Gastric Cancer (GC) is one of the most dangerous malignancies in the world. This study aims to evaluate the relationship between miR-146a and miR-155 in patients with H. pylori infections with GC compared to H. pylori-infected patients and healthy subjects. Forty patients with H. pylori and GC positive diagnoses and 40 patients with H. pylori positive and GC negative diagnoses, and 40 healthy persons were selected.The expression of miR-146a and miR-155 genes in the whole blood was examined using qRT-PCR. Moreover, ROC curves were drawn to represent the sensitivity and specificity of miR-146a and miR-155 expression as biomarkers. The results showed the expression of miR-146a and miR-155 in the whole blood of patients with H. pylori and GC positive diagnoses are significantly higher than in healthy individuals and are non-significantly enhanced compared to H. pylori positive and GC negative. Also, the results stated miR-146a and miR-155 expression in the whole blood of patients who are H. pylori positive and GC negative are significantly increased compared to healthy individuals. Furthermore, the ROC curve analysis of miR-146a and miR-155 RNA level demonstrated the two miRNAs have an appropriate sensitivity and specificity for diagnostic goals. In conclusion, H. pylori infection may increase the expression of miR-146a and miR-155 in patients with H. pylori and GC positive diagnoses, which can be effective in the curbing the progression of GC. For this reason, up-regulation of miR-146a and miR-155 along with H. pylori infection might contribute to the pathogenesis of GC, and also can be suggested as biomarkers for GC diagnosis and treatment.

Hemorrhage is a prevalent side effect of various injuries and can be life-threatening in certain instances. It is categorized into compressible and non-compressible types, each necessitating distinct modeling, laboratory assessments, and hemostatic approaches. This study utilized the keywords Hemorrhage, Bleeding, Animal Modeling, and Hemostat in reputable databases. The findings indicate that femoral artery hemorrhage and hepatic parenchymal hemorrhage are the predominant modeling techniques for compressible and noncompressible bleeding, respectively. Furthermore, it is noted that animal models of compressible hemorrhages are primarily situated in superficial body areas to investigate dressing or additive hemostats, while non-compressible hemorrhage models, typically located in visceral organs, are employed to examine adhesive or surgical instrumentbased hemostats.

Hemorrhage is a prevalent side effect of various injuries and can be life-threatening in certain instances. It is categorized into compressible and non-compressible types, each necessitating distinct modeling, laboratory assessments, and hemostatic approaches. This study utilized the keywords Hemorrhage, Bleeding, Animal Modeling, and Hemostat in reputable databases. The findings indicate that femoral artery hemorrhage and hepatic parenchymal hemorrhage are the predominant modeling techniques for compressible and noncompressible bleeding, respectively. Furthermore, it is noted that animal models of compressible hemorrhages are primarily situated in superficial body areas to investigate dressing or additive hemostats, while non-compressible hemorrhage models, typically located in visceral organs, are employed to examine adhesive or surgical instrumentbased hemostats.

Hemorrhage is a prevalent side effect of various injuries and can be life-threatening in certain instances. It is categorized into compressible and non-compressible types, each necessitating distinct modeling, laboratory assessments, and hemostatic approaches. This study utilized the keywords Hemorrhage, Bleeding, Animal Modeling, and Hemostat in reputable databases. The findings indicate that femoral artery hemorrhage and hepatic parenchymal hemorrhage are the predominant modeling techniques for compressible and noncompressible bleeding, respectively. Furthermore, it is noted that animal models of compressible hemorrhages are primarily situated in superficial body areas to investigate dressing or additive hemostats, while non-compressible hemorrhage models, typically located in visceral organs, are employed to examine adhesive or surgical instrumentbased hemostats.

Hemorrhage is a prevalent side effect of various injuries and can be life-threatening in certain instances. It is categorized into compressible and non-compressible types, each necessitating distinct modeling, laboratory assessments, and hemostatic approaches. This study utilized the keywords Hemorrhage, Bleeding, Animal Modeling, and Hemostat in reputable databases. The findings indicate that femoral artery hemorrhage and hepatic parenchymal hemorrhage are the predominant modeling techniques for compressible and noncompressible bleeding, respectively. Furthermore, it is noted that animal models of compressible hemorrhages are primarily situated in superficial body areas to investigate dressing or additive hemostats, while non-compressible hemorrhage models, typically located in visceral organs, are employed to examine adhesive or surgical instrumentbased hemostats.

Hemorrhage is a prevalent side effect of various injuries and can be life-threatening in certain instances. It is categorized into compressible and non-compressible types, each necessitating distinct modeling, laboratory assessments, and hemostatic approaches. This study utilized the keywords Hemorrhage, Bleeding, Animal Modeling, and Hemostat in reputable databases. The findings indicate that femoral artery hemorrhage and hepatic parenchymal hemorrhage are the predominant modeling techniques for compressible and noncompressible bleeding, respectively. Furthermore, it is noted that animal models of compressible hemorrhages are primarily situated in superficial body areas to investigate dressing or additive hemostats, while non-compressible hemorrhage models, typically located in visceral organs, are employed to examine adhesive or surgical instrumentbased hemostats.