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Integration of biosensors in the biomedical systems choices and outlook
- 1. INTERNATIONAL JOURNAL OF ADVANCED RESEARCH IN
International Journal of Advanced Research in Engineering and Technology (IJARET), ISSN 0976 –
6480(Print), ISSN 0976 – 6499(Online) Volume 3, Number 2, July-December (2012), © IAEME
ENGINEERING AND TECHNOLOGY (IJARET)
ISSN 0976 - 6480 (Print)
ISSN 0976 - 6499 (Online) IJARET
Volume 3, Issue 2, July-December (2012), pp. 145-152
© IAEME: www.iaeme.com/ijaret.html
Journal Impact Factor (2012): 2.7078 (Calculated by GISI)
©IAEME
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INTEGRATION OF BIOSENSORS IN THE BIOMEDICAL SYSTEMS-
CHOICES AND OUTLOOK
M.Rezki1, 3, A.Belaidi2, T.Benabdallah 1, M.Ayad3
med_rezki@yahoo.fr
1
Industrial Product and Systems Innovation Laboratory, E.N.S.E.T, University of Oran, 31000,
Algeria.
2
Department of ele ctroni c, E.N .S.E.T, University of Oran, 31000, Algeria.
3
Department of technical’s sciences, University of Bouira, 10000, Algeria.
ABSTRACT
The purpose of this paper is to present the recent technological and methodological
evolution of biosensors especially their integrability. Although there are several technologies
for biosensors, miniaturization and automation seem to be the most advantageous. This is one
of the issues addressed in this work.
Indeed, the condition for the integration of biosensors - in general with matrix form-, is
among the most critical criteria to choose from. To do this, our study will present the
criteria’s for integration of biosensors and the use of "Lab. On. Chip "as an example of an
integrated cell biosensors almost perfect and seems to be promising future technology.
In addition, we briefly review the thermal properties that may affect the integration of
biosensors.
Keywords: Biosensors, integration, Lab.On.Chip, electrochemical cells, selection
1. INTRODUCTION
The importance of biosensors is clearly demonstrated. It affects a number of areas:
biomedicine (diagnostic, medical monitoring, pharmacy), chemical engineering and
biochemistry (nutrition, environment, etc.). The need to develop fast and the robust standards
required in the areas mentioned necessitate the use of microelectronics because it offers
possibilities of micro manufacturing and automation that reduce the production costs.
The biosensor is an analytical component made to convert biologic signal to an electrical
signal that can be digitized easily in order to be integrated in an acquisition line of data. The
latter being the key element of the whole system allows us to choose small sensors that can
be transported and integrated with the electronic of command and processing [1] (figure 2).
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6480(Print), ISSN 0976 – 6499(Online) Volume 3, Number 2, July-December (2012), © IAEME
Fig. 1– Components of a biosensor [2]
Fig.2– Schematic of a biosensor with a minimal environment.
This technological trend of components miniaturization is established and also goes beyond
the anticipations of the Moore‘s law (figure 3).
Fig.3– Moore’s law (originally the law has stipulated that we can double every two years the
density of electronic components in the same surface) [3].
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6480(Print), ISSN 0976 – 6499(Online) Volume 3, Number 2, July-December (2012), © IAEME
The acquisition line of data is a shown in the figure 04:
Fig. 4– Generalized chain acquisition of a biosensor [4]
2. CLASSIFICATION OF BIOSENSORS
a. According to the technology of the transduction
The type of biological recognition determines the used type of transduction. Among
several modes of transduction, we mention:
- Calorimetric: the temperature change caused by biological reactions of bioreceptors is
translated into an electrical signal.
- Electrochemical cells: It uses the process of recognition ionic liquid environment, there are
many techniques in this detection such as: conductometry (either by the detection of
conductivity change or by measure of PH), potentiometric measure (it is the detection of
potential change of constant currant), ammeter (detection of current change to potential
constant), metallic electrodes (transmitting the effect of attachment of an electro active
substance such as gold and platinum), electronic techniques (structures EIS, ENFET,
CHEMFET, ISFET, TFT and others).
- Optics: The optical spectrum of light is detected using optical fibers.
- Mass variations: we use the piezoelectric effect; generally, quartz translates a biological
change of surface into frequencies change. There are other piezoelectric operations using
acoustic waves such as the SAW (Surface Acoustic Waves).
b. According to function
We have:
1. Enzymatic sensor: these sensors employ receptors that immobilize the enzymes.
2. Immunosensors: it is the result of antigen-antibody reaction since we know that the
immune system produces specific antigens against strange bodies (bacteria, viruses, etc.).
3. Microorganisms (Living sensors): these sensors use living tissues as selection receptors.
4. ADN Sensors and bio chips: these sensors are made to detect and/or identify blocks of
ADN sequences. Recall that the electronic sensors start replacing gradually the purely
biological sensors that use the detection techniques along with marking.
3. BASIC CHARACTERISTICS OF A BIOSENSOR
We mention:
- Linearity: the calibration curve of bio-sensor must be the most possible linear in the entire
area measure and even for strong concentration of the analyte.
- Selectivity: aptitude to give correct result having the least possible interference for different
chemical substances.
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- Sensibility: it is a response value of an electrode for a given concentration.
- Response time: the required time to reach 95% of the response and it must be minor.
- Reproducibility: it consists of obtaining almost the same result with the same biosensor
according to various different methods and even with different operators.
- Biocompatibility: it is the biosensor ability of being efficient in adequate response to a
specific application (example: a special chemical to be detected).
4. THE BIOSENSOR REAL DIFFICULTIES
Actually, we face many problems which may affect the development of biosensors. Among
them we mention the following [5]:
- The choice of adequate receptor as well as good transducer for various analytes.
