The first biogas that was seen to have a potent impact on the human body was NO. It was found by Drs. Furchgott, Murad, and Ignarro who were honored for their discovery by being awarded the Nobel Prize for medicine in 1998. Even though the studies of endothelium-derived relaxing factor (EDRF) and nitrovasodilators were discovered separately, two tales finally merged by finding the exact biological similarity of EDRF and NO. NO is synthesized from oxygen and L-arginine by NO synthase, and has major physiologic functions as a vasodilator, platelet aggregator, and neurotransmitter. It is known that NO interacts with various biomolecules that contain heme group-like guanylyl cyclase or cytochrome P450, and modulates the thiol status by interrupting the cysteine residues of proteins. As the second endogenous gas of interest, CO was discovered as an endogenously produced mediator and neurotransmitter. CO is synthesized during the metabolism of heme to biliverdin by heme oxidase-1 (HO-1). Generally known as a toxic gas produced by burning coal, CO asphyxia could cause serious damage since the affinity to hemoglobin is much higher with CO than with oxygen. However, increasing evidence has shown that CO can scavenge reactive oxygen species, regulate vascular muscle tone, or transmit neural signals to the brain, meaning that CO is a crucial mediator for maintaining physiological homeostasis [3, 4]. H₂S, the third gas of interest and importance, was also first known as a ‘toxic gas’ because for decades it was only known as a toxic environmental pollutant and principal offender of halitosis based on its strong odor of rotten eggs [5]. Even though, at the end of 1980s, endogenous hydrogen sulfide was found in the brain, it was suggested to be an artifact until Drs. Abe and Kimura described the enzymatic mechanism of H₂S production in the brain, its biological effects at physiological concentrations, and its specific cellular targets. H₂S is synthesized endogenously in various mammalian tissues by two pyridoxal-5’-phosphate-dependent enzymes responsible for metabolizing L-cysteine: cystathionine β-synthase (CBS) and cystathionine γ-lyase (CSE) [6]. The substrate of CBS and CSE, L-cysteine, is a sulfur-containing amino acid and can be derived from gastrointestinal (GI) sources or liberated from endogenous proteins. However, beyond this notoriety, increasing evidence has shown that H₂S could exert its beneficial physiological roles including the regulation of vasodilatation, attenuation of inflammation and modulation of gut signaling molecules, after which it became a key new therapeutic target, for instance, in the development of GI-safe NSAIDs, endotoxemia-induced gut injury, and GI motility disorders in the GI tract. In this chapter, we will focus on the role of H₂S in the GI system, providing both of its aspects: integrating the initiation and progression of GI diseases in a friendly or hostile manner.