Kategorien: Alle - detection - pathogens - persistence - monitoring

von Dalea Anuar Vor 4 Jahren

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7.0 MICROBIAL ASPECTS

Global changes, human development, and climate change are significantly influencing the risk of waterborne diseases. Zoonotic pathogens, which constitute a majority of emerging pathogens, present a substantial challenge for ensuring the safety of drinking and ambient water.

7.0 MICROBIAL ASPECTS

7.0 MICROBIAL ASPECTS

EMERGING ISSUES

zoonatic pathogen pose the greatest challenge to ensure the safety of drinking water and ambient water
zoonatic pathogen make up 75% of the emerging pathogens.
global changes, human development, population growth and climate change influence water disease risk

PUBLIC HEALTH ASPECTS

effects and exposure to pathogens are not the same for all individuals . Not all infected individuals will develop symptomatic infections.
waterborne pathogen that contaminated through drinking water can lead to severe and life threatening. Eg: cholera, hepatitis, thyphoid.
developing and applying control on drinking water quality should be control such a outbreaks.

TABLE TO REFER

Table 7.2 (pg 121)
Microorganisms for which transmission through drinking water has been proposed but evidence is lacking
Table 7.1 (pg 119)
Characteristics, behavior, resistance of pathogens

TREATMENT OF PATHOGEN

HOUSEHOLD TREATMENT
Combination (multiple-barrier) treatment approaches

Flocculation plus disinfection systems

e.g. commercial powder sachets or tablets

Coagulation, precipitation and / or sedimentation

Simple sedimentation

Thermal (heat) technologies

Boiling

UV light technologies using lamps

UV irradiation

Solar disinfection

Solar UV radiation + thermal effects

Granular media filter

Household-level intermittently operated slow sand fi ltration

Rapid granular, diatomaceous earth, biomass and fossil fuel - based filter

Membrane, porous ceramic or composite filters

Fiber and fabric filtration

Membrane filtration

Reverse osmosis

Ultrafiltration

Nanofiltration

Microfiltration

Porous ceramic and carbon block filtration

Chemical disinfection

Free chlorine disinfection

CENTRAL TREATMENT
There are positive and negative interactions occur between multiple steps and these can affect the overall of water quality.
The case that efficacy for microbial reduction differ among the microbial groups so different treatment process are needed.
For example : poor quality surface water require multiple treatments stages.

disinfection

filtration

sendimentation

flocculation

coagulation

Water treatment required to remove or destroy pathogenic microorganism
Validation is important in ensuring that treatment will achieve the desired goals

OCCURANCE

Discharge water is diluted in receiving surface water leading to reduce pathogen number with the dilution factor
Faecel indicator bacteria, such as E.Coli always present at high concentration in waste water
The concentration of pathogen in raw water can be estimated from concentration of pathogens in waste water
To provide treatment so that ensure health within water safety plan
To determine the pathogen concentration in source water

PERSISTANCE AND GROWTH IN WATER

high amount of biodegradable organic carbon together with warm water can permit growth of waterborne pathogen.
persistence is affected by several factors such as temperature.
pathogen with low persistence are more likely to be spread by person to person contact or poor personal hygiene.

IDENTIFYING LOCAL ACTIONS IN RESPONSE TO MICROBIAL WATER QUALITY PROBLEMS AND EMERGENCIES

Actions following an incident
Boil water advisories

METHODS OF DETECTION OF FAECAL INDICATOR ORGANISMS

The standardization of methods and of laboratory procedures is of great importance if criteria for the microbial quality of water are to be uniform in different laboratories and internationally.
Analysis for faecal indicator organisms provides a sensitive, although not the most rapid, indication of pollution of drinking-water supplies.

MICROBIAL MONITORING

Helminths
Microscopy
Protozoa parasites
Immunomagnetic separation in combination with immunofluorescence microscopy
Virus
Polymerase Chain Reaction (PCR)
Cell culture
Bacteria (E.coli)
Culture-based method

Solid media

Broth cultures

Included in
surveillance
operational
verification
To determine whether a treatment or other process is effective in removing target organisms.

QUANTITATIVE MICROBIAL RISK ASSESSMENT

Risk Assessment Paradigm For Pathogen Health Risks
Risk Characterization: Data collection on exposure, dose-response and incidence and severity of disease
Dose-Response Assessment: To derive the probability of an adverse effect following exposure to one or more pathogenic organisms
Exposure Assessment: Estimation of number of pathogen that is exposed to an individual through ingestion
Identify all possible hazards and their pathways from sources to recipients
Systemically combines information on exposure and dose-response models

REFERENCE PATHOGENS

PROTOZOA
Source of protozoa: Cryptospotidium and Balantidium
Least sensitive to inactivation by chemical disinfection
BACTERIA
Example: Vibrio, Campylobacter, E.coli O157, Salmonella and Shigella
Legionella and non-tuberculous mycobacteria can grow in water environment
Most sensitive to inactivation by disinfection
VIRUSES
Example: Rotaviruses, enteroviruses, and noroviruses
Can persist in a long period inn water
Smallest pathogen and difficult to remove by physical process (filtration)

Subtopic

ROUTE OF TRANSMISSION

Patients undergoing immunosuppressive therapy or those with acquired immunodeficiency syndrome (AIDS)
Ingestion of the eggs in food contaminated with faeces or faecally contaminated
Contact with water (dermal)
Inhalation of water droplets