Abstract:Wet chemistry was used to produce copper oxide nanoparticles (CuO NPs). The results indicated that most nanoparticles were bacillus-shaped and relatively uniform in size (less than 30 nm). The effect of synthesized CuO NPs on wheat (Triticum aestivum L.) germination and growth parameters was studied and compared to bulk Cu. The results showed that no significant difference was obtained in germination rate among all treatments. Bulk Cu additions significantly affect the mean germination rate and mean germinatio… Show more
“…To our knowledge, there have been no prior reports on seed germination inhibition due to application of HgO-NPs, while inhibitory impacts of other nano-sized heavy metals on seed germination of several plants have been studied. For example, declines of germination indicators were recorded in wheat treated with CuO NPs (Ibrahim et al, 2022), rice treated with Y2O3-NPs (Zhao et al, 2021) and maize treated with PbS-NPs (Ullah et al, 2020), Al2O3 and TiO2-NPS (Karunakaran et al, 2016). All these studies have consistently shown that the toxicity of the applied NPs increases in tandem with the dose, which aligns with our data.…”
Section: Hgo-nps Application Delayed Germination Of Maize Seedssupporting
confidence: 90%
“…Once accumulated in soil, toxic agents such as heavy metal nanoparticles (HM-NPs) inhibit seeds germination and development of early seedlings in several plants (Asadi-Kavan et al, 2020;Seddighinia et al, 2020). In this regard, retardation of germination and growth of young seedlings due to nano-sized heavy metals, such as PbS-NPs (Ullah et al, 2020), CuO-NPs (Ibrahim et al, 2022), Y2O3-NPs (Zhao et al, 2021) and ZnO NPs (Yang et al, 2023), have been studied in maize, wheat, rice and Arabidopsis thaliana, respectively. These authors ascribed the delaying of seed germination and deterioration of seedling growth to: (a) deactivation of seed' amylase and protease via formation of S-Metal-S bridges instead of -SH group in the enzyme' proteins (b) blocking of aquaporins delay the rupture of seed coat and emergence of radical (c) restraining water imbibition and uptake due to metal-induced ionic toxicity (d) generation of free radicals and cellular oxidative damage, (e) decreasing internodal length and plant height and (f) distortion of root structures and disruption of water uptake.…”
Given the widespread use of the mercuric oxide NPs (HgO-NPs), they have become increasingly prevalent in the soil ecosystem. As a result, it is important to promptly evaluate their phytotoxic impact on plants. To this end, we have investigated the effects of different concentrations of HgO-NPs (0-200 mg/L) on germination and growth of early emerged maize seedlings. Moreover, the primary root length was measured over time to examine the impacts of both time and doses of HgO-NPs on root growth, specifically studying their interactive effects. Additionally, HgO-NPs effects on root anatomical structures were investigated. Relative to control, HgO-NPs induced marked reductions in germination (percentage, speed and rate) while, increased mean germination time, mean daily germination time and time to 50% germination. Moreover, length and biomass of radical (root) and plumule (shoot) and seedling vigour indices were significantly deteriorated. The obtained inhibition in growth was more pronounced in root than shoot. Growth declines of young maize seedlings were concomitant with a dose and time dependent inhibition of root elongation. This response of root was consistent with the observed reduction in anatomical features, including root diameter, stele size, cortex size and cortex cell count. HgO-NPs effect was does dependent, where the decrease in maize germination and growth became more pronounced at higher doses of HgO-NPs. The most significant reduction was observed at a concentration of 200 mg/L HgO-NPs. The results of this study suggest that the presence of HgO-NPs leads to phytotoxic effects on germination process and the growth of young seedlings, highlighting a noteworthy challenge and environmental concern.
“…To our knowledge, there have been no prior reports on seed germination inhibition due to application of HgO-NPs, while inhibitory impacts of other nano-sized heavy metals on seed germination of several plants have been studied. For example, declines of germination indicators were recorded in wheat treated with CuO NPs (Ibrahim et al, 2022), rice treated with Y2O3-NPs (Zhao et al, 2021) and maize treated with PbS-NPs (Ullah et al, 2020), Al2O3 and TiO2-NPS (Karunakaran et al, 2016). All these studies have consistently shown that the toxicity of the applied NPs increases in tandem with the dose, which aligns with our data.…”
Section: Hgo-nps Application Delayed Germination Of Maize Seedssupporting
confidence: 90%
“…Once accumulated in soil, toxic agents such as heavy metal nanoparticles (HM-NPs) inhibit seeds germination and development of early seedlings in several plants (Asadi-Kavan et al, 2020;Seddighinia et al, 2020). In this regard, retardation of germination and growth of young seedlings due to nano-sized heavy metals, such as PbS-NPs (Ullah et al, 2020), CuO-NPs (Ibrahim et al, 2022), Y2O3-NPs (Zhao et al, 2021) and ZnO NPs (Yang et al, 2023), have been studied in maize, wheat, rice and Arabidopsis thaliana, respectively. These authors ascribed the delaying of seed germination and deterioration of seedling growth to: (a) deactivation of seed' amylase and protease via formation of S-Metal-S bridges instead of -SH group in the enzyme' proteins (b) blocking of aquaporins delay the rupture of seed coat and emergence of radical (c) restraining water imbibition and uptake due to metal-induced ionic toxicity (d) generation of free radicals and cellular oxidative damage, (e) decreasing internodal length and plant height and (f) distortion of root structures and disruption of water uptake.…”
Given the widespread use of the mercuric oxide NPs (HgO-NPs), they have become increasingly prevalent in the soil ecosystem. As a result, it is important to promptly evaluate their phytotoxic impact on plants. To this end, we have investigated the effects of different concentrations of HgO-NPs (0-200 mg/L) on germination and growth of early emerged maize seedlings. Moreover, the primary root length was measured over time to examine the impacts of both time and doses of HgO-NPs on root growth, specifically studying their interactive effects. Additionally, HgO-NPs effects on root anatomical structures were investigated. Relative to control, HgO-NPs induced marked reductions in germination (percentage, speed and rate) while, increased mean germination time, mean daily germination time and time to 50% germination. Moreover, length and biomass of radical (root) and plumule (shoot) and seedling vigour indices were significantly deteriorated. The obtained inhibition in growth was more pronounced in root than shoot. Growth declines of young maize seedlings were concomitant with a dose and time dependent inhibition of root elongation. This response of root was consistent with the observed reduction in anatomical features, including root diameter, stele size, cortex size and cortex cell count. HgO-NPs effect was does dependent, where the decrease in maize germination and growth became more pronounced at higher doses of HgO-NPs. The most significant reduction was observed at a concentration of 200 mg/L HgO-NPs. The results of this study suggest that the presence of HgO-NPs leads to phytotoxic effects on germination process and the growth of young seedlings, highlighting a noteworthy challenge and environmental concern.
