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Nosocomial Infections
Patrick Kimmitt
Today we are going to cover…
• The factors that contribute to nosocomial infections
• Examples of nosocomial infections and the organisms which cause them
• Control of nosocomial infections
• Surveillance of nosocomial infections
Nosocomial infections
• The word derives from the Greek nosokomeian, meaning hospital
• These days the terms hospital acquired – and healthcare associated – are used
• A very emotive subject with the public, driven by the press
• Do hospitals really deserve to be blamed for all cases of hospital infection?
Nosocomial infections are…
• Infections that are acquired in hospital (48 hours or more after admission)
• Approx 7% of patients will suffer from an infection whilst in hospital – the risk increases with length of stay
• A significant financial burden on NHS
Impact of nosocomial infections
• Possibly up to100,000 infections per year in UK
• A cause of ~5,000 deaths with nosocomial infections playing a role in ~15,000 others
• Costs the NHS £1 billion – 9% of its in-patient budget
• Cannot be eradicated but it’s thought they could be reduced by up to 30%
Impact of nosocomial infections
• Longer stays in hospital – bed occupancy
• Outbreaks leading to ward closures especially norovirus and C. difficile
• Pain and anxiety for patients and families
• Loss of earnings
Where is the money spent?
Best to be proactive rather than reactive!!
Why are we more likely to get an infection in hospital?
Consider 4 important factors…
1. The host
2. The microbes
3. The environment
4. Treatment
The host 1
• People in hospital are already sick!
• They may have poor general resistance to infection
• Lack of immunity– Extremes of age– Immunocompromised (eg cancer
chemotherapy)
The host 2
• Reduced immunity– Diabetes, severe burns
• Poor local resistance– Poor blood supply to tissues
• Surgery– Wounds, sutures
• Medical devices– Catheters, prostheses, tubing etc
The microbes
• Virtually any infection can be acquired in hospital
• However a number of “usual suspects” predominate
• What are they, where do they come from and why do they cause nosocomial infection?
Opportunistic infections
• Nosocomial infections are often caused by opportunistic pathogens i.e. those which do not normally cause infection in healthy people
• May be a reflection of reduced defences of host or access to sites not normally colonised by organisms
• May be from normal flora or environment• Antibiotic resistance is a problem
Opportunistic pathogens
• Pseudomonas aeruginosa
• staphylococci
• E. coli and other coliforms
• streptococci and enterococci
• Bacteroides fragilis
• Candida albicans
• Herpes simplex virus
• Cytomegalovirus
Biofilms
• Biofilms are microbial communities (cities) living attached to a solid support eg catheters/ other medical devices
• Biofilms are involved in up to 60% of nosocomial infections
• Antibiotics are less effective at killing bacteria when part of a biofilm
The Environment
• There are many different sources of pathogens when in hospital– Our own normal flora (endogenous infection)– Infected patients– Movement of staff and visitors– Environment e.g. fungi, Legionella– Blood products (v. rare)– Surgical instruments eg vCJD (v. rare)
ENVIRONMENTAL SOURCES OF PATHOGENS IN THE HEALTHCARE SETTING
Source Bacteria Viruses Fungi
Air Gram-positive cocci (originating from skin)Tuberculosis
Varicella zoster (chickenpox),Influenza
Aspergillus
Water (tap and bath)
Gram-negative bacteria (Pseudomonas aeruginosa, Aeromonas hydrophilia, Burkholderia cepacia, Stenotrophomonas maltophilia, Serratia marcescens, Flavobacterium meningosepticum, Acinetobacter calcoaceticus, and Legionella pneumophila) Mycobacteria (Mycobacterium xenopi, Mycobacterium chelonae, or Mycobacterium avium-intracellularae)
Molluscum contagiosum Human papillomavirus (bath water)Noroviruses
AspergillusExophiala jeanselmei
Food Salmonella species, Staphylococcus aureus,Clostridium perfringens,Clostridium botulinum, Bacilluscereus and other aerobic spore-forming bacilli Escherichia coli Campylobacter jejuni ,Yersinia enterocolitica, Vibrio parahaemolyticus, Vibrio cholerae, Aeromonas hydrophilia, Streptococcus species Listeria monocytogenes
Rotavirus Caliciviruses
Treatment
• There is continuous usage of antibiotics in hospitals especially in ICU
• As a result there will be a natural selection for strains that are antibiotic resistant – infections are getting harder to treat
• This has led to problems with multi-resistant bacteria e.g. MRSA, VRE, ESBLs
• Antibiotic treatment can also lead to alterations in normal flora and allow pathogens cause infection eg C. difficile
Sites of HAIs
Bloodstream nosocomial infections
– Coagulase-negative staphylococci– Enterococci– Fungi e.g Candida albicans– Staphylococcus aureus– E. coli and other coliforms– Pseudomonas aeruginosa – Acinetobacter baumannii with substantial
antimicrobial resistance - Reported with increasing frequency
Urinary Tract Infections
– E. coli and other coliforms– Candida albicans – Enterococcus– Staphylococcus– Pseudomonas
Surgical site infections
• S. aureus
• Pseudomonas aeruginosa
• Coagulase-negative staphylococci
• Enterococcus
• Candida albicans
• E. coli
Causes of death
1. Primary bloodstream infection
2. Pneumonia
3. Infection of surgical site
Staphylococcus aureus
• A common coloniser of the skin and mucosa (e.g. the nose) it is a classic opportunist
• Causes skin and wound infections as well as septicaemia, urinary tract infections and pneumonia
• Most strains are sensitive to many antibiotics…some are not…
MRSA
• Methicillin (Meticillin) Resistant Staphylococcus aureus
• S aureus carried by 30% of us (nose/ skin)• MRSA is more difficult to treat compared to
MSSA• Resistance due to mecA gene – encodes
PBP2a, doesn’t react with Penicillins• Emerging Vancomycin resistance is a concern• The Biomedical Scientist Jan 2008 p39-41
MRSA bacteraemia
Epidemic MRSA (EMRSA)• Epidemic strains have acquired a selective
advantage for transmission in hospital environments
• EMRSA-1 was identified in S.E. England in 1984.
