Introduction to Microbiology Lecture Notes PDF

Summary

These lecture notes provide an introduction to microbiology, covering the classification of microorganisms, including bacteria, fungi, and protozoa. The detailed structure of prokaryotic and eukaryotic cells, along with gram-positive and gram-negative bacteria are also discussed.

Full Transcript

Introduction to microbiology

Lecture 1 of 3
Dr Ashutosh Deshpande
Consultant Microbiologist
 Learning outcomes
– Understand what microbiology means
– Classify microorganisms in very broad terms
– Describe the general structure of bacteria and
the role of Gram stain in helping to classify
certain bacteria
 Microbiology
The study of microorganisms and their
relationship with humans
What is a microorganism?
Any organism/replicating entity that is of
microscopic size (e.g. bacteria) or small
(e.g. certain worms)
 Microorganisms – a simple
classification
Cellular
– Bacteria
– Fungi
– Protozoa/other parasites
Acellular
– Viruses
– Prions
 Classification of cellular
microorganisms
Prokaryotes
– Organisms without membrane-bound nucleus
– Transcription/translation coupled
– Single, circular chromosomal DNA
– Additional DNA carried in plasmids
– Bacteria
 Classification of cellular
microorganisms
Eukaryotes
– DNA carried on chromosomes in a
membrane-bound nucleus
– Transcription and translation are
compartmentalised
– Cytoplasm is rich in membrane-bound
organelles
– Cellular organisms other than bacteria
http://water.me.vccs.edu/courses/env108/lesson2_2.htm
http://www.ebi.ac.uk/microarray/biology_intro.html
 Bacteria
Single-celled prokaryotes with characteristic
cellular organisation
DNA in long circular form +/- plasmids
Cell is often surrounded by complex cell wall
and often a thick capsule
May be motile
Reproduce by binary fission
Wide range of aerobic and anaerobic
metabolic patterns and biochemical variations
 Bacteria
Classified as:
– Gram-positive
– Gram-negative
– Gram-variable
– Gram-stain unreliable
Bacteria that are very small, have an atypical life cycle,
atypical structure, or don’t have a complex cell wall (e.g.
mycoplasma)
For such bacteria, serological, molecular (ie PCR), or
other methods of detection may be used (specialist
microscopy, alternative staining and culture techniques
etc)
http://www.cehs.siu.edu/fix/medmicro/genmicr.htm
http://hugolila.pbworks.com/w/page/4881660/Gram%20Stain
http://pmj.bmj.com/content/77/905/148.full
 Common GPC:
– Staphylococcus aureus
– Streptococcus pneumoniae
Common GPR:
– Listeria monocytogenes
– Corynebacterium diphtheriae
Common GNC:
– Neisseria meningiditis
Common GNR:
– Escherichia coli
– Salmonella species
 Learning outcomes
– Understand what microbiology means
– Classify microorganisms in very broad terms
– Describe the general structure of bacteria and
the role of Gram stain in helping to classify
certain bacteria
Introduction to microbiology

Lecture 2 of 3
Dr Ashutosh Deshpande
Consultant Microbiologist
 Learning outcomes
– Describe sites of the body that are sterile and
those that are colonised with bacteria
– Understand the difference between
colonisation and infection
– State common colonisers and pathogens of
different body systems
– Understand the concept of host, pathogen
and environmental factors that lead to
infection
 Bacteria and the body:
colonisation
Colonisation
– Commensal organisms, mutualism
– Symbiotic and natural living arrangements
between two species which may be beneficial to
one or both parties and does not cause harm
– Normal flora is acquired soon after birth and
changes with age
Benefits
– Competition and natural by-products inhibit
establishment of infection
– Vitamins (K and B) in the gut produces as
metabolic end-products
– Immune stimulation
http://www2.bc.cc.ca.us/bio16/PAL/Lecture%202.htm
 Bacteria and the body
Sterile body sites
– Blood, tissues and organ systems
– CNS
– Lower respiratory tract
– Sinuses, inner and middle ear
– Renal system down to posterior urethra
– Female reproductive tract down to the
cervix
– Eye (exposed conjunctivae colonised)
 Bacteria and the body: infection
Colonisation +/- multiplication of pathogens or organisms that
may cause harm in a vulnerable host, +/- manifestation of
disease
Organisms may produce manifestations of disease by direct
invasion or production of toxins and other virulence factors
Some definitions:
– Parasite
– Opportunistic infection
– Nosocomial infection
– Carrier state
Transient or chronic
 Infection: microbial factors
Virulence factors
– Colonisation factors
– Invasive factors
– Toxigenicity
Other microbial defences
– Antigenic mimicry
– Antigenic masking
– Antigenic shift
– Encapsulation
– Evasion of host immune response
– Induction of inappropriate immune responses
Infectious doses
 Endotoxin
Lipopolysaccharide
in outer membrane
of Gram-negative
bacteria
“Endotoxic lipid A”
and “O antigen”
Elicits strong
immune responses
and can make
patients appear
“septic”
http://en.wikipedia.org/wiki/File:LPS.svg
 Superantigens
Exotoxins liberated by certain
Gram-positive bacteria
– Produced intracellularly
and released as mature
toxins on infection
– Staphylococcus aureus,
Streptococcus pyogenes
Massive immune stimulation
– Non-specific polyclonal T-
cell stimulation
– Toxic shock syndrome

