Foodborne disease outbreaks in Australia, 1995 to 2000

This report published in Communicable Diseases Intelligence, Volume 28, Number 2 provides and analysis of foodborne disease outbreaks in Australia from 1995 to 2000. Health agencies are increasingly conducting systematic reviews of foodborne disease outbreak investigations to develop strategies to prevent future outbreaks.

Page last updated: 04 July 2004

Craig B Dalton,1 Joy Gregory,2 Martyn D Kirk,3 Russell J Stafford,4 Ed Kraa,5 David Gould6

Backgroud | Methods | Results | Discussion | Conclusion |Acknowledgements | References

Abstract

Health agencies are increasingly conducting systematic reviews of foodborne disease outbreak investigations to develop strategies to prevent future outbreaks. We surveyed state and territory health departments to summarise the epidemiology of foodborne disease outbreaks in Australia from 1995 to 2000. From 1995 through 2000, 293 outbreaks were identified, with 214 being of foodborne origin. One hundred and seventy-four (81%) had a known aetiology, and accounted for 80 per cent (6,472/8,124) of illnesses. There were 20 deaths attributed to foodborne illness. Of the 214 outbreaks, bacterial disease was responsible for 61 per cent of outbreaks, 64 per cent of cases and 95 per cent of deaths. The most frequent aetiology of outbreaks was Salmonella in 75 (35%) outbreaks, Clostridium perfringens in 30 (14%), ciguatera toxin in 23 (11%), scombrotoxin in 7 (3%) and norovirus in 6 (3%). Salmonellosis was responsible for eight of the 20 (40%) deaths, as was Listeria monocytogenes. Restaurants and commercial caterers were associated with the highest number of outbreak reports and cases. Outbreaks in hospitals and aged care facilities were responsible for 35 per cent of deaths. The most frequently implicated vehicles in the 173 outbreaks with known vehicles were meats 64 (30%), fish 34 (16%), seafood 13 (6%), salad 12 (6%), sandwiches 11 (5%) and eggs 9 (4%). Chicken, the most frequently implicated meat, was associated with 27 (13%) outbreaks. This summary demonstrates the serious nature of foodborne disease and supports the move to risk-based food safety interventions focusing on mass catering and hospital and aged care facilities. Commun Dis Intell 2004;28:211-224.

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Background

Foodborne disease is a significant cause of morbidity and mortality throughout the world.1 Contaminated food causes serious outbreaks that can result in significant societal costs. In addition, outbreaks have major implications for the food industry through lost earnings, lawsuits and damaged consumer confidence.2,3

Many countries systematically review outbreaks to develop strategies to prevent foodborne illness.3,4 These reviews allow health agencies to identify high-risk foods, hazardous food processing procedures, and pathogens commonly associated with foodborne disease outbreaks. Summary findings can then be translated into policy to reduce foodborne disease. In the United States of America, reviews of outbreak data led to changes in the recommendations about eating undercooked eggs and hamburgers and the development of processing standards for ready to eat foods.5,6,7

In Australia, doctors notify foodborne disease outbreaks to state and territory health departments under state public health laws.8 Members of the public, local government authorities and other agencies may voluntarily report foodborne outbreaks. Health agencies use standard techniques to investigate these outbreaks, and summarise the results for historical and legal purposes.9 Health agencies only publish the results of a very small proportion of these investigations, making summary reviews more important.

There have been several reviews of foodborne disease outbreaks in Australia, although their accuracy and completeness has varied considerably.10,11,12 Until the establishment of the OzFoodNet program in 2000, there had been no systematic collection of national foodborne disease data.13,14 The objective of this study was to summarise the epidemiology of foodborne disease outbreaks in Australia from 1995 to 2000, as background to the OzFoodNet initiative.

