Microbial Antibiotic Resistance - Micro 462 Lecture Notes PDF

Summary

These lecture notes cover microbial antibiotic resistance, discussing the various aspects related to the topic from different perspectives like antibiotics, bacteria, pathogen, and their effect on human health. The notes provide a comprehensive overview and are helpful for the students who are undergoing medical or microbiology courses.

Full Transcript

Microbial antibiotic resistance - Micro 462

Prepared by
Dr/ Essam KOTB
Associate Professor of
Microbiology, IAU University
[email protected]
+2/01121343400
+966/0563533550

1
 Course specification

2
 Reference books
– Carlos F. Amábile-Cuevas (2016) Antibiotics and
Antibiotic Resistance in the Environment. CRC
Press, Taylor & Francis Group, London, UK
– Anthony R.M. Coates (2012) Antibiotic Resistance.
Springer Heidelberg New York
– Antibiotic Resistance, 2010, Institute of Medicine
Forum on Microbial Threat. 978-0-309-15611,
National Academic Press, Washington.
– Antimicrobial Resistance in the Environment,
Patricia L Keen and Mark HMM Montforts. ISBN:
978-0-470-90542-5
Schedule of assessments during the semester
Assessm
ent Percentage of
timing Total
No Assessment Activities *
Assessment
(in week Score
no)

1 Quiz 1 4 10%

2 Midterm 8 20%

3 Quiz 2 13 10%

Team projects and 10-14 20%
4
presentations/H.W

5 Final Exam 15 40%
 Course objectives
After completing this course, you will be able to:
1. Understand what antibiotics are and how they
work.
2. Understand how bacteria become resistant to
antibiotics.
3. Appreciate the issues surrounding antibiotic
resistance.
4. Know the challenges in developing new
antibiotics.
5. Know about alternative approaches to tackle
infectious diseases.
Lesson 1: General overview of the history of
infectious diseases and antibiotics

Prepared by
Dr/ Essam KOTB
Associate Professor of
Applied Microbiology, IAU
[email protected]
+2/01121343400
+966/0563533550
 Objectives
By the end of this lesson, you should be able to:
1. Define the term antibiotic and give examples.
2. Describe the importance of antibiotics in health
care.
3. Analyse antibiotic data and make simple
deductions about antibiotic use and resistance
patterns.
4. Discuss the consequences of a future without
antibiotics.
5. Build up your own opinion about this dilemma.
Infectious diseases and antibiotics
Most infectious diseases are caused by bacteria
because they are the most numerous organisms and
living in all habitats.
The secret of their success in all habitats is their
simplicity which allow them to adapt quickly to
changes in their surroundings thus reproduce quickly
and efficiently.
Each adaptive characteristic passes rapidly to the next
generation and a new strain evolves.
 It should be emphasized that, most bacteria found in or
on the human body are harmless M.Os called
commensals (microbiota) living on the body without
having any detrimental effect.
However, a tiny proportion (about 500 species) are
pathogenic – capable of causing diseases.
– These pathogenic bacteria evade the body’s normal
defenses to colonize body tissues or produce
harmful toxins.
Some bacteria are opportunistic pathogens – these
don’t harm the normal hosts as they are not real
pathogens but attack weak hosts due to weak immune
system.
 Until the mid-twentieth century, bacterial infections
were difficult to treat and were a leading cause of
mortality worldwide.
In the 1940s, the antibiotics were introduced, and the
outcomes of bacterial infections were improved
dramatically.
Antibiotics are organic chemical compounds which kill
or inhibit bacteria.
– Antibiotics which kill bacteria are called
bactericidal antibiotics.
– Antibiotics which inhibit bacterial growth are called
bacteriostatic antibiotics.
 They are produced naturally by M.Os especially those
living in soil in order to stop bacteria competing for
shelter, nutrients and other resources.
Antibiotics specifically target bacteria – a
characteristic that humans have exploited for their
own advantage to avoid the side effects produced by
traditional medications.
Narrow-spectrum antibiotics - only affect a few
bacterial types.
Broad-spectrum antibiotics - affect a wider range of
bacteria.
 Most antibiotics are specifically effective against
bacteria during the exponential phase of growth; why?
Because during the exponential phase the bacterial
cells are at their most activity, continually growing,
dividing and forming new cells.
The metabolic processes which underpin this period
of growth such as the synthesis of DNA, RNA,
proteins and cell wall are good targets for the
antibiotics to disrupt it therefore kill or inhibit cells.
For this, the bacterial spores are resistant to
antibiotics because the metabolic processes are
nearly dormant.
 Classification of antibiotics (BG AMTO FRT)
There are numerous antibiotics, some of which are naturally
occurring while others are semi- or fully synthetic.
Antibiotics are usually classified according to the chemical
structure because structurally similar antibiotics have the
same antibacterial activity (see below).
Antibiotic class Example Cellular process Effect on
targeted bacteria*
ß-Lactams ampicillin bacterial cell wall Bactericidal
(penicillins) synthesis
ß-Lactams cephazolin bacterial cell wall Bactericidal
(cephalosporins synthesis
)
ß-Lactams imipenem bacterial cell wall Bactericidal
(carbapenems)
* Common synthesis
effect but depends on the concentration at which the antibiotic is used.
Antibiotic class Example Cellular process Effect on
targeted bacteria*
Aminoglycosides streptomycin Protein synthesis Bactericidal
Macrolides azithromycin Protein synthesis Bacteriostatic
Tetracyclines tetracycline Protein synthesis Bacteriostatic
Oxazolidinones linezolid Protein synthesis Bacteriostatic

