Biosensors as Emerging Market: Obstacles to Implement
Russian Case
A. A. Balyakin
1
, E. V. Blokhina
2
, G. E. Kunina
1,3
and S. B. Taranenko
1,3
1
National Research Center Kurchatov Institute, 1, ac. Kurchatov sq., Moscow, Russia
2
Univeresity College Dublin, Belfield, Dublin 4, Co. Dublin, Ireland
3
NGO “ANEK”, 16 Maximova str., Moscow, Russia
Keywords: Biosensors, Emerging Market, Distant Medicine, Health System, Prognosis.
Abstract: We discuss the modern trend in high tech medicine connected with biosensors implementation. Though this
technology being mature with a number of interesting technological and/or scientific solutions, the
corresponding market has not been formed yet. In our work we try to summarize the obstacles for
biosensors implementation using Russian Federation as an example of a country with strong governmental
support for health care system. We argue that biosensors implementation should give rise for more proper
monitoring and data handling, providing more correct choice of treatment, but should not be regarded as
medical solutions.
1 INTRODUCTION
The modern pace of high technology development
inevitably raises the question of its practical
application, and medicine is one of the most
promising areas. In particular, the general trend of
devices miniaturization and progress in data
handling have led to the possibility of developing
biosensor systems used for the treatment and
diagnosis of social diseases. Currently, the
increasing worldwide attention is given to the
prospects of usage of implantable sensors that
register the parameters of human body.
In Russian Federation, the implementation of
high-tech medicine service into reality is listed as
government priorities, with special attention paid to
the development of distant medicine. The need for
such development is due to several reasons: first, an
aging population and the associated rapid growth of
health care costs, second - the growing shortage of
qualified medical staff, third - the technical
readiness for such devices production, and fourth -
the defence needs.
We conducted a study of probable biosensors
that could be implemented in Russia. The focus of
our work was given to devices and approaches
aimed at reducing mortality in the following areas:
diseases of the cardiovascular system, control blood
sugar levels, the disease of the gastrointestinal tract,
and timely medication to the patient (drug delivery).
As a result of our work we formed a list of
ready-to-produce devices that are in demand on the
Russian market. This work is still under progress,
and we are searching for new devices that could be
implemented. Hereafter we present the results of our
work as of 1 September 2013.
Totally about 150 companies were considered. It
was found that following companies are the leading
manufacturers and suppliers of implantable cardiac
pacemakers and defibrillators: Medtronic, Boston
Scientific, Biotronik and St. Jude Medical. Leading
manufacturers and suppliers of implantable
neurostimulators are Medtronic, and St. Jude
Medical. These four companies account for 56
selected technical solutions while all other
companies produce only 28 items.
Russian companies provide original solutions
exclusively to the diagnosis and treatment of
diseases of the cardiovascular system. Three main
companies were identified - The Bakulev Center for
Cardiovascular Surgery (Bakulev CCVS) of the
Russian Academy of Medical Sciences (RAMS),
Federal State Unitary Enterprise "IMZ" and
"Kardioelektronika" Ltd. We also found several
commercialized solutions for gastrointestinal tract
diseases (particularly endocapsule "Lily of the
Valley", developed by specialists of the Moscow
102
A. Balyakin A., V. Blokhina E., E. Kunina G. and B. Taranenko S..
Biosensors as Emerging Market: Obstacles to Implement - Russian Case.
DOI: 10.5220/0004748301020106
In Proceedings of the International Conference on Biomedical Electronics and Devices (BIODEVICES-2014), pages 102-106
ISBN: 978-989-758-013-0
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
Engineering Physics Institute). Though many
Russian companies are said to operate in the field of
high-tech medicine, we found that actually only 14
companies should be taken into account.
Major domestic results are still in the category of
research, not many of them are ready for practical
implementation. Thus, the analysis of 250 Russian
projects under the Federal Target Program
"Research and development on priority directions of
scientific-technological complex of Russia for 2007-
2013" revealed just 39 projects related to biosensors,
and only 3 of them were proved to be ready for
practical implementation.
Our short list of practical solutions contains 51
devices dealing with cardiovascular disease (market
leaders - pacemakers, 43 items), 8 devices dealing
with gastro-intestinal tract problems, 4 devices for
blood sugar levels control, 10 neurostimulators (5 of
them - at the stage of clinical trials, awaiting
approve from FDA), and 11 other devices (typically
- a targeted drug delivery system).
