Impact of treated wastewater irrigation on vegetable growth, yield, and heavy metal bioaccumulation in a semi-arid greenhouse environment: A case study in Neyshabur, Iran

Keramati, Sara; Keramati, Sanaz; Das, Saima

doi:10.22034/jhmr.2025.553295.1001

Impact of treated wastewater irrigation on vegetable growth, yield, and heavy metal bioaccumulation in a semi-arid greenhouse environment: A case study in Neyshabur, Iran

https://doi.org/10.22034/jhmr.2025.553295.1001

Volume 1, Issue 1 - Serial Number 1
Winter 2026

Pages 17-27

Document Type : Original Article

Authors

Sara Keramati ¹

Sanaz Keramati ²

Saima Das ³

¹ Faculty of Agricultural Sciences and Food Industries, Islamic Azad University of Mashhad

² Education and Training Organization of Khorasan Razavi, Mashhad, Iran

³ Environmental Physiology Laboratory, Department of Botany, Aligarh Muslim University, India

Abstract

This study investigates the potential of using treated municipal wastewater to irrigate fenugreek, spinach, radish, and carrot crops in Neyshabur, Iran, as a sustainable response to water scarcity in arid regions. Greenhouse experiments were conducted under three irrigation regimes—100% groundwater (control), 50% wastewater blend, and 100% wastewater—to assess growth performance, yield, and soil and plant quality. Irrigation with 100% wastewater significantly enhanced plant growth, biomass, leaf area, and yield, particularly in fenugreek, due to the wastewater’s high nutrient content (nitrogen, phosphorus, potassium, and organic matter), which improved soil fertility despite increased salinity and pollution indicators (EC, BOD, COD). Heavy metal analyses revealed elevated concentrations of Pb, Ni, Zn, Cu, Cr, and Cd in soils irrigated with wastewater, yet all remained below international safety standards. Although metal accumulation in plant tissues rose with wastewater use, concentrations were within FAO/WHO permissible limits, except for cadmium (Cd), which showed a transfer factor (TF) greater than 1 in root vegetables, indicating higher mobility from soil to edible parts. Overall, treated wastewater proved to be a promising alternative water and nutrient source for vegetable cultivation in water-limited areas like Neyshabur, enhancing productivity without immediate health risks, though continuous monitoring of cadmium accumulation is essential to prevent potential long-term soil and food safety issues.

Keywords

Wastewater Reuse

Heavy Metals

Soil Contamination

Food Safety

Semi-Arid Agriculture

Neyshabur

Subjects

Agriculture and Food

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Impact of treated wastewater irrigation on vegetable growth, yield, and heavy metal bioaccumulation in a semi-arid greenhouse environment: A case study in Neyshabur, Iran

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