Helicobacter pylori (H. pylori), a human pathogen, is a gram-negative bacterium that colonizes in the host gastroduodenal tract, causing some variant diseases like gastritis, gastric ulcer (GU), duodenal ulcer (DU) and gastric cancer (GC). Interestingly, DU and GC are considered as clinically divergent events. Some previous studies suggested that the outer membrane proteins of H. pylori played important roles in pathogenesis and host recognition. Thus, we aimed to focus on discovering the outer membrane proteins of H. pylori as GC-related biomarkers, and to develop a new platform which is rapid and easy for diagnosis of screening GC patients from DU patients infected by H. pylori. In our previous study, we compared the membrane proteome of two clinical H. pylori strains, one strain from GC patients and the other strain from DU patients. We identified 57 proteins which the expression levels of GC strain were higher than that of DU strain. In this study, we found four membrane proteins as potential biomarkers. The four proteins were outer inflammatory protein (OipA), adherence-associated lipoprotein A (AlpA), sialic acid-binding adhesin (SabA) and blood group antigen binding adhesin (BabB). These candidates were reported to be responsible for the adhesion of H. pylori to the host gastric epithelium and mucosa. We cloned and purified the recombinant membrane proteins. Using immunoblot, the purified proteins were probed with serum samples from gastritis, DU, GC patients and normal controls. The results revealed that OipA, AlpA, SabA and BabB showed significantly higher immuno-reactivity in GC patients than that in DU patients, and OipA, SabA and BabB were strongly related to GC. In addition, we found that the use of multiple antigens improved the discrimination between patients with GC and those with DU as the odds ratios increased from 0.75 (0.26–2.15) for seropositivity for any one antigen alone to 3.00 (0.95–9.53) for two of the four antigens and to 6.33 (1.29–31.1) for three antigens or all four antigens. These results suggested that these adhesion molecules we selected may be potential H. pylori GC-associated biomarkers. Moreover, to develop a faster and more convenient platform for diagnosis, we tested the condition for printing the purified recombinant membrane proteins onto glass slides to create GC-related antigen membrane protein chip and the chip was incubated with serum from DU, GC patients and normal controls. The results were significantly consistent with our results of immunoblot that OipA, SabA and BabB were potential biomarkers for specifically distinguishing GC from DU and healthy controls. In the future, we expect to use GC-related antigen membrane protein chip to detect antibody patterns in sera of patients and the membrane protein chip combined with the idea of multiple biomarkers can be used for diagnostic application.