http://en.wikipedia.org/wiki/File:Seb.png
 Infection: host and environmental
factors
Age, gender, ethnicity, personal hygiene, nutrition
Other medical conditions, drugs
Immunocompromise
– Immune deficiency disorders, malignancy,
chemotherapy and other drugs
– Immunocompromising infections e.g. HIV
Presence of foreign objects
– Make infection with commensals more likely
– Biofilms
Vaccination history
Crowding, seasonal variations, sanitation,
socioeconomic and public health factors
 Common infections in different body
System
systems
Example of infection Example of common pathogen

Respiratory Pneumonia Streptococcus pneumoniae
Haemophilus influenza
Sore throat Streptococcus pyogenes
Gastrointestinal Cholecystitis Gut flora
Food Poisoning Campylobacter, Salmonella, certain
strains of E.coli, Shigella
Central nervous system Meningitis Neisseria meningiditis
Streptococcus pneumoniae
Haemophilus influenzae
Bone and joint Osteomyelitis Staphylococcus aureus
Septic arthritis

Skin and soft tissue Cellulitis Staphylococcus aureus
Necrotising fasciitis Streptococcus pyogenes

Renal Pyelonephritis Gram-negatives e.g. Escherichia coli
UTI

Genital Pelvic inflamamtory disease Neisseria gonorrhoea
Urethritis Chlamydia trachomatis

Cardiovascular Endocarditis Streptococci, Staphylococci, various
others

Ophthalmological Periorbital cellulitis Staphylococci, Streptococci
Endophthalmitis Various iatrogenic
Conjuncivitis
Obstetrics/neonates Chorioamnionitis, neonatal sepsis Group B Streptococci, E.coli, Klebsiella
 Natural course of infection
Host, microbial and
environmental factors will
determine the likelihood of
getting infected, severity of
symptoms, and chances of
overcoming the infection
Most healthy individuals will
mount an immune/
inflammatory response to
infection and eventually
clear it
Both the host immune or
inflammatory response, and
the offending pathogen
itself, may contribute to
symptoms and signs

http://www.cardiff.ac.uk/biosi/subsites/cold/commoncold.html
 Natural course of infection: more
definitions
Entrance (portal of entry)
Colonisation (adherence; adhesion; attachment)
Multiplication +/- dissemination (spread)
Penetration +/- invasion (not all pathogens are
invasive)
Signs and symptoms of disease (morbidity, mortality)
based on host immune system and pathogenic
virulence factors etc
Resolution or chronic state may occur
Elimination and/or exit of pathogen (carrier state may
be established)
 Learning outcomes
– Describe sites of the body that are sterile and
those that are colonised with bacteria
– Understand the difference between
colonisation and infection
– State common colonisers and pathogens of
different body systems
– Understand the concept of host, pathogen
and environmental factors that lead to
infection
Introduction to microbiology