Comparative analysis of health care financing in
the United States, Russia and other countries shows
that the level of funding in Russia is about 20 times
lower than in the U.S. The Russian market of mobile
biosensors by 2015 will be about 1.5-2% of the
world (with the prospect of up to 3%), i.e. will be
largely a niche market with no significant export
prospects (unless special measures are taken, such as
production localization, building a cooperation
research-production-implementation via
governmental demand).
The expected growth in the Russian biosensors
market is expected to be rather high, (about 10% in
2014-2017), with gradual decreasing (down to 5%
after 2017). In this case, based on the market size of
$ 300 million to date, by 2015 the expected volume
will be 585 million, in 2020 - 845 million (18 and 26
billion roubles, respectively). Under certain
conditions (first of all - managerial) distant market
medicine in Russia in 2020 could amount to 70
billion roubles.
2 OBSTACLES TO IMPLEMENT
This forecast is however rather uncertain. Most
analysts suppose the very problem is technological,
and do not take into account obstacles that would
arise after the device is ready for fabrication. During
our study we encounter a number of obstacles that
prevent biosensors to become the large-scale market
in nearest future. This does not mean the
impossibility to produce such devices, but rather
refers to their usage and/or consequences that we
suppose would be very different from ones expected
now.
2.1 Technological Issues
First, let us consider problems derived from
technological aspects. At present, modern advances
in technology allow the design and implementation
of very complex integrated microscale systems,
including MEMS and labs-on-a-chip for biological
applications. By a complex system we should
understand a system that includes components from
different physical domains and their behaviour is not
obvious from the behaviour of their components.
BioMEMS are true complex systems in this sense.
They perform multiple functions and they combine
elements from different physical domain. Therefore,
there will be a number of difficulties in the
fabrication and applications of BioMEMS that arise
from their complexity and are typical for other
MEMS devices. On the other hand, there will be
specific issues related to the presence of biological
agents and biological functions performed by
BioMEMS.
Among the general difficulties from the first
group, we should mention the following:
The lack of tools for the complete modelling
and design of BioMEMS. In addition, we still
need to develop the understanding of their
behaviour on the system level. This will
become an issue in the next years since the
modern technology allows the fabrication and
integration of extremely complex and multi-
function systems;
Issues related to the reliability, lifetime and
long-term stability of used materials and the
dependence of their properties on the
environment;
The reliability and lifetime issues can be
expanded specifically to BioMEMS.
BioMEMS are particularly sensitive to short-
term and long-term material stability issues.
The materials used for BioMEMS as reacting
agents must be biocompatible and highly
selective. (i.e. the material must accurately
quantify a selected bio-agent in the
environment where many other bio-agents can
also be found). The materials used for
BioMEMS structure and wafers must also be
biologically stable and compatible and
resistant to oxidation;
The lifetime of material/devices is also a very
sensitive point. Particularly for implanted
BiosensorsasEmergingMarket:ObstaclestoImplement-RussianCase
103
bioMEMS when there is no possibility to
replace the device too often;
Since we mentioned implanted BioMEMS
(which are impossible to access too often to
replace batteries), effective power supply is
another problem;
It is widely argued if the device could operate
independently or if it should be controlled by
an operator. At any case this issue requires a
stable connection and/or synchronization with
PC.
It is important to understand that due to the
complexity of such systems, designers have to
address numerous issues: packaging, material
selection, energy efficiency, signals acquiring and
processing, biocompatibility and etc. There are
many researchers that tackle these issues at different
levels. For instance, material reliability/selection is
solved by introducing new materials. Lifetime and
power consumption is solved on the engineering side
by introducing low-power efficient control circuitry
and energy harvesting from human/environment
motion. Signal processing – by improving the
algorithms that allows to analyse sparse or distorted
signals. Finally modelling and design is a multi-
disciplinary area addressed by researches in the area
of physics, engineering biology and mathematics.
2.2 Data Handling
Most biosensors work with numerous data obtained
from human body and handling it is a great
challenge.
First, by now most biosensors work as devices
individually adjusted in any chosen case. That
means the necessity of individual data handling.
Second, it is still not clear what data is sufficient.
How much information should be collected? And if
we gather all possible information, is it possible to
transmit and analyse it? What part of data could be
lost without serious consequences? Third, if a
biosensor is supposed not to only monitor, but also
to act as a therapeutic tool, the question is what
algorithms should be used to take the decision? And
to what extent could we transfer this option from a
man to the computer?
