2.2 Smart Delivery Systems The use

2.2 Smart Delivery Systems

The use of pesticides increased in the second half of the 20th century with DDT
becoming one of the most effective and widespread throughout the world.
• highly toxic,
• affecting human and animal health and
• result whole ecosystems.
• As a consequence they were banned.

To maintain crop yields,
• Integrated Pest Management systems,
o mix traditional methods of crop rotation
o biological pest control methods,
o are becoming popular and implemented in many countries,

In the future, nanoscale devices with novel properties could be used to make
agricultural systems “smart”.
• identify plant health issues before these become visible to the farmer.
Such devices may be capable of responding to different situations by taking
appropriate remedial action. If not, they will alert the farmer to the problem.
In this way, smart devices will act as both a preventive and an early warning
system.
Such devices could be used to deliver chemicals in a controlled and targeted
manner in the same way as nanomedicine has implications for drug delivery
in humans.
• Nanomedicine developments are now beginning to allow us to treat different
diseases such as cancer in animals with high precision, and targeted delivery
(to specific tissues and organs) has become highly successful.
• Technologies such as encapsulation and controlled release methods, have
revolutionised the use of pesticides and herbicides.
• Many companies make formulations which contain nanoparticles within the
100-250 nm size range that are able to dissolve in water more effectively
than existing ones (thus increasing their activity).
• Other companies employ suspensions of nanoscale particles (nanoemulsions),
which can be either water or oil-based and contain uniform suspensions of pesticidal or herbicidal nanoparticles in the range of 200-400 nm. These can
be easily incorporated in various media such as gels, creams, liquids etc, and
have multiple applications for preventative measures, treatment or
preservation of the harvested product.
• One of the world’s largest agrochemical corporations, Syngenta, is using
nanoemulsions in its pesticide products. One of its successful growth
regulating products is the Primo MAXX® plant growth regulator, which if
applied prior to the onset of stress such as heat, drought, disease or traffic
can strengthen the physical structure of turfgrass, and allow it to withstand
ongoing stresses throughout the growing season.
• Another encapsulated product from Syngenta delivers a broad control
spectrum on primary and secondary insect pests of cotton, rice, peanuts and
soybeans. Marketed under the name Karate® ZEON this is a quick release
microencapsulated product containing the active compound lambda-
cyhalothrin (a synthetic insecticide based on the structure of natural
pyrethrins) which breaks open on contact with leaves.
• In contrast, the encapsulated product “gutbuster” only breaks open to release
its contents when it comes into contact with alkaline environments, such as
the stomach of certain insects.
• In other areas, scientists are working on various technologies to make
fertiliser and pesticide delivery systems which can respond to environmental
changes. The ultimate aim is to tailor these products in such a way that they
will release their cargo in a controlled manner (slowly or quickly) in response
to different signals e.g. magnetic fields, heat, ultrasound, moisture, etc.
New research also aims to make plants use water, pesticides and fertilizers more
efficiently, to reduce pollution and to make agriculture more environmentally friendly.
Smaller companies are forming alliances with major players such as LG, BASF,
Honeywell, Bayer, Mitsubishi, and DuPont to make complete plant health monitoring
systems in the next 10 years using nanotechnologies