The use of indium in semiconductor products has increased markedly in recent years. The release of indium into the ecosystem is inevitable. Under such circumstances, effective and accurate assessment of indium risk is important. However, knowledge of its environmental fate has been very limited so far. This study aims to investigate indium accumulation and its toxic effects on plants, as plants constitute the base of food chains. In soil, the predominant indium species are indium associated with iron hydroxides followed by indium hydroxide and phosphate precipitates. Their solubilities determine overall indium availability in soil, which is higher at lower pHs. Most absorbed indium accumulates at the roots, with only a tiny portion reaching the grains. Indium accumulation in plants caused stunted growth, oxidative stress, anthocyanization, and unbalanced mineral nutrition. Secreted citrate could function as a potential detoxifier to repel indium uptake. Consumption of indium-contaminated food crops is potentially a major human exposure pathway. Indium accumulation in the human body is probably carcinogenic and has various adverse effects on human health, such as heart, kidney, and liver damages. To evaluate potential risks associated with indium-contaminated consumption, rice and wheat were grown on soils with different pHs and textures, including acidic soil with a high indium concentration (1.0 mmol kg-1), which is considered the worst-case scenario because it promotes the greatest indium bioavailability. The health risks to humans, based on their grain consumption, were evaluated using the Hazard Quotient (HQ). The corresponding HQ indicated no adverse effects on human health, even in the worst-case scenario. Therefore, the consumption of rice and wheat grains harvested from indium-contaminated soils probably does not warrant concern for human health. Further field studies are necessary to better elucidate the risks associated with consuming crops grown in indium contaminated soils.