Nanobiotechnology, bionanotechnology, and nanobiology are terms that refer to the intersection of nanotechnology and biology.
Given that the subject is one that has only emerged very recently,
bionanotechnology and nanobiotechnology serve as blanket terms for
various related technologies.
This discipline helps to indicate the merger of biological research with various fields of nanotechnology. Concepts that are enhanced through nanobiology include: nanodevices (such as biological machines), nanoparticles, and nanoscale phenomena that occurs within the discipline of nanotechnology. This technical approach to biology allows scientists to imagine and create systems that can be used for biological research. Biologically inspired nanotechnology uses biological systems as the inspirations for technologies not yet created. However, as with nanotechnology and biotechnology, bionanotechnology does have many potential ethical issues associated with it.
This discipline helps to indicate the merger of biological research with various fields of nanotechnology. Concepts that are enhanced through nanobiology include: nanodevices (such as biological machines), nanoparticles, and nanoscale phenomena that occurs within the discipline of nanotechnology. This technical approach to biology allows scientists to imagine and create systems that can be used for biological research. Biologically inspired nanotechnology uses biological systems as the inspirations for technologies not yet created. However, as with nanotechnology and biotechnology, bionanotechnology does have many potential ethical issues associated with it.
A ribosome is a biological machine.
The most important objectives that are frequently found in
nanobiology involve applying nanotools to relevant medical/biological
problems and refining these applications. Developing new tools, such as
peptoid nanosheets,
for medical and biological purposes is another primary objective in
nanotechnology. New nanotools are often made by refining the
applications of the nanotools that are already being used. The imaging
of native biomolecules, biological membranes, and tissues is also a major topic for the nanobiology researchers. Other topics concerning nanobiology include the use of cantilever array sensors and the application of nanophotonics for manipulating molecular processes in living cells.
Recently, the use of microorganisms
to synthesize functional nanoparticles has been of great interest.
Microorganisms can change the oxidation state of metals. These microbial
processes have opened up new opportunities for us to explore novel
applications, for example, the biosynthesis of metal nanomaterials. In
contrast to chemical and physical methods, microbial processes for
synthesizing nanomaterials can be achieved in aqueous phase under gentle
and environmentally benign conditions. This approach has become an
attractive focus in current green bionanotechnology research towards
sustainable development.
Terminology
The
terms are often used interchangeably. When a distinction is intended,
though, it is based on whether the focus is on applying biological ideas
or on studying biology with nanotechnology. Bionanotechnology generally
refers to the study of how the goals of nanotechnology can be guided by
studying how biological "machines" work and adapting these biological
motifs into improving existing nanotechnologies or creating new ones.
Nanobiotechnology, on the other hand, refers to the ways that
nanotechnology is used to create devices to study biological systems.
In other words, nanobiotechnology is essentially miniaturized biotechnology, whereas bionanotechnology is a specific application of nanotechnology. For example, DNA nanotechnology
or cellular engineering would be classified as bionanotechnology
because they involve working with biomolecules on the nanoscale.
Conversely, many new medical technologies involving nanoparticles
as delivery systems or as sensors would be examples of
nanobiotechnology since they involve using nanotechnology to advance the
goals of biology.
The definitions enumerated above will be utilized whenever a
distinction between nanobio and bionano is made in this article.
However, given the overlapping usage of the terms in modern parlance,
individual technologies may need to be evaluated to determine which term
is more fitting. As such, they are best discussed in parallel.
Concepts
Most
of the scientific concepts in bionanotechnology are derived from other
fields. Biochemical principles that are used to understand the material
properties of biological systems are central in bionanotechnology
because those same principles are to be used to create new technologies.
Material properties and applications studied in bionanoscience include
mechanical properties (e.g. deformation, adhesion, failure),
electrical/electronic (e.g. electromechanical stimulation, capacitors,
energy storage/batteries), optical (e.g. absorption, luminescence,
photochemistry), thermal (e.g. thermomutability, thermal management),
biological (e.g. how cells interact with nanomaterials, molecular
flaws/defects, biosensing, biological mechanisms s.a. mechanosensing),
nanoscience of disease (e.g. genetic disease, cancer, organ/tissue
failure), as well as computing (e.g. DNA computing) and agriculture (target delivery of pesticides, hormones and fertilizers.