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Methods

Identification of outbreaks

We surveyed state and territory health departments in 1998, 2000 and 2002 to elicit summary information on confirmed and suspected outbreaks in their jurisdiction from January 1995 to December 2000. Medline searches were conducted using the keywords Australia, foodborne disease, food poisoning, outbreak, and the specific pathogens (Salmonella, Campylobacter, hepatitis A, Clostridium perfringens, ciguatera toxin, Staphylococcus aureus, Listeria monocytogenes, Bacillus cereus, enterohaemorrhagic Escherichia coli, Salmonella Typhi, Shigella, Vibrio, Norwalk virus, toxoplasma, scombroid); state and commonwealth health agency bulletins, conference proceedings of the Australian Society of Microbiology, the Public Health Association, and the Communicable Diseases Network Australia were reviewed to identify any other foodborne outbreaks.

For each outbreak, health department staff completed a survey form that identified the pathogen, date and setting of outbreak, number of cases, number of fatalities, the attack rate among those consuming the implicated food, the mode of transmission, the type of study and whether food microbiology was positive. We provided a dummy outbreak report as an example to guide respondents in the use of the form.

Definition of foodborne outbreak

An outbreak was defined as foodborne if two or more people experienced a similar illness after sharing a common food or meals. However, for some settings and pathogens further analytical epidemiological and/or microbiological evidence was required. For example, outbreaks occurring in an institution required epidemiological or microbiological evidence of foodborne transmission to be included as a foodborne outbreak. For outbreaks due to hepatitis A, Shigella or Giardia, which are more commonly transmitted person-to-person in Australia, epidemiological and/or microbiological evidence was required for inclusion regardless of the setting. For outbreaks due to pathogens that are more commonly associated with foodborne transmission such as Salmonella, Campylobacter, Staphylococcus aureus, Bacillus cereus and Clostridium perfringens, and fish toxins such as scombrotoxin and ciguatoxin, that occurred after common foods or meals were shared, only epidemiological (or microbiological) evidence was required to identify that the outbreak was foodborne. However, the specific food vehicle responsible for the outbreak did not have to be identified.

Clusters of seemingly unrelated cases of Salmonella of a common subtype clustered in time and place were not included unless a particular food vehicle or a particular meal was implicated through investigation. If the pathogen was unknown, epidemiological evidence implicating a specific food vehicle was required. Waterborne outbreaks were not included in this summary. Where health department summary outbreak forms provided inadequate information, we contacted outbreak investigators or reviewed departmental reports to determine the evidence of foodborne disease transmission.

Classification of food vehicle and outbreak settings

Vehicles were grouped into a hierarchical classification system for food vehicle types. We adapted the food classification system used in the Centers for Disease Control and Prevention Electronic Foodborne Outbreak Reporting System (EFORS) (personal communication, Alana C Sulka, March 2002). Vehicles were coded into four levels of classification. For example, level one foods include broad food groups such as dairy, meat, fish, seafood and eggs. Level two breaks the foods into a second level such as cheese (dairy), beef (meat), herring (fish), crab (seafood) and egg sauces (eggs). Levels three and four became increasingly more specific.

Common Australian foods that were not in this system were added where relevant, such as pork rolls, which featured a number of times as vehicles for transmission in outbreaks. These were defined as level 1-sandwiches; level 2-sandwich, red meat based, and level 3-sandwich pork. The 'soups and sandwiches' descriptor used in EFORS was separated to reflect separate meal types, as there is no reason to combine these food types in an Australian setting.

Food vehicle groupings were presented as level 1 except where meats were broken down to level 2, oysters were shown as a level 2 subset of seafood, and fruit juice was shown as a level 3 subset of 'non-dairy beverages'.

A coding system was used for classifying the settings where outbreaks occurred. We looked separately at where the food was prepared and where the food was eaten as the former more accurately reflects, where possible, food handling errors may have occurred. Most of the settings definitions are self evident. Restaurants included cafes and meals served in hotels where patrons sat down to eat. Take-away included milk bars and fast food outlets. Commercial caterer was defined as a setting in which food was produced for a special function or group (e.g. wedding and airlines) either in a private function room or at a location distant from the commercial caterer's kitchen. Contaminated primary produce was defined as food that routinely underwent no further processing before consumption. Commercial manufactured food was defined as foods that were prepared by large commercial processing groups and widely distributed.

