With new technological advances, the long-term use of 3C products has led to an increasing burden on the eyes. According to the previous researches, lutein can specifically accumulate in the macular and reduce the risk of macular degeneration. As a result, sufficient lutein supplementation is of critical importance. Marigold flower (Tagetes erecta) contains high amount of lutein, which is the largest source of commercial lutein supplement. However, after lutein extraction, the remaining residue is often discarded, which still contains high amounts of water-soluble phytochemicals, such as phenols, they are also effective compounds for eye health and could be wasted if abandoned. Liposome is a sphere vesicle composed of phospholipid bilayer. Compared to other nanotechnology, liposome possess several advantages including biocompatible, biodegradable, low cost, low toxicity, and able to co-encapsulate both hydrophilic and hydrophobic compounds. The purpose of this study was to co-encapsulate both hydrophilic and hydrophobic compounds extracted from marigold flower in liposomes, expand the value of marigold flower, and overcome the low stability and bioavailability of lutein. Results of this study indicated that stable marigold extract liposomes could be constructed at the molar ratio of lecithin to cholesterol 1 : 1, the molar ratio of lutein to lecithin 1 : 10, and the concentration of total phenol content in the hydration solution was 400 μg GAE/mL. The encapsulation efficiency of lutein could reach 82%, while phenolic compound was 31.7%. The particle size of the marigold extract liposome was approximately 1030.8 nm, and the zeta potential was -38.28 mV. The storage stability of lutein encapsulated in liposome was improved as compared with free lutein. In addition, the marigold extract liposome only released 3.7% lutein in simulated gastric fluid for 1 h, indicating that liposomes could protect lutein from gastric acid. Furthermore, In vitro Caco-2 intestinal permeability assay showed that the encapsulation increased 43.7% absorption rate of lutein, revealing that liposome encapsulation is a feasible way to improve lutein absorption. The protective effect of retinal epithelial cells by marigold extract liposome was also demonstrated using the ARPE-19 cell model. The viability of the cells under H2O2 induce oxidative damage was significantly increased. In conclusion, the functional marigold extract liposome was successfully constructed in this experiment, which not only increased the eye protection value of marigold flower, but also ameliorated the storage stability and absorption of lutein.