Search Results (3)

Biochar is a carbon-rich material that enhances nutrient availability, soil quality, and microbial activity, improving plant growth and crop productivity. In this study, the palm oil midrib biochar (POMB) was used as a soil conditioner to improve the growth of romaine lettuce (Lactuca sativa L. var. longifolia), together with a biofertilizer containing a newly isolated bacterial strain SM11. The newly isolated SM11 was closely related to Bacillus siamensis, with 99.77% similarity based on 16s rRNA gene sequence analysis. POMB treatment improved the fresh weight of romaine lettuce by up to 181.33 ± 1.15 g plant⁻¹, which is equivalent to 160.27% growth enhancement compared to the control without POMB. By comparison, POMB treatment with a biofertilizer containing SM11 increased fresh weight to 275.67 ± 11.59 g plant⁻¹ with a growth enhancement of 295.68%. The addition of SM11 biofertilizer also protected against disease during cultivation. The addition of POMB reduced nitrate accumulation in romaine lettuce from 631.38 ± 0.36 to 223.31 ± 0.20 mg kg⁻¹ by 59.08% compared to the control. This study suggests a way to manage agricultural waste from local palm oil plantations, thereby reducing waste accumulation and adding value to palm oil waste by-products for agricultural benefit through a biotechnological process. Full article

Plant factories with artificial lighting (PFALs), with well-insulated and airtight structures, enable the production of large quantities of high-quality plants year-round while achieving high resource use efficiency. However, despite the controlled environment in PFALs, variations in plant individuals have been found, which affect productivity in PFAL operations. Plant phenotyping plays a crucial role in understanding how the surrounding microenvironment affects variations in plant phenotypes. In the current study, a modular phenotyping system for seedling production was developed, focusing on practicality and scalability in commercial PFALs. Experiments on seedlings, which strongly affect productivity, were conducted to obtain cotyledon unfolding time and the time series projected area of cotyledons and true leaves of individual seedlings of romaine lettuce (Lactuca sativa L. var. longifolia), using RGB images. This was also undertaken to analyze how the surrounding microenvironment of photosynthetic photon flux densities and nutrients affect growth variations for plant cohort research. In agreement with the actual measurements, variations in seedling growth were identified even under similar microenvironments. Furthermore, the results demonstrated larger variations in seedlings with higher relative growth. Aiming for simplified interactions of phenotypes with the microenvironment, management, and genotype, seedling selection and breeding with plant production in PFALs may enable plant uniformity and higher productivity. Full article

Plant phenotyping plays a crucial role in understanding variations in the phenotype of individual plants affected by environment, management, and genotype. Measurement of seed germination is an important phenotyping stage as germination impacts on the whole plant growth process. However, germination measurement has been limited to germination percentage of a seed population. Understanding of the germination time, from sowing to outbreak of the radicle from seed coat, at a single seed level is essential. How individual germination time and further plant growth are affected by its microenvironment and management factors remains elusive. Plant phenotype measurement system was developed to assess individual germination time of romaine lettuce (Lactuca sativa L. var. longifolia), using time-series two-dimensional camera images, and to analyze how microenvironment (volumetric water percent in seed tray, individual seed surface temperature and air temperature) and management factors (coated/uncoated seeds) affect the germination time for plant cohort research, emphasizing practicality in commercial cultivation. Germination experiments were conducted to demonstrate the performance of the system and its applicability for a whole plant growth process in a plant factory for commercial production and/or breeding. The developed phenotyping platform revealed the effects of microenvironment and management factors on germination time of individual seeds. Full article