• Subsequent surveys showed further 13 multi-hospital MRSA (EMRSA-2 to -14)
• Mid-1990s: EMRSA-15 and -16 emerged and spread rapdily
• Approx 60% of MRSA isolates in hospitals are EMRSA-15, and 35% EMRSA-16
Rapid MRSA screening
• Current methods for screening for MRSA are based on culture and take 48 hours
• PCR-based screening can generate a result in 2 hours!
• mecA is carried on a transferable gene cassette called SCCmec – but also found in coagulase-negative staphylococci
• PCR developed using primers for SCCmec and orfX on the S. aureus chromosome
Use of SCCmec/orfX PCRPCR product
mecA SCC 3` end orfX
No PCR product
orfX
No PCR product
mecA SCC 3` end
MRSA
MSSA
MR CN-Staph
Cuny & Witte Clin Microbiol Infect (2005) 11:834-837
Vancomycin Resistant Enterococci
Extended spectrum β-Lactamases
• ESBLs are enzymes responsible for resistance to 3rd generation Cephalosporin antibiotics such as Ceftazidime and Cefotaxime
• Resistance is found in E. coli and other members of the Enterobacteriacae
• Often cross-resistance with other antibiotics making treatment difficult – use carbapenems
Clostridium difficile
• Causes antibiotic-associated diarrhoea and pseudomembranous colitis – life-threatening illnesses
• Normally affects only the elderly, especially those on long-term broad-spectrum antibiotics
• Produces two powerful toxins and is a spore-former– difficult to eradicate, resistant to alcohol
• Reasons for the rapid increase in cases is still not known
Clostridium difficile
• Nosocomial disease spread primarily by hands of staff and “outbreaks” are common
• Patients generally respond to discontinuation of the inciting agent or therapy with metronidazole or vancomycin. Response is rapid but Mtz and Vanc may also alter normal flora and may allow disease to recur
• Once the colon is injured it is more susceptible to re-infection. “Relapse” rates are up to approx 20%
• Almost impossible, at present, to rid the environment of C. difficile spores
• Some use 1000-10000ppm hypochlorite – highly caustic and damaging to surfaces. There may be rapid re-contamination of environment.
Nosocomial transmission of C. difficile
• Contamination rates after contact with CDAD patients:
• Physicians & medical Students 75% of the time• Dialysis Technicians 66% of the time• Nurses 56% of the time• Physiotherapists 50% of the time
• Underside of fingernails 43% • Fingertips and Palms 37%• Underside of Rings 20%
• C difficile spores remain in environment in 34-58% of sites after “detergent” cleaning
• CDC 2005
Success story
• Scunthorpe and Goole NHS trust looked at changing their antibiotic prescribing policy to reduce the incidence of C. difficile disease
• Cost £12,000 extra to implement
• Saved £280,000 in staffing, bed occupancy, treatment, use of isolation rooms and of course lives
Infection Control
• Infections may derive from endogenous (auto-infection) or exogenous sources (cross-infection)
• We need to consider the chain of infection and the transmission of an infectious agent
Transmission
1. Contact – most common• Direct (physical contact)• Indirect (via contaminated objects)
2. Airborne Transmission• Droplet respiratory secretions on surfaces• Inhalation of infectious particles
3. Blood-borne transmission (v. rare)
4. Food-borne (rare)
The Cycle of Contagion
Susceptible person
Infection or colonisation
Transmission
Pathogen
Infection control hygiene
The Cycle of Contagion
Susceptible person
Infection or colonisation
Transmission
Pathogen
X
XX
X
Immunisation or prophylaxis
Individual treatmentImmunisation or prophylaxis
Role of infection control teams
• Education and training
• Development and dissemination of infection control policy
• Monitoring and audit of hygiene
• Clinical audit
Isolation & barrier precautions
Decontamination of equipment
Prudent use of antibiotics
Hand washing
Decontamination of environment
The 5 pillars of infection control
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Cleanyourhands campaign
• An initiative that was rolled out in 2004
• Increased procurement of alcohol rub in wards
• Poster campaign• Evaluation of this
published in BMJ May 3 2012
Tabloid sensationalism?