Data management and analysis

Summary information was entered into Epi info 6.04b and analysed in Epi Info 2002 and Excel 2000. The number of foodborne disease outbreaks per capita by state or territory were calculated using 1998 Australian Bureau of Statistics population projections.15

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Results

Participation and response

There were 293 outbreak reports for the six-year period. Of these, 214 outbreaks were due to foodborne transmission and were included in the analysis. Seventy-nine outbreaks were excluded from analysis. For 78 outbreaks there was no epidemiological association with a food source, including:

  • 37 outbreaks of unknown aetiology;
  • 15 outbreaks of viral aetiology (mostly noroviruses);
  • 5 bacterial outbreaks (4 of Salmonella and 1 of Campylobacter) in institutional settings;
  • 6 outbreaks outbreak that were suspected person-to-person transmission including 3 Shigella outbreaks, two parasitic outbreaks and one hepatitis A;
  • 10 waterborne outbreaks; and
  • 5 Salmonella clusters.

One foodborne outbreak was excluded because the cases were infected while travelling overseas.

Time and state or territory of outbreak

From 1995 through 2000, there were 214 outbreaks of gastroenteritis of foodborne origin resulting in 8,124 cases. More outbreaks were reported annually during the data collection period from 1998-2000 compared to the retrospective collection of the 1995-1997 data (Table 1). Victoria and New South Wales recorded the highest number of outbreaks during the six-year period, the average number of outbreaks per million population by jurisdiction for the six-year period was highest in the Northern Territory, South Australia and Victoria. There were six multi-state outbreaks resulting in 945 cases. Outbreaks were more frequently reported in the warmer months of October through March (Figure) predominantly due to the higher incidence of Salmonella outbreaks in these months. One hundred and seventy-four (81%) outbreaks had a known aetiology and these outbreaks accounted for 79 per cent (6,472/8,124) of illnesses (Table 2). The median number of cases for foodborne outbreaks was 17 (range 2 to 862). There were 20 deaths associated with the outbreaks, equating to a fatality rate of 0.3 per cent.

Figure. Seasonality of all foodborne disease and Salmonella outbreaks, 1985 to 2000

Figure. Seasonality of all foodborne disease and Salmonella outbreaks, 1985 to 2000

Table 1. Foodborne disease outbreaks and number of people affected, 1995 to 2000, by state or territory and year


  1995 1996 1997 1998 1999 2000 Total
1995–2000
Average annual reported cases/outbreaks per million population
1995–2000
NSW Cases
71
144
475
226
422
216
1,554
41
Outbreaks
5
6
10
11
8
8
48
1
Victoria Cases
69
1213
358
669
325
2,634
95
Outbreaks
2
11
19
24
17
73
3
Queensland Cases
564
119
189
127
999
48
Outbreaks
4
3
14
12
33
2
South Australia Cases
97
173
89
378
543
60
1,340
150
Outbreaks
2
3
4
7
4
5
25
3
Western Australia Cases
4
59
146
72
151
432
39
Outbreaks
1
3
8
2
6
20
2
Tasmania Cases
32
15
47
17
Outbreaks
1
1
2
1
ACT Cases
26
23
49
26
Outbreaks
1
1
2
1
Northern Territory Cases
20
43
5
56
124
108
Outbreaks
1
2
1
1
5
4
Australia* Cases
362
1,243
2,322
1,339
1,900
958
8,124
72
Outbreaks
11
18
30
52
53
50
214
2

* Six multi-state outbreaks and 945 associated cases were only included in the total for Australia hence the annual columns for each state or territory do not sum to the total for Australia.