Lecture 3 of 3
Dr Ashutosh Deshpande
Consultant Microbiologist
 Learning outcomes
– Understand the importance of pre-antibiotic
sampling and develop an understanding of
the specimen journey
– Understand the meaning of sepsis and the
broad principles of assessment and
management of infection
– Understand what is meant by the “chain of
infection” and the rationale behind standard
and transmission-based infection control
precautions
 Laboratory diagnosis of infection
Pre-antibiotic samples are important
Samples need to get to the lab on time in the correct
containers and media
Samples must be labelled correctly, and must have
plenty of accurate clinical details on them
In emergencies, do not wait for lab results – check
previous microbiology results, check the empirical
prescribing policy, check for any antibiotic allergies,
discuss with a senior, and start treatment
Always review empirical antibiotic choices and tailor
these to the organisms grown when appropriate
 The specimen journey
Depending on the clinical details and type
of sample, the sample is processed in an
appropriate area of the lab
 Specimen processing
Processing may involve anything from
microscopy, culture, sensitivity testing or PCR to
serology or referral of the sample to reference
laboratory services for techniques such as whole
genome sequencing
Samples that are heavily contaminated with
commensal flora, such as stool samples, require
decontamination steps and selective and
differential culture media
Microscopy, culture and
sensitivities

24 hours

24 hours
24 hours

24 hours

1-2 hours
 Microbiological emergencies
Acutely threatening to organ-system or life
Must be assessed and treated empirically
immediately
– Infection of a normally sterile site
– Meningitis/CNS infection/cerebral abscess
– Septic arthritis
– Deep ocular or periorbital infections
– Infection involving breach of the GI tract e.g.
peritonitis
– Any outbreak scenario or public health risk
– Any infection in which a patient is “septic”
– Don’t forget agents other than bacteria
 Sepsis
Physiological response to severe infection involving
cytokine cascades, free radical production and
vasoactive mediators
Many older textbooks describe the old SEPSIS scoring
system below. The principles are similar, but this has
now been superceded by different scoring systems to
measure degree of illness of patient
SIRS
– 2 or more of: T outwith 36-38 C, HR > 90, RR > 20 or PaCo2 <
4.3 kPa, WCC outwith 4-12, or > 10% immature band forms
Sepsis
– SIRS in presence of infection
Severe sepsis
– Sepsis with evidence of organ damage or hypoperfusion e.g.
hypoxaemia, oliguria, acidosis, cerebral dysfunction
Septic shock
– Severe sepsis with hypotension despite fluid resuscitation or
vasopressor/inotropic support
 Severity Scores
SIRS/Sepsis/MEWs/NEWs/SOFA or other similar
scores commonly used in most settings
Maternal and paediatric settings may have more
bespoke guidelines
Help objectively assess how critically unwell a patient
– early aggressive management can save lives
Familiarise yourself with the system used in your local
hospital/health board
Other organ system-specific scores in common use
– Clostridium difficile severity score
– CURB 65 score
Kumar, A. Early Antimicrobial Therapy in Severe Sepsis and Septic
Shock. Curr Infect Dis Rep 12, 336–344 (2010).
https://doi.org/10.1007/s11908-010-0128-x
 Sepsis “bundles”
SEPSIS 6 and other “bundles” are used to
help guide early identification and
management of septic patients ASAP,
ideally within the first hour of assessment
 Principles of treatment
Management Examples

Investigate Imaging, cultures etc – helps guide later
managment

Conservative Rehydration, nutrition,
inotrope/vasopressor support, oxygen,
support affected organ systems, drugs

Antibiotics “Golden hour” of antibiotics
NB contraindicated in E.coli 0157

Surgical Fulminant colitis (C. difficile), peritonitis ,
collections, abscess etc.

Infection control Single room or cohort isolation, enteric
precautions, respiratory precautions,
hand hygiene
Public health Outbreak surveillance, exclusions,
microbiological clearance
 Infection control precautions
Universal precautions
– Apply to all patients
– Care with body fluids, broken skin and mucous
membranes
– Handwashing, PPE, environmental cleaning, injury
prevention
Transmission-based precautions
– May involve some sort of isolation and special PPE
– Airborne Precautions
– Droplet precautions
– Contact precautions
– Other special precautions e.g. enteric, prions etc.
http://instructor.mstc.edu/instructor/csebasti/543102_NursingSKills.html
 Learning outcomes
– Understand the importance of pre-antibiotic
sampling and develop an understanding of
the specimen journey
– Understand the meaning of sepsis and the
broad principles of assessment and
management of infection
– Understand what is meant by the “chain of
infection” and the rationale behind standard
and transmission-based infection control
precautions