Abstract
A root growth chamber is described which allows seedling root growth dynamics and structure to be monitored continuously under a variety of conditions for several weeks. The chamber consists of two cells with inner dimensions 18×20×0.12 cm. To simulate the soil matrix, each cell was filled with spherical glass beads of 0.1 cm diameter. Given the 0.12 cm width of each cell, the glass bead matrix was approximately one bead layer thick. Roots were therefore grown in a quasi -two-dimensional and transparent environment. This enabled root images of high spatial and temporal resolution to be collected and analysed quantitatively using standard image analysis techniques. The chamber was constructed such that the root environment could be manipulated with regard to nutrient distribution, `soil' matrix structure and other perturbations to the system. Preliminary experiments of the growth dynamics of lentil roots (Lens culinaris L. cv. Verte du Puy) in the chamber were conducted. The majority of the primary and lateral roots followed a similar growth pattern with high growth rates between days 5 and 9 and days 14 and 18 separated by a period of low growth rate between days 10 and 12 after seeding in the chamber. Thus, primary and lateral root growth was to a certain extent synchronized. Lateral roots developed after 3 to 8 days on the outer curve (convex side) of the primary root. The roots shared many of the characteristics of roots developed in three-dimensional systems indicating that the chamber did not induce artificial root behaviour. Thus, the idealized and quantitative studies that can be conducted in the chamber may enable many aspects of the complex interactions between the root system and environment to be studied.
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Futsaether, C.M., Oxaal, U. A growth chamber for idealized studies of seedling root growth dynamics and structure. Plant and Soil 246, 221–230 (2002). https://doi.org/10.1023/A:1020609224525
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DOI: https://doi.org/10.1023/A:1020609224525