27.1
Introduction
When we look back on the history of human diseases, infectious diseases have
accounted for a very large proportion of diseases. It was, however, only in the latter
half of the nineteenth century when microorganisms were discovered to be respon-
sible for a number of infectious diseases that have been plaguing mankind since
ancient times. Thereafter, the first antimicrobial agent salvarsan was formulated by
Ehrlich in 1910 for the cure of syphilis. In 1935, a new class of synthetic drugs called
sulphonamides was developed by Domagk and other researchers to cure bacterial
infections successfully (Yousef et al. 2018). However, these compounds had
limitations in terms of safety and efficacy. In 1928, Sir Alexander Fleming discov-
ered penicillin, an excellent and outstanding antimicrobial agent in terms of safety
and efficacy that lead to the golden period of antimicrobial therapy. It came into
clinical use in the 1940s.
For the next two decades, new types of antimicrobial drugs were developed one
after the other, leading to remarkable advances in the treatment of infectious diseases
and fate of mankind (Saga and Yamaguchi 2009). This gave rise to an overwhelmingly
optimistic view that infectious diseases will be eliminated in the near future, provided
new antibiotics continue to be developed. However, the development of new types of
antibiotics has slowed in the mid-1980s, and very few have been developed in the last
quarter of a century (Shallcross et al. 2015; Silver 2011). At present, fewer new
antimicrobial agents are being introduced in the market. In addition, infections with
drug-resistant organisms remain an important problem in clinical practice that is
difficult to solve. As a consequence of this, isolates are now appearing which are
resistant to almost every antibiotic available, raising the spectre of untreatable infection
even at the world’s most advanced medical centres (Snitkin et al. 2012).
In fact, by the early 1940s, resistance to antimicrobials drugs has been observed
and reported in various studies (Abd-El-Aziz et al. 2017). For instance, in 1941,
Abraham
and
co-workers
(1941)
observed
that
cultures
of
Staphylococci
sp. developed resistance by continuous subculture in the presence of penicillin,
and in 1942, Rammelkamp and Maxon (1942) isolated four strains of penicillin-
resistant Staphylococci sp. during treatment of local infections with penicillin.
Within two decades of penicillin’s introduction, most strains of S. aureus isolated
in large hospitals were resistant to penicillin and to other antibiotics including
streptomycin, tetracycline, and erythromycin.
Widespread scientific consensus has concluded that the human overuse and
mismanagement of antimicrobial agents have contributed to the rapid development
of antimicrobial resistance (AMR) in microorganisms. AMR arises when the
microorganisms which cause infection (e.g. bacteria) survive exposure to a medicine
that would normally kill them or stop their growth. This allows those strains that are
capable of surviving exposure to a particular drug to grow and spread, due to the lack
of competition from other strains. Antibiotics are the preferable treatment for the
cure of chronic bacterial infection. These antibiotics have a potent outcome and also
it is cost-effective, but with time the overuse and misuse of antibiotics create resistant
towards broad spectrum of bacteria. This has led to the emergence of ‘superbugs,’
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