All these issues are not new, and most of them
have been successfully solved in other areas
(decision making, data processing, etc.), but in case
of biosensors one should take into account that most
information is private or can be supposed to be
private, that restricts its usage.
2.3 Ethical Aspects of Biosensor
Implementation
In our opinion, in Russia in the near future two
problems with moral and ethical aspects of the use
of biosensors will manifest: on the one hand -
populist and unexamined, but vibrant domestic
"threats", and on the other - articulated long-term
questions from abroad (where this problem has been
studied for a much longer time). The first will be as
permanent bursts, in which interest will be warmed
up by certain quarters for their own purposes
(political or financial), the second - will be the
limiting factor in a number of research, development
and implementation for the Russian market.
Let us list a number of basic problems of moral
and ethical plan, relevant in Russia:
First, it is a threat to establish total control over
the person from the state or medical services. In the
Russian emphasis it is the suppression of the
individual, while in the West the problem is
considered from the point of view of the loss of
human autonomy and the loss of personality.
Secondly, the problem “end justifies the means”.
This problem is always neglected in Russia, but is a
key issue for Western professionals: what is to
improve a man? Where man ends and a machine
starts, if any? It continues to the general concept of
life and death in the concept of modified human. Is it
ethical to interfere in the future?
Third, issues related to information security (that
is very closely connected with data handling
problems). What information collected by
biosensors, is ethical? What information can and
should be collected? Should we limit the collection
of information? There is no doubt that the
widespread adoption and use of biosensors will lead
to a correction of the relevant laws.
Fourth, the issue of equality and accessibility of
services in the field of bio-sensing technology. Who
could use biosensor technology and why? What are
the limits? Price? Religious beliefs? We note a great
concern of probable inequality that could derive
from biosensor implementation in nearest future.
Fifth, what would be the overall effect of high
tech implementation in medicine on the society? On
the socio-political structure, the economics, etc.? We
have not found any detailed study yet. Let us just
mention a survey on high-tech medicine conducted
in Russia in 2012 that reveals the following. Just
16% are familiar with this issue, 68% see no need of
high-tech implementation, the average amount of
subsidy from the government was about 4000 USD,
83% got the information from their physician, the
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main drawback mentioned by people were quotas for
high–tech medicine implementation. Thus we see
that people just do not understand what biosenors
mean and if they can be used in their everyday life.
2.4 Institutional Aspects of Biosensor
Market Formation in Russia
The formation of the market of high-technology
medical care in Russian Federation today is hindered
by a number of institutional factors that need to be
addressed.
First of all, it is the lack of institutionalization of
the actors of the market - the economic and
technological agents that form stable types of
behaviour in the market, both in the short and in the
long term. Institutionally, the market of high-
technology medical care in Russia, as in many other
countries, is not a classic, i.e. the consumer of health
services, as it was not veiled insurance mechanisms,
not the taxpayer, which determines the range of the
market. That is the government, and precisely – the
main actor is the Ministry of Health of Russia that
forms the demand in high-tech care in Russian
Federation, as well as put the standards for them.
That is easily understood in term of price and money
needed: the only source for a large-scale financing is
governmental budget.
However, Russian Ministry of Health constitutes
its viewpoint based on medical issues, i.e. is inclined
to current medical practice, not assuming innovative
proposals that the market could offer today and/or in
the future. The only actors, able to properly move
the aspects in the formation of the nomenclature of
the market towards the introduction of the
achievements of biosensor technologies are experts’
community. One of them is the technological
platform "Medicine of the Future", that brings
together specialists from different fields and
organizations in solving the general problem of the
development of new high-tech face of the Russian
medicine - the task set and maintained by the state.
Biosensors are distinguished as a special trend
within the Technology Platform. Among the
organizations that might have a major influence on
the direction of development of high-tech medicine,
it is necessary to highlight the National Research
Centre "Kurchatov Institute" - a fundamentally
interdisciplinary leading research and technology
centre in the country with the functions of the
organization and promotion of technologies in
various sectors of the Russian Federation.
Thus we conclude that nowadays the position of
experts’ community is crucial: they can attract more
attention to biosensors, influencing the authorities to
bring innovative ideas into practice.
Another important issue is financing the
biosensor technology implementation. By now it is
supposed to be financed via the Fund of obligatory
medical insurance. However expensive medical
treatment (or rather long one) could not be afforded
and the idea is to develop a voluntary medical
insurances company. Scientific research is funded
through highly specialized grants systems (Russian
Foundation for Basic Research, Bortnik Fund, etc.).
