Acrylamide is an industrial chemical and exists in high temperature processed food. When exposed, it is metabolized into chemically reactive and genotoxic epoxides －　glycidamide. Evidence of its carcinogenicity has been shown via animal studies that observed tumors in multiple organs of rats and mice. However, evidence in epidemiological studies still remain inconclusive. Therefore, International Agency for Research on Cancer (IARC) listed acrylamide as a Class 2A carcinogen in 1994. The Maillard reaction between amino acids and carbohydrates has been recognized as the most probable process for producing acrylamide. Previous studies have reported that when starch-rich foods, such as potatoes, are processed in high temperature (above 120 °C), asparagine and reducing sugars would react to acrylamide, and partially decompose to degradation products. Thus, exposure to acrylamide through daily diet have become a common public concern. In this study, a systematic study was conducted to understand the effect of high-temperature processing on the formation of acrylamide. Food processing involves numerous factors that can affect the formation of acrylamide, such as processing time and temperature, followed by asparagine, free amino acids, glucose, fructose content, etc. The impact of these factors on health risks was evaluated. The objective of this study was to establish a chemical kinetic model of the food processing to discuss how the formation of acrylamide can be predicted, controlled and reduced. We use the model to predict frying for 300 seconds at 165°C, the acrylamide concentration is 0.0104 mmol/kg fat-free dry weight (equivalent to 0. 216 ppm), which is between 0.015 mmol/kg fat-free dry weight (Equivalent to 0. 312 ppm) of the simulated valueand and 0.007 mmol/kg fat-free dry weight (equivalent to 0.145 ppm) of the experimental value in the paper. These results were used as verification and show that this chemical kinetic model can be used to simulate the content of acrylamide in high-temperature processed food. Based on the simulated acrylamide concentration, integrating toxicological data and animal experiment data of acrylamide, we used The Benchmark Dose Software (version 2.7.0.4) to calculate dose response relationship. The BMDL of humans was 0.265 mg/kg/day, and the CSF was 0.377 (mg /kg/day)-1. In 2019, the National Food Database of Taiwan surveyed the consumption pattern of fries and potato foods of 19 to 65 years-old consumers and estimated the average intake to be 76.05 g per day. Monte Carlo simulation with 10,000 iterations was carried out to conduct a probabilistic estimate of the cancer risk and Margin of exposure of exposure to acrylamide through ingestion of fries potato foods. The median cancer risk of 19~65 years-old consumers was 8.64×10-5, and the upper limit of the 95% confidence interval was 4.75×10-4; the median cancer risk of 19~65 years-old male and female consumers were 7.71×10-5 and 9.31×10-5, respectively; the median MOE for of 19~65 years-old consumers, male and female were 1.15×103, 1.28×103, and 1.08×103, respectively. The sensitivity analysis of cancer risk showed that the most influential factor was the intake rate of acrylamide, which 93% positively correlated to cancer risk. From the correlation of process parameters to cancer risk, it can be observed that body weight is -0.0826, food intake is 0.31, asparagine is 0.2354, time is 0.2123, moisture is -0.282, and temperature is 0.7918, except that food intake can be improved. It is very important to start with temperature. The purpose of this research was to develop a chemical kinetic model of acrylamide in food, explore the formation mechanism of acrylamide, and improve the processing process by adjusting the model parameters. Simulate the production of acrylamide during the frying process of potato foods, and conduct a health risk assessment.