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Table 2. Foodborne disease outbreaks, cases, and deaths, Australia, 1995 to 2000, by aetiology (% of total)

Aetiology Outbreaks
No. (%)
Cases
No. (%)
Deaths
No. (%)
Median number of cases per outbreak Range
Bacterial
131 (61)
5,356 (64)
19 (95)
17
2–862
Salmonella
75 (35)
4,123 (51)
8 (40)
18
2–862
Clostridium perfringens
30 (14)
787 (10)
1 (5)
25
2–171
Campylobacter spp.
6 (3)
136 (2)
14
4–74
Listeria monocytogenes
5 (2)
41 (<1)
8 (40)
5
4–23
Staphylococcus aureus
5 (2)
78 (<1)
13
2–33
Bacillus cereus
2 (1)
28 (<1)
14
4–24
Enterohaemorrhagic E. coli
3 (1)
35 (<1)
2 (10)
6
6–23
Salmonella Typhi
1 (0.5)
4 (<1)
Shigella
2 (1)
42 (<1)
13–29
Streptococcus pyogenes
1 (0.5)
72 (<1)
Vibrio cholerae non O1, non O139
1 (0.5)
10 (<1)
Viral
8 (4)
780 (10)
1 (5)
40
10–466
Norovirus
6 (3)
297 (4)
40
10–97
Hepatitis A
2 (<1)
483 (6)
1 (5)
17–466
Protozoal (toxoplasma)
1 (0.5)
12 (<1)
0
Chemical
34 (16)
324 (4)
0
6
2–56
Ciguatera
23 (11)
179 (2)
5
2–33
Scombroid
7 (3)
34 (<1)
4
3–9
Dinophysis species
2 (1)
78 (<1)
22–56
Wax ester (escolar)
2 (1)
33 (<1)
14–19
Unknown
40 (19)
1,652 (20)
0
28
5–200
Total
214 (100)
8,124 (100)
20 (100)
17
2–862

Aetiological agent

Of the 214 outbreaks, bacterial disease was responsible for 61 per cent of outbreaks, 64 per cent of cases and 95 per cent of deaths (Table 2). Most frequent were non-typhoidal salmonellae in 75 (35%) outbreaks, Clostridium perfringens in 30 (14%), ciguatera toxin in 23 (11%), scombrotoxin in 7 (3%), and norovirus in 6 (3%). Campylobacter spp. and Listeria monocytogenes were responsible for only 6 (3%) and 5 (2%) outbreaks respectively. Salmonellosis was responsible for eight of the 20 (40%) deaths, as was Listeria monocytogenes. Enterohaemorrhagic E. coli was responsible for two deaths, and C. perfringens and hepatitis A, one death each.

The largest outbreaks were 862 cases of illness associated with Asian-style pork rolls in Victoria in 1997 in which Salmonella Typhimurium phage type 1 was confirmed as the aetiological agent,16 502 cases of illness in South Australian in 1999, associated with the consumption of orange juice in which Salmonella Typhimurium phage type 135A was confirmed as the aetiological agent (Ingrid Tribe, personal communication, May 2004) and 466   cases of hepatitis A in New South Wales in 1998, associated with oysters.17

Fourteen different serotypes of Salmonella were responsible for foodborne outbreaks, with serotype Typhimurium responsible for 49 (65%) of all Salmonella outbreaks and 2,716 (66%) of all Salmonella cases. The most common phage types of S. Typhimurium were phage type 135 (16 outbreaks, 1,014 cases); phage type 9, (13 outbreaks, 454 cases); and phage type 64 (4 outbreaks, 81 cases). S. Virchow was the second most common serotype responsible for eight outbreaks, with phage type 34 accounting for seven outbreaks (78 cases). The following serotypes were also implicated: Chester (4 outbreaks, 62 cases); Bredeney (2 outbreaks, 183 cases); Heidelberg (2 outbreaks, 507 cases); Mbandaka (2 outbreaks, 175 cases). Serotypes Anatum, Bareilly, Brandenburg, Hessarek, Mississippi, Muenchen, Oranienburg, and Saintpaul each caused one outbreak with a total of 248 cases ranging from two to 102 cases per outbreak.