The impact of bionanoscience, achieved through structural and
mechanistic analyses of biological processes at nanoscale, is their
translation into synthetic and technological applications through
nanotechnology.
Nano-biotechnology takes most of its fundamentals from
nanotechnology. Most of the devices designed for nano-biotechnological
use are directly based on other existing nanotechnologies.
Nano-biotechnology is often used to describe the overlapping
multidisciplinary activities associated with biosensors, particularly
where photonics,
chemistry, biology, biophysics, nano-medicine, and engineering
converge. Measurement in biology using wave guide techniques, such as dual polarization interferometry, are another example.
Applications
Applications
of bionanotechnology are extremely widespread. Insofar as the
distinction holds, nanobiotechnology is much more commonplace in that it
simply provides more tools for the study of biology. Bionanotechnology,
on the other hand, promises to recreate biological mechanisms and
pathways in a form that is useful in other ways.
Nanomedicine
Nanomedicine is a field of medical science whose applications are increasing more and more thanks to nanorobots and biological machines,
which constitute a very useful tool to develop this area of knowledge.
In the past years, researchers have done many improvements in the
different devices and systems required to develop nanorobots. This
supposes a new way of treating and dealing with diseases such as cancer;
thanks to nanorobots, side effects of chemotherapy have been
controlled, reduced and even eliminated, so some years from now, cancer
patients will be offered an alternative to treat this disease instead of
chemotherapy, which causes secondary effects such as hair loss, fatigue
or nausea killing not only cancerous cells but also the healthy ones.
At a clinical level, cancer treatment with nanomedicine will consist of
the supply of nanorobots to the patient through an injection that will
search for cancerous cells while leaving untouched the healthy ones.
Patients that will be treated through nanomedicine will not notice the
presence of these nanomachines inside them; the only thing that is going
to be noticeable is the progressive improvement of their health.
Nanobiotechnology
Nanobiotechnology (sometimes referred to as nanobiology) is best described as helping modern medicine progress from treating symptoms to generating cures and regenerating biological tissues. Three American patients have received whole cultured bladders
with the help of doctors who use nanobiology techniques in their
practice. Also, it has been demonstrated in animal studies that a uterus can be grown outside the body and then placed in the body in order to produce a baby. Stem cell treatments have been used to fix diseases that are found in the human heart
and are in clinical trials in the United States. There is also funding
for research into allowing people to have new limbs without having to
resort to prosthesis. Artificial proteins might also become available to manufacture without the need for harsh chemicals and expensive machines. It has even been surmised that by the year 2055, computers may be made out of biochemicals and organic salts.
Another example of current nanobiotechnological research involves
nanospheres coated with fluorescent polymers. Researchers are seeking
to design polymers whose fluorescence is quenched when they encounter
specific molecules. Different polymers would detect different
metabolites. The polymer-coated spheres could become part of new
biological assays, and the technology might someday lead to particles
which could be introduced into the human body to track down metabolites
associated with tumors and other health problems. Another example, from a
different perspective, would be evaluation and therapy at the
nanoscopic level, i.e. the treatment of Nanobacteria (25-200 nm sized)
as is done by NanoBiotech Pharma.
While nanobiology is in its infancy, there are a lot of promising
methods that will rely on nanobiology in the future. Biological systems
are inherently nano in scale; nanoscience must merge with biology in
order to deliver biomacromolecules
and molecular machines that are similar to nature. Controlling and
mimicking the devices and processes that are constructed from molecules
is a tremendous challenge to face the converging disciplines of
nanotechnology. All living things, including humans, can be considered to be nanofoundries.