Fluoroquinolone ciprofloxacin DNA synthesis Bactericidal
s
Rifamycins rifampicin RNA synthesis Bactericidal

Not applicable Trimethopri Antimetabolite (e.g Bactericidal
m folic acid)
The pre-antibiotic era
Before the discovery of antibiotics, the treatment options
for bacterial infections were limited (video 3).
People were not only vulnerable to potentially deadly
infections like TB (tuberculosis) and meningitis, but
also simple wound infections by bacteria led to sepsis
and death in many cases.
Common infections such as sore throats, which
considered ‘non-serious’ today, were killers in the pre-
antibiotic era.
Routine procedures such as childbirth were also deadly.
 Treatment during that era includes:
1. Herbal remedies.
2. Pastes from insects.
3. Chemicals such as mercury for syphilis.
4. Bloodletting.
5. Draining of pus from wounds.
6. Fresh air used for TB.
Those approaches relieved the symptoms and did little
against the underlying cause therefore, the outcomes
were largely ineffective.
 For example, George Washington the funding of USA
suffered a sore throat and died from such simple
infection.
The Black Death of the 14th century killed a quarter of
Europe. The plague bacterium causes your flesh dies
and rots while you're still alive.
Thence there's tuberculosis, a slow and deadly killer, the
cause of lung abscesses.
Gangrene and tetanus caused by soil bacteria residing in
every dirty bullet, scalpel, wood and glass pieces.
The old physicians would laugh in your face if you told
them that microscopic life is killing people. They were
still clung to theories passed down from the ancient
Greek who claimed that, the cause of diseases were
devils' or fairies' punishments, and that healing was a
gift from God.
 Now we know that infectious diseases are caused by
microorganisms.
This discovery, was known as the germ theory of
diseases, which was a pivotal moment in medicine.
This theory was established and proved by Louis
Pasteur and Robert Koch (back to micro307 course).
 By the early twentieth century, efforts to tackle infectious
diseases were focused on finding drugs that can kill the
bacterial pathogen without harming the patient – so-called
‘magic bullets’.
Salvarsan and Sulfonamides were the first magic bullets of
chemical origin.
Alexander Fleming’s chance discovery in 1928 of the first
natural antibiotic – penicillin – paved the way for research
into other ‘magic bullets’ to cure bacterial infections. This
was the start of the antibiotic era.
Since their introduction in the 1940s, antibiotics have
saved millions of lives (Figure 3).
Thence deadly diseases such as pneumonia, and TB were
treatable, in addition, everyday infections and minor
injuries become no longer life-threatening.
 (a) Childbirth- (b) All infectious
related infection diseases.
(puerperal fever)

