Morphology-tailored hydroxyapatite nanocarrier for rhizosphere-targeted phosphorus delivery
High hydrophilicity and soil fixation collectively hamper the delivery of phosphorus (P) released from conventional chemical phosphorus fertilizers (CPFs) to plant rhizosphere for efficient uptake. Here, a phosphorus nutrient nanocarrier (PNC) based on morphology-tailored nanohydroxyapatite (HAP) is...
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sg-ntu-dr.10356-1689712023-06-26T01:20:33Z Morphology-tailored hydroxyapatite nanocarrier for rhizosphere-targeted phosphorus delivery Tang, Siqi Liang, Jiaming Li, Ouyang Shao, Ningning Jin, Yongsheng Ni, Jinren Fei, Xunchang Li, Zhenshan School of Civil and Environmental Engineering Engineering::Environmental engineering Phosphate Starvation Response Phosphorus Nutrient Nanocarriers High hydrophilicity and soil fixation collectively hamper the delivery of phosphorus (P) released from conventional chemical phosphorus fertilizers (CPFs) to plant rhizosphere for efficient uptake. Here, a phosphorus nutrient nanocarrier (PNC) based on morphology-tailored nanohydroxyapatite (HAP) is constructed. By virtue of kinetic control of building blocks with designed calcium phosphate intermediates, rod-like and hexagonal prism-like PNCs are synthesized, both having satisfactory hydrophobicity (water contact angle of 105.4–132.9°) and zeta potential (−17.43 to −58.4 mV at pH range from 3 to 13). Greenhouse experiments demonstrate that the P contents increase by up to 183% in maize rhizosphere and up to 16% in maize biomass when compared to the CPF. Due to the water potential gradient driven by photosynthesis and transpiration, both PNCs are stably transported to maize rhizosphere, and they are capable to counteract soil fixation prior to uptake by plant roots. Within the synergies of the HAP morphological characteristics and triggered phosphate starvation response, root anatomy confirms that two pathways are elucidated to enhance plant P replenishment from the PNCs. Together with structure tunability and facile synthesis, our results offer a new nanodelivery prototype to accommodate plant physiological traits by tailoring the morphology of HAP. The authors acknowledge the financial support from the National Natural Science Foundation of China (41171005 and 32202605) and the National Key Research and Development Program of China (2022YFC3201801). 2023-06-26T01:20:33Z 2023-06-26T01:20:33Z 2023 Journal Article Tang, S., Liang, J., Li, O., Shao, N., Jin, Y., Ni, J., Fei, X. & Li, Z. (2023). Morphology-tailored hydroxyapatite nanocarrier for rhizosphere-targeted phosphorus delivery. Small, 19(14), 2206954-. https://dx.doi.org/10.1002/smll.202206954 1613-6810 https://hdl.handle.net/10356/168971 10.1002/smll.202206954 19 2-s2.0-85145720714 14 19 2206954 en Small © 2023 Wiley-VCH GmbH. All rights reserved. |
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Engineering::Environmental engineering Phosphate Starvation Response Phosphorus Nutrient Nanocarriers |
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Engineering::Environmental engineering Phosphate Starvation Response Phosphorus Nutrient Nanocarriers Tang, Siqi Liang, Jiaming Li, Ouyang Shao, Ningning Jin, Yongsheng Ni, Jinren Fei, Xunchang Li, Zhenshan Morphology-tailored hydroxyapatite nanocarrier for rhizosphere-targeted phosphorus delivery |
| description |
High hydrophilicity and soil fixation collectively hamper the delivery of phosphorus (P) released from conventional chemical phosphorus fertilizers (CPFs) to plant rhizosphere for efficient uptake. Here, a phosphorus nutrient nanocarrier (PNC) based on morphology-tailored nanohydroxyapatite (HAP) is constructed. By virtue of kinetic control of building blocks with designed calcium phosphate intermediates, rod-like and hexagonal prism-like PNCs are synthesized, both having satisfactory hydrophobicity (water contact angle of 105.4–132.9°) and zeta potential (−17.43 to −58.4 mV at pH range from 3 to 13). Greenhouse experiments demonstrate that the P contents increase by up to 183% in maize rhizosphere and up to 16% in maize biomass when compared to the CPF. Due to the water potential gradient driven by photosynthesis and transpiration, both PNCs are stably transported to maize rhizosphere, and they are capable to counteract soil fixation prior to uptake by plant roots. Within the synergies of the HAP morphological characteristics and triggered phosphate starvation response, root anatomy confirms that two pathways are elucidated to enhance plant P replenishment from the PNCs. Together with structure tunability and facile synthesis, our results offer a new nanodelivery prototype to accommodate plant physiological traits by tailoring the morphology of HAP. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Tang, Siqi Liang, Jiaming Li, Ouyang Shao, Ningning Jin, Yongsheng Ni, Jinren Fei, Xunchang Li, Zhenshan |
| format |
Article |
| author |
Tang, Siqi Liang, Jiaming Li, Ouyang Shao, Ningning Jin, Yongsheng Ni, Jinren Fei, Xunchang Li, Zhenshan |
| author_sort |
Tang, Siqi |
| title |
Morphology-tailored hydroxyapatite nanocarrier for rhizosphere-targeted phosphorus delivery |
| title_short |
Morphology-tailored hydroxyapatite nanocarrier for rhizosphere-targeted phosphorus delivery |
| title_full |
Morphology-tailored hydroxyapatite nanocarrier for rhizosphere-targeted phosphorus delivery |
| title_fullStr |
Morphology-tailored hydroxyapatite nanocarrier for rhizosphere-targeted phosphorus delivery |
| title_full_unstemmed |
Morphology-tailored hydroxyapatite nanocarrier for rhizosphere-targeted phosphorus delivery |
| title_sort |
morphology-tailored hydroxyapatite nanocarrier for rhizosphere-targeted phosphorus delivery |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/168971 |
| _version_ |
1772825572299243520 |