Government response…
Hospital superbug must be halved
Bloodstream infections with the hospital superbug MRSA must be halved in three years, the government has said.
Health Secretary John Reid tasked NHS hospitals with achieving a year on year reduction up to and beyond March 2008.
Government meddling??
• By forcing targets on NHS trusts for reduction of MRSA numbers, has this led to an increase in infections with other “superbugs”?
• Hand washing with alcohol-based antiseptics is fine for decontamination of MRSA but have no effect on spores of C. difficile - need to wash with soap and water
• Include soap as well as alcohol rub on wards
Some progress
• In recent years there has been a steady decline in cases and deaths caused by both MRSA and C. difficle
• Is our infection control policy paying off?
Resistant Gram negative bacteria
• The emphasis is switching to multi-resistant Gram negative pathogens e.g.
• CTX-M ESBL producers, seen in E. coli and other Enterobacteriacae providing resistance to 3rd generation cephalosporins
• CRE – Carbapenem Resistant Enterobacteriacae e.g. NDM-1 - very few treatment options here (colistin)
Surveillance
• Continuous monitoring of the frequency and distribution of infectious diseases
• Determines the most important causes of infectious diseases and identifies at risk groups
Uses of surveillance
• Used to identify new “problems”
• Used to identify where resources are most needed
• Used to determine the burden of disease
• Used for strategic planning and policies
• Use surveillance for measuring outcomes of intervention strategies
Epidemiology
• Surveillance is also used to detect epidemics and outbreaks
• Epidemiologists at Centre for Infections analyse data sent from laboratories throughout the country
• Surveillance reports published in CDR weekly http://www.hpa.org.uk/cdr/index.html
• But how do Biomedical Scientists help with this work?• Isolating and identifying the pathogens - hospitals• Typing – specialist laboratories
Typing of pathogens
• There are many different strains of a bacterial/ fungal/ viral species so in order to identify a possible outbreak and identify the source we need to discriminate between organisms of the same species
• This is called typing: there are a number of methods available– Those based on phenotype (traditional)– Those based on genotype (recent)
Typing methods
• Typing is usually performed at specialised Reference Laboratories such as those at HPA Centre for Infections
• Different methods are used for different pathogens – use the one which gives best discrimination
• Pathogens of the same type may be part of an outbreak, if they are of a different type an outbreak can be ruled out
Phage Typing
• Phage (bacteriophage) is a virus that infects and kills bacteria
• Different strains are susceptible to different phages
• Gives a fingerprint that can discriminate between strains
• Used in the typing of S. aureus and Salmonella
Serotyping
• Used to detect variations in certain antigens present on the pathogen
• Use specific antisera and observe a Antibody-Antigen reaction (usually a precipitation or agglutination reaction)
• Eg Streptococcus pyogenes M-protein typing – M1 type is important in invasive infections (flesh eating etc)
• H and N typing of influenza eg H5N1, H1N1 etc
Biotyping
• Biotyping explores the metabolism of an organism eg a particular enzyme activity or ability to ferment a particular sugar
• Eg. coagulase-negative staphylococci
Genotyping
• There are a number of methods available – most rely on sequence variation in non-coding (intergenic) DNA
• This variation is characteristic of a particular strain (or type)
• Strains from an outbreak will be the same type
• Similar to DNA fingerprinting used in CSI and paternity disputes
Restriction Fragment Length Polymorphism (RFLP)
• DNA extracted from bacterial isolates is digested (cut) with a restriction enzyme eg EcoR I
• Produces DNA fragments of varying size – gel electrophoresis
• Pattern of bands is strain-specific
Pulsed Field Gel Electrophoresis
• Used to separate large DNA fragments >10 kb
• Chromosomal DNA digested with restriction enzyme and fragments separated by PFGE
• Banding pattern is strain specific – used e.g in MRSA typing
Repetitive DNA
• Much of the bacterial genome consists of short repeating DNA sequences – micro or minisatellites
• By comparing the number of repeats present at specific loci the relationship between strains can be investigated
• Often known as VNTR typing
Summary 1
1. Can you explain in detail why patients in hospital are more prone to infection?
2. Can you define a primary and an opportunistic pathogen?
3. Can you give examples of nosocomial infections, with predisposing factors and examples of the pathogens which cause them?
4. Can you discuss infections due to MRSA and C. difficile in detail?
Summary 2
5. Can you discuss the transmission of infection in hospitals, uses of infection control and the role of infection control teams?
6. Why is surveillance of nosocomial infections important?
7. What is the role of the laboratory in the diagnosis and surveillance of nosocomial infections?
8. Can you give examples of the methods used in the laboratory for diagnosis and surveillance of nosocomial infections?
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