Urea is the most widely used and low-cost nitrogen fertilizer in agriculture. However, it is seldom used as a nitrogen source in hydroponic culture due to its poor nitrogen use efficiency. These results could be related to the lose sight of Ni supplement. Plants utilized urea via urease to hydrolysis it into ammonia for further assimilation process. Ni is of importance for activation of urease and hence for promoting plants to utilize urea in urea-based nutrients. Partially replacing nitrate with urea in hydroponic culture could reduce nitrate content in vegetable crops and reduce the risk of excessive nitrate intake. Therefore, the objective of this study was to develop urea-containing nutrient formula especially in view of Ni addition. We hope this nutrient formula could be applied on low-nitrate vegetable crops production. In order to investigate the effect of Ni on urea-based solution on plant growth, nitrate and nutrient content. Water spinach (Ipomoea aquatic cv. Taoyuan No. 1) were grown in deep flow technic system (DFT) with nutrient based on Hoagland solution. NO3-N were partially replaced with urea-N, while the total-N were the same. The research was divided into four experiments. In the 1st experiment, we used six Ni concentration (0-85.3 μM) with 7 mM urea-N to observe the Ni toxic effect on water spinach. Excess Ni (> 8.6 μM) inhibited plant growth. Young leaves had chlorosis or necrosis symptoms and Fe content in leaf were aslo decreased. Ni might affect Fe uptake and occupy Fe-related enzyme, and cause symptoms that similar to Fe deficiency. Then in the 2nd experiment, five Ni concentration (0-4 μM) with two urea-N level (0, 8 mM) were used to find the suitable Ni dosage in nutrients. With appropriate Ni addition (0.5, 1 μM), plant growth were improved and the Ni content in roots were higher in the presence of urea. In the 3rd experiment, seven urea levels (0-10 mM) combined with suitable Ni dosage (0, 1 μM ) to evaluate the degree of substitution urea for nitrate on plants response. Water spinach could growth well under high urea-N dosage (10 mM). Ni addition could increase water spinach growth under 6, 8 mM urea-N and drcreased nitrate content 21% compared to no urea control. The content of Ca in whole plant, Fe and Zn in root decreased under high urea dosage, while Mn in roots increased under high urea dosage. Among these nutrients, root Fe content significantly declined as urea dosage increased, which showed the distinct difference compared to traditional no-urea formula. Under the same 1 μM Ni addition, root Ni content in plants were positively correlated to urea concentration in nutrients. These trend were in agreement with the result of the 2nd experiment. The 4th experiment was to monitor the absorption of urea-N, NH4-N and NO3-N from nutrients. Nutrients contained three levels of urea-N (2, 4, 10 mM) and two levels of Ni (0, 1 μM). Ni addition significantly increased water spinach urea-N uptake rate and decreased NH4-N uptake rate. While Ni addition only decreased NO3-N uptake rate in the first week under Ni addition. Water spinach could grow well and effectively reduce nitrate content in shoots under high urea-N dosage. These advantages provided some potential of applying this urea-based formula on water spinach. Appropriate addition of Ni promoted water spinach urea absorption and improve growth in 6, 8 mM urea-N. The demand of Ni for water spinach was also higher in the existence of urea. These evidences demonstrated the essentiality of Ni on designing a urea-based hydroponic culture system.