin (0.8–20 μg/kg i.v.) on gastric motility was completely eliminated by pretreatment with atropine or by bilateral cervical vagotomy. Interestingly, a recent study demonstrated that intravenous administration of ghrelin (0.1–10 μg/kg) induced fasting-like motor activity in both the stomach and the duodenum in vagotomised rats [10]. It is known that gastric motility is regulated by gastric myoelectrical activity (GMA), which consists of gastric slow wave and spike potential [17]. Electrogastrography (EGG) is a technique for recording gastric myoelectrical activity, which can be measured using one of three methods: cutaneous electrodes, intraluminal electrodes, or serosal electrodes. Serosal electrodes give the most reliable recording, which reflects detailed information on GMA. However, this is suitable only for experimental studies on animal models [18]. Chen and McCallum [19] reported that normal slow wave frequency in the EGG was related to normal gastric motility and that abnormal slow wave frequencies were associated with motility disorders. It is clear that the mechanism of ghrelin-induced changes in gastrointestinal motility has not been fully understood. Therefore, the principal objective of this study was to investigate the pharmacological role of ghrelin on gastric myoelectrical activity in rats. A secondary objective was to study the role of ghrelin on the gastric emptying rate of a non-caloric liquid meal in conscious rats. In addition, atropine sulfate was administered subcutaneously before the ghrelin injection to investigate whether cholinergic activity is involved in the effect of ghrelin.