Upper Gastrointestinal Simulator

Features of Upper Gastrointestinal Simulator

• Composition of gastrointestinal tract 3D model: Fixed model part: model base and upper cover, nasal cavity, oral cavity, throat, esophagus, stomach and duodenum.

• Replaceable model part: simulated polyp.

• Procedure: Gastroscopy, upper gastrointestinal biopsy, and polypectomy.

• Versatile training: As one of the top medical simulator manufacturers, we are committed to ensuring that the gastrointestinal simulator supports a variety of upper gastrointestinal operation training, including endoscopy, biopsy, polypectomy, etc., to help medical professionals improve their skills comprehensively.

• Other characteristics: Based on the CT data of the adult upper digestive tract, this stomach anatomy model is designed and made of soft silica gel material. Among the Endo Sim, the models of mouth, nose, throat, esophagus, stomach, and duodenum are highly close to the relevant anatomical structures of the human body, and the operation feel is realistic.

  
  

Specification of Upper Gastrointestinal Simulator

Upper GI endoscope training model	MODEL: PLXH1003 (medical simulation models)
Main Material	Highly soft silica gel, hardness:18A~30A
Product Size	Model length: 30cm (11.8 in)
	Model width: 30 cm (11.8 in)
	Model height: 75 cm (29.5 in)
Lead Time	15 days
Port	Shanghai, China

Drawing of Upper Gastrointestinal Simulator

Highly Realistic Operation Feel

• Our gastrointestinal tract models use high-quality silicone or other biomimetic materials to simulate the texture and elasticity of human tissue.

  
  

• The anatomical structure of these gastrointestinal tract models is highly accurate and detailed, and can realistically reproduce various parts of the human gastrointestinal tract.

  
  

• Our gastrointestinal simulator can simulate the dynamic changes of human tissue during operation, such as tissue movement, deformation and rebound.

  
  

• The high-end series gastrointestinal tract 3D model simulates the temperature and humidity inside the human body to further enhance the realism of operation.

Preclinic GI Tract Model: Committed to Provide Conditions Close to the Real in Vivo Environment

A high-quality GI tract model needs to accurately simulate the physical, chemical and biological characteristics of the gastrointestinal tract, including the folds of the stomach wall, the secretion of gastric juice, intestinal peristalsis, etc. We continue to develop more advanced human digestive system 3D models to better simulate the complex environment of the human gastrointestinal tract. Our gastrointestinal simulator can simulate the physical and chemical environment of the gastrointestinal tract to a certain extent, and the degree of simulation is gradually improved through continuous technological innovation.

Preclinic Gastrointestinal Simulator Helps More Students Achieve Their Training Goals

• Precise anatomical structure: The gastrointestinal simulator uses advanced simulation technology to accurately reproduce the anatomical details of the upper gastrointestinal tract, including the esophagus, stomach, and duodenum.

• Real tissue texture: Using high-quality silicone material, the gastrointestinal tract 3D model simulates the softness and elasticity of human tissue, providing a realistic touch and operating resistance.

• Dynamic functional simulation: Preclinic gastrointestinal model can simulate the peristalsis, contraction, and fluid flow of the upper gastrointestinal tract, providing a dynamic operating environment and enhancing clinical response capabilities.

• Pathological state and visual feedback: The gastrointestinal tract model is equipped with a variety of lesion models and high-definition endoscopic fields of view, providing real-time operating feedback to help students identify and handle different clinical scenarios.

Gastrointestinal Tract Model Application: Efficacy Evaluation of Functional Foods

The high-precision gastrointestinal tract model is able to reproduce the environmental conditions of different digestive stages, such as pH, enzyme activity, and intestinal microbiota. This simulation can more accurately predict the actual effects of functional foods in the human body. Researchers can use this gastrointestinal model to conduct in vitro experiments, reducing reliance on animal experiments while improving the repeatability and reliability of experiments. The efficacy evaluation of functional foods includes their effects on nutrient absorption, intestinal health, and overall metabolism. The gastrointestinal tract 3D model can also help identify potential side effects and adverse reactions, thereby improving food safety.