Previous studies have shown that organic matter (OM) can affect the arsenic (As) mobilization and bioavailability in soil as this may lead to the increase of As uptake into rice plants and pose human health risks since the As-exposure pathway via food chain. But the relationship between organic matter and As in the soils are not clear. Therefore, the aim of this study is to evaluate the effect of various organic amendments on As availability in As-contaminated soils and accumulation in rice seedlings. Two different properties of agricultural soils (Pinchen soil, Pc, and Chengchung soil, Cf) which were spiked with 0 and 150 mg As(V) kg-1 respectively and two Guandu soils (Gd) with low and high levels of As concentrations were used in this study. Soybean meal (SB), cattle-dung compost (CD), and sugarcane dregs compost (SC) were added into soils at the application rates of 0, 1, and 4 % (dry weight bases). The soils equilibrated at field water capacity condition for 21 days, and then flooding incubation and pot experiments for growing rice seedlings were performed. The results showed that the formation of iron plaque were increased, and there was a significantly positive correlation (P＜0.001) between the amounts of As and Fe in iron plaque, which might sequestrate As. However, the application of organic amendments increased As uptake by rice seedlings. The use of organic amendments enhanced As accumulation in rice plant whereas shoot biomass of rice seedlings grown in As-contaminated Pc and Gd soils treated with 1% SB was significantly increased. In addition, the rice seedlings in both non-added As(V) and As-contaminated Pc soils died which amended with 4 % SB treatment, and it was probably due to fertilizer burn; and the rice seedlings under additions of 4 % SB and SC in As-contaminated Cf soils were dead but not found in non-added As(V) Cf soils, it was subjected to serious As toxicity. The proportion of As in solution phase is easily absorbed by rice seedlings. The concentrations of As in soil solutions were increased by the applications of organic amendments, and thus As uptake by rice seedlings was enhanced, while the extent of increase varied depending on soils and organic amendments. The application of organic amendments will increase the DOC concentration in soil solutions while the extent of increase was the highest under the SB treatment. The DOC concentrations were significantly correlated to the As concentrations in soil solution, presumably that DOC can compete with As for adsorption sites at soil surface or forming soluble OM-As complexes. On the other hand, the increase of soil pH and the decrease of the soil redox potential (Eh) were also observed. The variation of soil characteristics resulted in difference of elevating As release to the soil solution amended with organic amendments, and the lowest effect were found under the CD treatments. Cf soil which has high pH and low levels of clay content and iron and aluminum oxides content was found to have low affinity for As and thus resulting in As concentration in soil solutions of 4% SB treatment was higher than 15 mg L-1. In conclusion, the addition of organic amendments, especially for more decomposable organic amendments could increase the As release and consequent As uptake by rice. This effect could be more obvious in soils with high pH value and low As sorption ability which was resulting in the increase of As toxicity of rice seedlings. Therefore, it is important to evaluate the properties of organic amendments and soils carefully while adding organic materials into As-enriched soils.