Biomedical Engineering Reference
In-Depth Information
engineering, gene therapy and genetically modified foods. Can we
modifycellsviabiophotonics,byimitatinghowthebiogenicelectric
(E)andmagnetic(H)fieldswork?Canweuseelectromagnetic(EM)
fields in a more refined manner of therapy than pharmaceuticals,
genetics ormacroscopic engineeringalone?
The genetic information stored within DNA is an internal form
of bioinformation that is unfolded and unpacked, as needed. Each
page is read and the chemical instructions carried out. As each
page of coded instructions is implemented, the outside world
inputs via molecular and biophotonic means. Incubation requires
an environment that is supportive of the overall process, not just
biochemical particulates, but a nurturing medium, including the
fields and the ambient energy bath. In terms of an analogy, we may
think of DNA as consisting of letters and words forming topics with
pages. The various proteins are the managers who read the words
on the topic's pages and delegate the work. Yet the various fields do
the actual work of growth and development.
Knowledgeofchemistryhasbeenlimitedbytheinherentinaccu-
racy of quantum mechanics (QM) with its Heisenberg uncertainty
principle. Molecular chemistry, the nanoscopic view of biology, is
incomplete. SFT sees gravitation all the way up to and including
the cosmological level as a form of molecular interaction. Till
recently this lack was not understood, even though Einstein flagged
the problem before World War II (WWII). Our health and safety
standards are still at present written around the macroscopic tenet
of temperature changes to a piece of tissue one cubic centimetre
in volume. Classical EM, as given by Maxwell's equations, is linked
to present-day macroscopic bioeffects. This is not a su
ciently
detailedviewtounderstandembryology.Weneedtounderstandthe
biophotonic level of interaction. How do cells replicate via the fields
that are biogenic to tissues? And where do the fields come from? By
understanding these field mechanisms and how they percolate into
action, we progress. This is achieved via SFT that sees the overall
division process as a series of balances followed by transitions
and eventually cascades across molecular states. It is not only via
atomic-level chemical processes but by the interplay between fields
and biomolecular structures that the processes involved in division
occur. As with the question whether the photon is a wave or a
