420 9.4 Personalizing Healthcare
normal process of endocytosis by which eukaryotic cells internalize extracellular material
(see Chapter 2). Other emerging targeted delivery tools involve synthetic biological 3D
nanostructures, for example, made from DNA, to act as molecular cages to enable the effi
cient delivery of a variety of drugs deep into a cell while protecting it from normal cellular
degradation processes before it is released to exert its pharmacological effect.
Exciting nanomedicine developments also include bionanoelectric devices to interface
with nerve and muscle tissue, such as in the brain and the heart. Devices used in cellular
repair are sometimes referred to as nanoscale robots, or nanobots. Much recent media
coverage concerning nanobots has involved speculation over the terrifying implications were
they to go wrong. Such as consuming the entire Earth or at the very least turning it into a
gray goo. However, the realistic state of the art in nanobot technology is still at a technically
challenging stage; to get even natural nanoscale machines to work unmodified outside of
their original biological function, let alone to generate de novo molecular machines that can
be programmed by the user to perform cellular tasks, is hard enough, as any veteran student
in this area of biophysics will attest!
The most promising emerging area of nanomedicine currently involves methods to facili
tate tissue regeneration. This can be achieved through the use of biomimetic materials and
the application of stem cells. Stem cells in multicellular eukaryotic organisms are cells that
have not yet differentiated. Differentiation is not to be confused with the mathematical term
in calculus, but here is a biological process in which cells undergo morphological and bio
chemical changes in their life cycle to commit to being a specific cell type, for example, a
nerve cell and a muscle cell. However, prior to this stage, cells are described as stem cells and
can in principle differentiate into any cell type depending on external triggers involving both
the external chemical environment and mechanical signals detected by the cell from the out
side world. Thus, if stem cells are transplanted from an appropriate donor source, they can
in principle replace damaged tissue. In some countries, including the United States, there are
still some levels of ongoing ethical debate as to the use of stem cells as a therapeutic aid to
alleviate human suffering.
The development of biomimetic structures as replacements for damaged/diseased tissues
has experienced many successes, such as materials either directly replace the damaged tissue
and/or act as a growth template to permit stem cells to assemble in highly specific regions
of space to facilitate the generation of new tissues. Biomimetic tissue replacement materials
focus largely on being mimics for the structural properties of the healthy native tissue, for
example, hard structural tissues such as bone and teeth and also softer structural extracel
lular matrix material such as collagen mimics.
Biocompatible inorganic biomimetics has focused on using materials that can be
synthesized in aqueous environments under physiological conditions that exhibit chemical
and structural stability. These particularly include noble metals such as gold, platinum, and
palladium, as well as metal oxide semiconductors such as zinc oxide and copper(I) oxide,
but also chemically inert plastics such as polyethylene, which benefit from having a low
frictional drag while being relatively nonimmunogenic, and also some ceramics, and so all
have applications in joint replacements. Inorganic surfaces are often precoated with short
sequence peptides to encourage binding of cells from surrounding tissue.
Collagen is a key target for biomimetization. It provides a structural framework for the
connective tissues in the extracellular matrix (see Chapter 2) as well as plays a key role in the
formation of new bone tissue from bone producing cells (called osteoblasts) embedded in
the extracellular matrix. Chemically modifying collagen, for example, by generating multiple
copies of a cell binding domain, can increase the rate at which new bone growth occurs. This
effect can be characterized using a range of biophysical techniques such as confocal micros
copy and SEM in vitro. Thus, modified collagen replacement injected into the connective
tissue of a patient suffering from a bone depletion disease into local regions of bone deple
tion, detected and quantified using x-ray and CT imaging in vivo, can act as a biomimetic
microenvironment for osteoblasts to stimulate the regeneration of new bone tissue.
Mimicking the naturally porous and fibrous morphology of the extracellular matrix can
also be utilized in biomimetization of tissues and organs. Some biomimetic tissues can be