Aim：Past studies have indicated that eugenol can slowly permeate into the inflamed dental pulp chamber through dentin, resulting in anti-inflammatory and analgesic effects. However, there are variations in the eugenol concentration that penetrates through dentin in different research studies. Moreover, there has been limited research on the impact of eugenol on healthy human dental pulp cells（hDPCs）. While utilizing eugenol for its anti-inflammatory and analgesic properties in dental clinical practice, understanding its effects on healthy cells is crucial. This study aims to explore the eugenol permeation through dentin, its cytotoxicity, and its impact on inflammatory response in healthy hDPCs, as well as investigating relevant cellular signaling pathways. Materials and methods： The study consists of three main parts. The first part involves an in vitro experiment using the transwell dentin disc model with mass spectrometers to detect and analyze the permeation ability of varying concentrations of eugenol through 0.5mm dentin over 12 and 24 hours. In the second part, hDPCs obtained from extracted teeth are cultured and exposed to eugenol at concentrations determined in the previous part. Cell morphology are observed using an optical microscope, and cell viability is analyzed using the MTT assay. The third part involves treating healthy hDPCs with eugenol for different time durations. The effects of eugenol on pro-inflammatory pathways and intracellular signaling molecules are examined using Western blot and Immunofluorescence techniques. Additionally, pre-treatment with U0126 （MEK/ERK inhibitor） was conducted in healthy hDPCs to investigate eugenol's influence on signaling pathways. Results： After 12 hours of permeation through 0.5mm dentin, the eugenol concentrations of IRM® and 10mM were approximately 82.6µM and 61.3µM, respectively. After 24 hours, the eugenol concentrations were approximately 242.3µM and 387µM, respectively. Eugenol concentrations below 500µM had minimal impact on the cell viability and morphology of human dental pulp cells. However, concentrations higher than 500µM started to induce changes in cell viability and morphology. Cell death observed at concentrations greater than 1.5mM within 12 hours. In healthy hDPCs exposed to 500µM or 1000µM eugenol for approximately three hours, we observed the highest levels of phosphorylation in ERK 1/2, p38, and NF-κB. Concurrently, the expression of COX-2 exhibited an upward trend over time following treatment with 500μM or 1000µM eugenol. U0126 inhibited the increase in COX-2 levels in healthy hDPCs induced by eugenol. Conclusion：(1)Both IRM® and eugenol can penetrate through dentin. Whether using IRM® or a 10mM eugenol solution, the permeation concentrations were below 500µM in the dentin disc model. Such permeation concentrations do not exhibit cytotoxicity to human dental pulp cells and have minimal impact on their behavior.(2)Eugenol concentrations below 500µM have limited effects on the cell viability and morphology of human dental pulp cells, while concentrations above 500µM start to induce changes in cell viability and morphology. At concentrations higher than 1.5mM, cell death was observed within 12 hours, indicating high cytotoxicity of eugenol at high concentrations.(3)U0126 inhibited the increase in COX-2 levels in healthy hDPCs induced by eugenol. Currently, eugenol is widely used in cavity filling and indirect pulp capping procedures due to its antibacterial, anti-inflammatory, analgesic, and nerve-calming effects. Utilizing these properties may reduce root canal treatments in the future. However, high concentrations of eugenol can be cytotoxic to cells, and direct contact with dental pulp cells should be avoided. Research on the effects of eugenol on dental pulp cells is crucial for dental clinical treatment, and further investigations should explore its impact on COX-2 expression and related signaling pathways to optimize its clinical applications.