- The insufficient development of immobilization technologies on the sensors areas
(biosensors)
- Instability during the operation of the use of biosensor because of the span time which can
last many hours.
- The existence of analytes interference.
- Incoherent development of the techniques of fabrication, stock, processing, calibration and
with least cost.
5. CRITERIA FOR SELECTION OF AN INTEGRATED BIOSENSOR
a. Benefits of integration
The integration provides many advantages [6]:
- Miniaturisation.
- Reduction of energy consumption.
- Reduced costs due to the possibility of mass production.
- Improved reliability by reducing the number of connections.
- Best immunity to noises.
b. Applications of the selection criteria of integrated sensor
In addition to the basic characteristics of a biosensor which are selection criteria, we have
other criteria such as: compatibility with the integrated electronic circuits (IC’s), the low cost
and the dimensions. But we will focus on drawbacks as criteria summary of choice and the
degree of integrability which gave us the following table (Table 01):
c. Example of an integrated sensor “the Lab.on.Chip”
First, let’s start by defining the bio chip. It is a matrix of individual biosensors that can be
controlled individually and often used for the analysis of multiple analytes.
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Table 1– Obstacles that hinder the application of integrated biosensors
Biosensor
Major inconvenienes [7] Degree of integrability
Type
Calorimetric - Scope to use relatively small for the Low
enzymes.
Optic -The ambient light often causes - Low for the usual type optical
strong interferences. biosensor SPR (Surface Plasmon
- The cost of optical fiber is Resonance).
expensive. - Good for the Mach Zender
- Phase indicators need to be interferometer voice but remains in
removed after a while. development.
Acoustic (type -Problem of integration (requires Low
SAW) several modules instead of one)
- Difficulties in using low frequency.
- Instability if the temperature varies.
Electrochimical -reproducibility: problems for some Very good especially for
electronic techniques. microelectronic techniques (Isfet’s,
- Average sensitivity often Nernstian TFT, etc.)
especially for the PH type.
Mass (piezo) - Instability if the temperature varies. Low
- Low sensitivity in liquid medium
due to the problems of low viscosity.
This matrix is integrated into a single box.
The Laboratory - on-chip (Figure 05) or "Lab .On. Chip" is a mega bio-chip that integrates
more than the biosensors the complement modules such as bioamplifiers etc. It is a
multidisciplinary approach we select and it allows us to minimize energy consumption and
increase the speed of biochemical reactions. In fact it includes all the benefits of integrated
circuits such as the possibility of increased automation and robotics.
Fig.4– Circuit board of Lab-on-a-chip [8] [9]
The Lab.On.Chip is used for the study of : ADN, proteins and peptides, cells, antibodies and
antigens.
It exists in two (02) forms:
- CMOS Imaging (optoelectronic technique).
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- Charge Based Capacitive Measurement CBCM (capacitive measure).
Le CMOS imaging is more accurate than the CBCM but it has more complex design and
more uses than the second.
Fig. 5– Example of a Lab-On- Chip constitution - type CBCM [10]
The circuit shown in FIG (05) illustrates the operating principle of CBCM, the capacity can
be found using the following equation:
ሺܫௌ − ܫோ ሻ = ݂. ܸ . ∆ܥ …(1)
IS and IR are the quantities to be measured.
The Lab. On. Chip is a recently and growing technology which is in full expansion because it
has more features in this integrated device and thus is a quite promising technique.
6. Complement study: effect of temperature and its impact on the biosensors
As biosensors treat physiological signals and therefore biological one, we must consider the
thermal properties of biological substances. This is another condition in addition to the study
of integration.
The specificity of heat in the biological field manifests itself in these two parameters:
- Thermal conductivity: biological substances can have a large temperature change in its
two forms: hypothermia and hyperthermia (cases of a disease for example). We will have a
transport of heat energy which is called 'thermal conductivity'. It directly affects the thermal
resistance of the material (see figure6).
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Fig. 6– Simulated diagram between thermal resistance (RTH) and the conductivity (K)
The figure n°6 represents this model [11]:
1 ܾ ܽ+2ߙ݊ܽݐ.ܮ
ܴݐℎ = ݈݊ ቂ .ቀ ቁ ቃ …(2)
2.ܭሺܾ−ܽሻ ܽ ܾ+2ߙ݊ܽݐ.ܮ
ܵ = ܾ. ܽ ݐ݅ݓℎ ܾ > ܽ
If a=b, then:
ܮ
ܴݐℎ = …(3)
ܽ.ܭሺܽ+2ߙ݊ܽݐ.ܮሻ
The data 1 explains the first situation (when b›a) and the data 2 says the second (b=a).
- Thermal expansion: the Thermal warming of a biological substance often causes an
increase in the volume called thermal expansion.
These two parameters change more rapidly in solid materials, hence the need for additional
thermal study - in addition to the classic study of heat transfer: convection, conduction and
radiation- in the design of bio chips and their boxes of heat dissipation.
7. CONCLUSION
In this study, we wanted to address a general way the problem of true integration. We
have several levels of integration, we can add for example a system of temperature
compensation to the biosensor and say that we have an integrated biosensor but it is only a
slight integration.
From the table n°1 we can ascertain the benefits of microelectronic techniques and deduct
that they are the most integrable, thus explains the importance of the Lab.On.Chip.
In effect, the researches continue in the integration of sensors in general, but for the
biosensors specially. The essential difficulty still resides on the necessity to have a coherent
development in several disciplines (biology, chemical, electronics, software, etc.). So it’s a
continuing multidisciplinary research which is imposed.
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8. REFERENCES
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