Commercialization is supposed to be supported by
Vnesheconombank program (public-private
partnership for the development of distant medical
services). There are some signs of big mobile
operators’ interest to this issue. In 2012 Beeline (one
of three largest mobile companies in Russia)
conducted a test of mobile medicine usage in
Moscow region that has rather promising results.
Thirdly, the very important issue is the question
of standards. Data collecting (what exactly, with
which preciseness, etc.), parameters of the devices
(size, weight, electrical circuits inside, etc.),
parameters of the resulted information (what is
“out”?). If those standards refer to medicine?
Technical devices? Information processing? This
question has not been solved yet, and biosensors can
be considered differently: there is no precise rule.
Practically, he, who establishes the standards, will
control the market. Russian Federation strives to
strictly protect its independence, and do not adopt
foreign standards. European Union, as can be
concluded from plans of Horizon 2020, will not
supervise it, and European standards are supposed to
follow ones proposed by the US. This means that for
Europe the United States will form the biosensors
market, and demand will be defined by US needs
and preferences.
3 CONCLUSIONS
The problems of biosensors implementation are not
limited to the obstacles listed above, and for sure
there are a lot of other issues that would arise while
developing the biosensor market. Our work is still
continuing, and we are currently updating the lists of
technical solutions appropriate for Russian market,
as well as lists of challenges.
We stress, however, the hope that biosensor
could solve all medical problems and distant
medicine would substitute the old one is useless.
So what could be “Dream Biosensor”? To
answer this question we conduct a short survey of
BiosensorsasEmergingMarket:ObstaclestoImplement-RussianCase
105
specialists in the field of medicine and
biotechnology. By the end of 2013 we received more
than 100 filled questionnaires. Experts stress that the
device should be small (light weight), should deal
preferably with cardiovascular decease, and should
have some new (re)charging mechanisms. The last
peculiarity seems to be the most important.
An ideal “Dream Biosensor” could be described
as passive universal implantable medical device that
measures and transmits to mobile devices and/or
personal computers a number of selected indicators
(such as temperature, pulse, blood pressure, the
content sugar in the blood). The collected data are
used for 2 purposes: first, the government has the
precise statistics about national health, and can
modify its politics in accordance with real situation;
and second it can be used for better medical
treatment. This should be performed either by the
patient himself advised by a physician (likely after
the case of alert), or by specialist who interprets the
data distantly. The decision making procedure could
never be fully automatized, and human control
proves to be necessary.
One can hope that in this case the biosensor
would not be too “individual” with high price, and
could be produced in a large numbers in different
areas of the country.
Thus, to our viewpoint biosensors should be
considered as a tool to optimize the decision
concerning health issues. And those decisions could
be both medical and managerial: what treatment
would be better? What politics should be followed?
As the government is the main customer of high-
tech medicine in Russia, its position will be decisive.
At the same time, as of today the market in Russia
has not formed yet, the purpose of all stakeholders
(both Russian organizations and foreign
manufacturers) is to form the market, to identify key
trends and to offer a wide range of devices for
different price range which could be introduced in
Russia.
Thus, we see three essential steps for biosensor
market development in Russia. First, to form the
consolidated viewpoint of experts’ community.
Second, to influence the government, to convince
the authorities to support distant medicine
implementation. And third, to arrange the production
of the devices. We note that similar model attracting
the most promising and profitable solutions for their
implementation under the governmental control,
could then be replicated in other countries with
strong state influence on the health system.
ACKNOWLEDGEMENTS
This work was supported by RFBR grant 13-02-
12111.
REFERENCES
Global Healthcare Exchange (http://www.ghx.com/).
Healthcare in Russia. Stat. Dig. Rosstat. Moscow. 2011 (in
Russian).
Implantable Medical Devices Industry Study #2852. 2012
(http://www.freedoniagroup.com/).
The Industrial Property Digital Library
(http://www.ipdl.inpit.go.jp/homepg_e.ipdl).
European Patent Office. Database (http://www.epo.org/).
Russian patent office. Database. (http://www1.fips.ru/).
The US patent office. Database. (http://www.uspto.gov).
Google patent database. (http://www.google.com/
?tbm=pts).
Eurasian patent information system (http://
www.eapatis.com/).
Federal Target Program “Research and development on
priority directions of scientific-technological complex
of Russia for 2007-2013” (http://www.fcpir.ru/).
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