“…In agreement with those results obtained from exposed Mung beans [29] and maize seeds [56], TiO 2 NPs were able to penetrate pomegranate seeds, as confirmed through TEM, XRF, and ICP-OES, which is the first direct evidence of TiO 2 NP uptake in pomegranate seed tissues. Such evidence of TiO 2 internalization by plant tissues is also in accordance with a variety of other metal-based nanoparticles, including Fe 3 O 4 , Au, and Cu nanoparticles [57][58][59].…”
Seed priming is a novel approach that is undertaken to improve seed germination and therefore potentially enhance growth and yield. Low-cost, eco-friendly, and efficient seed treatment as a means of enhancing growth and yield is still being sought for high-value crops such as pomegranates (Punica granatum L.), particularly in areas situated at high altitudes such as the Taif region. The uptake of nanoparticles (NPs) by plants provides a potential pathway for NP exposure. Therefore, it is imperative to understand NP uptake via seed priming and their unique properties within plants. In the present study, titanium dioxide nanoparticles (TiO2NPs) were green-synthesized and utilized as priming agents for pomegranate seeds at a concentration of 40 mg/mL for 24 h. The adsorption of NPs was verified by scanning electron microscopy (SEM) and energy dispersive X-ray analysis/spectroscopy (EDX), while their incorporation was detected by transmission electron microscopy (TEM). To validate the EM results, X-ray fluorescence (XRF) and inductively coupled plasma optical emission spectroscopy (ICP–OES) techniques were further undertaken. The results confirmed the successful synthesis of pure anatase TiO2NPs by employing aqueous extracts of pomegranate fruit peel (PPE) and coffee ground beans (CE). All of the analytical techniques employed in this research confirmed the incorporation of TiO2NPs inside seeds, even after storage during priming treatment. This study lays the foundation for future sustainable seed technologies in terms of crop productivity and seed germination.
“…This appears further encouraging in light of the similar repots highlighting soil organic carbon's role in nutrient mobilisation and environmental sustainability 16 , 31 , 33 . However, amid increasing concerns over the bio and environmental compatibility of the poorly defined nanomaterials and lack of enough information over their mechanism and efficiency, this needs vigorous investigation 37 , 38 . Figure 9 A schematic diagram showing the whole process from the synthesis of the ZnO NPs to its application; The interaction between negatively charged soil colloidal carbon surface with positively charged ZnO NPs (sheet-like structure); nano surfaces along with other mineral nutrients interactions in soil solution for nutrient uptake efficiency has also been shown.…”
Nanotechnology appears to be a promising tool to redefine crop nutrition in the coming decades. However, the crucial interactions of nanomaterials with abiotic components of the environment like soil organic matter (SOM) and carbon‒sequestration may hold the key to sustainable crop nutrition, fortification, and climate change. Here, we investigated the use of sugar press mud (PM) mediated ZnO nanosynthesis for soil amendment and nutrient mobilisation under moderately alkaline conditions. The positively charged (+ 7.61 mv) ZnO sheet-like nanoparticles (~ 17 nm) from zinc sulphate at the optimum dose of (75 mg/kg blended with PM (1.4% w/w) were used in reinforcing the soil matrix for wheat growth. The results demonstrated improved agronomic parameters with (~ 24%) and (~ 19%) relative increases in yield and plant Zn content. Also, the soil solution phase interactions of the ZnO nanoparticles with the PM-induced soil colloidal carbon (− 27.9 mv and diameter 0.4864 μm) along with its other components have influenced the soil nutrient dynamics and mineral ecology at large. Interestingly, one such interaction seems to have reversed the known Zn-P interaction from negative to positive. Thus, the study offers a fresh insight into the possible correlations between nutrient interactions and soil carbon sequestration for climate-resilient crop productivity.
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