Abstract
In recent years there has been a growing demand for the development of agrochemical controlled release (CR) technologies. In the present study, we aimed to create a novel agricultural CR device using two polymeric systems that have been predominantly employed in biomedical applications: beads of alginate hydrogel embedded with drug-bearing Polycaprolactone (PCL) microspheres. The combined device utilizes the advantages of each polymer type for biodegradation and controlled release of Paclobutrazol (PBZ), a common growth retardant in plants. Surface morphology of the alginate beads was characterized by scanning electron microscopy (SEM) and water immersion tests were performed for stability and controlled release measurements. Bioassays were performed both in accelerated laboratory conditions and in field conditions. The results showed a capability to control the size of PBZ-loaded PCL microspheres through modification of homogenization speed and emulsifier concentration. Enlargement of PCL microsphere size had an adverse effect on release of PBZ from the alginate device. The growth of oatmeal plants as a model system was affected by the controlled release of PBZ. The preliminary field experiment observed growth retardation during two consecutive rainy seasons, with results indicating a substantial benefit of the sustained growth inhibition through the controlled release formulation. The final product has the potential to be used as a carrier for different substances in the agrochemical industry.
Highlights
In recent years there has been a growing demand for the development of agrochemical controlled release (CR) technologies
Granular formulation of CR microparticles used in agrochemical applications often need to remain negatively buoyant so that the granules remain in place even when there is run-off during the rainy season
It is important to protect the polymers from the adverse effects they may encounter when subjected to extreme weather conditions during the dry season, including high levels of ultraviolet radiation caused by prolonged exposure to sunlight
Summary
In recent years there has been a growing demand for the development of agrochemical controlled release (CR) technologies. It is important to protect the polymers from the adverse effects they may encounter when subjected to extreme weather conditions during the dry season, including high levels of ultraviolet radiation caused by prolonged exposure to sunlight. These protective design features are difficult to implement with polymer formulations alone, and may require an additional organic or inorganic “matrix”, to assist in achieving the overall delivery objectives. The shape, size and degradability of the vehicle used to encapsulate the AI are important parameters that affect the release profiles As well as controlling the shape, size and degradation properties of the polymer(s), makes the desired AI release p ossible[16,17]
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