Figure 3 Effect of antibiotics on death rates in UK between 1931 and 1957
from (a) childbirth-related infection (puerperal fever) and (b) all infectious
diseases. The arrows indicate when specific antibiotics were introduced.
 For this, antibiotics were extensively used in medicine for:
1. Treatment of patients and improvement of the
survival rates during childbirths and surgical
operations.
2. Prophylaxis - that is they are taken before routine
surgical procedures to prevent infection by internal
sterilization.
Unfortunately, recently antibiotics are no longer looked as
the ‘magic bullets’, why??
3. Because of our over-reliance (over-use) on them to
prevent and treat human infections.
4. Their use in nonmedical purposes (mis-use), such as
in veterinary medicine, agriculture, canning, food
preservation which has led to lose most of their power
and resistance against them has appeared.
 Antibiotic resistance can be natural resistance. However,
the overuse and misuse of antibiotics exerts a selective
pressure on bacteria to adapt and survive thus, acquired
resistance appeared.
There is a coincidence between the antibiotic use and the
rise of antibiotic resistance.
For example, between 2000 and 2010, total global
antibiotic consumption increased by over 30%, also
antibiotic resistance increased dramatically.
By analysing country-specific data for the period 2000 to
2010, we can build up a picture of antibiotic use and
resistance worldwide.
Figure 4 Percentage change in antibiotic consumption per capita 2000–2010.
Percentage decrease is indicated in blue while percentage increase is
indicated in red. Lower percentage changes are indicated by lighter colours.
Superbugs
There is a constant race between antibiotics and bacteria. A
superbug is a bacterium that got resistance to ignore the impact
of multiple antibiotics (Video 4, Article 2 Bacteria that resist
‘last antibiotic’ found in UK).
What is the warning?
– All bacteria become superbugs resisting all antibiotics.
How big could the impact be?
– At the moment, some antibiotics still used to treat
infections.
– In the near future, we will have infections that can no longer
be treated. In addition, things like surgery may be fatal to do
because bacterial contamination will not be resolved.
For this, in 2017, WHO published a list of 5 superbugs for
which alternative treatments are urgently required (K.
Pneumoniae, E. coli, Staph. aureus, N. gonorrhoeae, Str.
Bacterium Antibiotic resistance Priority
rating

K. pneumoniae Multi-drug
Critical
E. coli Multi-drug
Staph. aureus Methicillin,
Vancomycin
High
N. gonorrhoeae Cephalosporins,
Fluoroquinolones

Str. pneumoniae Penicillins Medium
Case study (The link between antibiotic use and antibiotic
resistance e.g Cephalosporins).
Study figure 4a and b which compare cephalosporin use
from 2000 to 2015 in the UK and South Africa then answer
the following questions.

Figure 4a
Figure 4b
Activity 1: Try to answer the following questions from charts.
How did cephalosporin use change over time in each country?

Which country had the lowest consumption in 2015?

What reason accounts for the decrease in cephalosporin consumption
in the UK since 2007?

Which country is more vulnerable to develop resistant bacteria to
cephalosporin?
 Activity 2: Try to answer those questions from charts.
Now study figure 4c and d which compare cephalosporin
resistance among K. pneumoniae and E. coli clinical
isolates in the UK and South Africa then answer the
following question.

Figure 4c
What was the resistance pattern for each organism in each
country?

Figure 4d
 Next lesson you will find out:
1. How different antibiotics work and how they target
bacteria in the body leaving the body cells unharmed.
2. Why some antibiotics are active against a wide range
of bacteria, but others are not.

Thanks for
your
attention
Questions?