21
Implantable Microelectronics
Mario Birkholz
IHP – Leibniz Institut für innovative Mikroelektronik, Frankfurt (Oder), Germany
CONTENTS
21.1 Introduction......................................................................................................................341
21.2 Sensor and Actuator Designs........................................................................................343
21.3 Biocompatibility...............................................................................................................346
21.4 Intelligence........................................................................................................................347
21.5 Communication................................................................................................................348
21.6 Energy Supply..................................................................................................................348
21.7 System Integration...........................................................................................................349
21.8 Ethical Aspects.................................................................................................................350
21.9 Conclusions and Perspectives.......................................................................................352
Acknowledgments......................................................................................................................352
References ....................................................................................................................................353
21.1 Introduction
A breathtaking development began with the realization of the first integrated circuits
[1–3] around 1960, which has reached a level today allowing the integration of billions of
transistors on one microchip. In the course of this development, not only were enormous
rationalization potentials in industrial processes tapped and an essential basis for the
economic prosperity of many people laid, it also opened up new business fields in in
formation and communications technology, such as those associated today above all with
the Internet [4]. Microelectronic chips are already being used in various human implants,
and it is foreseeable that their use in the human body in the form of sensors and actuators
will become increasingly widespread.
The development of intelligent implants is essentially based on advances in micro
electronics and its continuous miniaturization. The latter is usually referred to as
“Moore’s Law” and goes back to the observation, first published by Gordon Moore, that
the number of components used in integrated circuits doubles every 1½ to 2 years [5]. For
many years, this doubling was possible due to the so-called scaling of CMOS technology
(complementary metal-oxide-semiconductor), as first described in 1974 by Dennard et al.
for the MOS field-effect transistor MOSFET [6]. This observation gave Moore’s law the
character of a self-fulfilling prophecy since Moore had stated in his work that there were
“no comparable limits to the degree of integration as in thermodynamic processes.” It
is true that in the leading semiconductor factories, scaling is no longer reflected in the
DOI: 10.1201/9781003263265-21
341