Natural evolution has optimized the "natural" form of nanobiology over
millions of years. In the 21st century, humans have developed the
technology to artificially tap into nanobiology. This process is best
described as "organic merging with synthetic." Colonies of live neurons can live together on a biochip device; according to research from Dr. Gunther Gross at the University of North Texas. Self-assembling nanotubes have the ability to be used as a structural system. They would be composed together with rhodopsins; which would facilitate the optical computing process and help with the storage of biological materials. DNA (as the software
for all living things) can be used as a structural proteomic system - a
logical component for molecular computing. Ned Seeman - a researcher at
New York University - along with other researchers are currently researching concepts that are similar to each other.
Bionanotechnology
DNA nanotechnology is one important example of bionanotechnology. The utilization of the inherent properties of nucleic acids like DNA
to create useful materials is a promising area of modern research.
Another important area of research involves taking advantage of membrane properties to generate synthetic membranes. Proteins that self-assemble
to generate functional materials could be used as a novel approach for
the large-scale production of programmable nanomaterials. One example is
the development of amyloids found in bacterial biofilms as engineered nanomaterials that can be programmed genetically to have different properties. Protein folding
studies provide a third important avenue of research, but one that has
been largely inhibited by our inability to predict protein folding with a
sufficiently high degree of accuracy. Given the myriad uses that
biological systems have for proteins, though, research into
understanding protein folding is of high importance and could prove
fruitful for bionanotechnology in the future.
Lipid nanotechnology
is another major area of research in bionanotechnology, where
physico-chemical properties of lipids such as their antifouling and
self-assembly is exploited to build nanodevices with applications in
medicine and engineering.
Agriculture
Nanotechnology
application to biotechnology leaves no field untouched by its
groundbreaking scientific innovations for human wellness; the
agricultural industry is no exception. Basically, nanomaterials are
distinguished depending on the origin: natural, incidental and
engineered nanoparticles. Among these, engineered nanoparticles have
received wide attention in all fields of science, including medical,
materials and agriculture technology with significant socio-economical
growth.
In the agriculture industry, engineered nanoparticles have been serving
as nano carriers, containing herbicides, chemicals, or genes, which
target particular plant parts to release their content.
Previously nanocapsules containing herbicides have been reported to
effectively penetrate through cuticles and tissues, allowing the slow
and constant release of the active substances. Likewise, other
literature describes that nano-encapsulated slow release of fertilizers
has also become a trend to save fertilizer consumption and to minimize
environmental pollution through precision farming. These are only a few
examples from numerous research works which might open up exciting
opportunities for nanobiotechnology application in agriculture. Also,
application of this kind of engineered nanoparticles to plants should be
considered the level of amicability before it is employed in
agriculture practices. Based on a thorough literature survey, it was
understood that there is only limited authentic information available to
explain the biological consequence of engineered nanoparticles on
treated plants. Certain reports underline the phytotoxicity of various
origin of engineered nanoparticles to the plant caused by the subject of
concentrations and sizes . At the same time, however, an equal number
of studies were reported with a positive outcome of nanoparticles, which
facilitate growth promoting nature to treat plant.
In particular, compared to other nanoparticles, silver and gold
nanoparticles based applications elicited beneficial results on various
plant species with less and/or no toxicity.
Silver nanoparticles (AgNPs) treated leaves of Asparagus showed the
increased content of ascorbate and chlorophyll. Similarly, AgNPs-treated
common bean and corn has increased shoot and root length, leaf surface
area, chlorophyll, carbohydrate and protein contents reported earlier. The gold nanoparticle has been used to induce growth and seed yield in Brassica juncea.
Tools
This field relies on a variety of research methods, including experimental tools (e.g. imaging, characterization via AFM/optical tweezers etc.), x-ray diffraction based tools, synthesis via self-assembly, characterization of self-assembly (using e.g. MP-SPR, DPI, recombinant DNA methods, etc.), theory (e.g. statistical mechanics, nanomechanics, etc.), as well as computational approaches (bottom-up multi-scale simulation, supercomputing).
