Animal wastes as fertilizers enhance growth of young walnut trees under soil drought conditions.

BACKGROUND: Using nutrient-rich animal wastes as organic fertilizers in agricultural practices is a sustainable method for soil amendment and avoiding environmental pollution. In order to evaluate their practical effect, we applied different proportions of animal waste as fertilizers to wet or dry soils that were either planted or not planted with young walnut trees. RESULTS: The results showed that animal waste could increase soil C accumulation and carbon to nitrogen (C/N) ratio and reduce soil organic nitrogen and total nitrogen contents as well as the nitrogen to phosphorus (N/P) ratio in the planted group soil. This framework of soil C and N composition (a high C/N ratio) resulted in high N and Mg contents as well as high Cu and Zn contents in the leaves of the young trees as well as a high dry matter weight/leaf N ratio, causing increased leaf photosynthesis, reduced transpiration and relatively high water use efficiency under soil drought conditions. Also, animal wastes as fertilizers caused the branching of walnut to switch from elongation growth to thickening growth under soil drought conditions. CONCLUSIONS: Principal component analysis and redundancy analysis demonstrated the mechanism by which the soil C/N ratio mediates the flux of available nutrients from the soil to the plant and thereby regulates plant dry matter accumulation and branching architecture under soil drought conditions. The results of this study provide new insights into the improvement of hilly soils using animal waste. © 2020 Society of Chemical Industry.

Biomimetic Nanovesicles for Enhanced Antitumor Activity of Combinational Photothermal and Chemotherapy.

The combination of multiple modalities has shown great potential in cancer treatment with improved therapeutic effects and minimized side effects. Here, we fabricated a type of doxorubicin-encapsulated biomimetic nanovesicle (NV) by a facile method with near-infrared dye insertion in the membrane for combinatorial photothermal and chemotherapy. With innate biomimetic properties, NVs enhanced the uptake by tumor cells while reducing the phagocytosis of macrophages. Upon laser irradiation, NVs can convert the absorbed fluorescent energy into heat for effective tumor killing. Hyperthermia can further induce membrane ablation of NVs to accelerate the release of chemotherapeutic drug for potent cytotoxicity to tumor cells. The NVs improved drug accumulation and showed a more efficient in vivo photothermal effect with a rapid temperature increase in tumors. Moreover, the NV-based combinational photothermal and chemotherapy exhibited significant tumor growth suppression with a high inhibitory rate of 91.6% and negligible systemic toxicity. The results indicate that NVs could be an appealing vehicle for combinational cancer treatment.