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Setting of outbreaks

Setting of food preparation

Ninety-four per cent (202/214) of outbreaks were associated with food prepared commercially or in settings other than private residences. Restaurants were associated with the highest number of outbreak reports and commercial caterers with the highest number of cases (Table 3).

Table 3. Foodborne disease outbreaks, cases, and deaths, Australia, 1995 to 2000, by setting prepared (% of total)

Setting prepared Outbreaks
No. (%)
Cases
No. (%)
Deaths
No. (%)
Median number of cases per outbreak Range
Restaurants
60 (28)
1,084 (13)
4 (20)
13
3–96
Commercial caterer
43 (20)
2,264 (28)
1 (5)
30
5–500
Contaminated primary produce
34 (16)
996 (13)
2 (10)
8
2–466
Take-away
(non franchised)
17 (8)
1,397 (17)
23
2–862
Commercial manufactured food
14 (7)
967 (12)
5 (25)
17
2–502
Private residence
12 (6)
237 (3)
16
4–55
Aged care institution
8 (4)
167 (2)
4 (20)
22
4–37
Institution not elsewhere specified
5 (2)
304 (4)
72
17–85
Camp
4 (2)
252 (3)
22
9–200
Fair, festival, other temporary/mobile service
4 (2)
125 (2)
1 (5)
20
12–74
Hospital
3 (1)
64 (<1)
3 (15)
13
5–46
School
3 (1)
188 (2)
74
24–90
Grocery store/deli/ supermarket
3 (1)
24 (<1)
8
6–10
Military institution
1 (<1)
8 (<1)
Contaminated imported food
1 (<1)
17 (<1)
Other
1 (<1)
3 (<1)
Unknown
1 (<1)
27 (<1)
Total
214 (100)
8,124 (100)
20 (100)
17
2–862

The median number of cases per outbreak was much higher for commercial caterers (30 cases), take-away (23 cases) and commercially manufactured food (17 cases) than for restaurants (13 cases) reflecting the relative scale of production in these industry sectors. Aged care and hospital settings were responsible for 35 per cent of deaths despite being associated with only five per cent of outbreaks and less than three per cent of cases. There were seven deaths among 231 (3%) cases in aged care and hospital settings compared to 13 deaths among 5,297 cases (0.3%) in other settings in which deaths occurred.

Setting of food consumption

The setting where people consumed the implicated food was usually the same as where the food was prepared. The exception was where foods were purchased from a take-away store, a grocery store, delicatessen, or a supermarket. Foods contaminated in a commercial manufacturing setting or where the food was grown, were also consumed elsewhere. Foods prepared in settings where consumption occurred elsewhere resulted in 39 outbreaks and 3,288 cases in the community, and 37 outbreaks and 398 cases clustered in private residences.

Implicated food vehicles

A food vehicle was implicated in 173 (81%) of the 214 outbreaks. The most frequent vehicles were meats 64 (30%), fish 34 (16%), seafood 13 (6%), salad 12 (6%), sandwiches 11 (5%), desserts 9 (4%) and eggs 9 (4%) (Table 4). Chicken was the most frequently implicated meat and was associated with 27 (13%) outbreaks. Fish was the next most common cause of outbreaks but it was responsible for a relatively smaller number of cases as most were small outbreaks of ciguatera poisoning. When all outbreaks containing foods in which egg was the main high-risk ingredient were collated, a total of 16 potentially egg-associated outbreaks were identified. Salmonella was the aetiological agent for 14 of the 16 potentially egg-associated outbreaks. Salad, egg, dessert, and sandwich (pork roll) associated outbreaks tended to result in higher numbers of cases per outbreak. Seventy per cent (565/803) of cases attributed to seafood outbreaks were due to oyster consumption in the Wallis Lake oyster outbreak responsible for 446 cases of hepatitis A.17

Table 4. Foodborne disease outbreaks, cases, and deaths, Australia, 1995 to 2000, by vehicle of transmission (% of total)

Vehicle
Outbreaks
No. (%)
Cases
No. (%)
Deaths
No. (%)
Median number of cases per outbreak Range
Meats
64 (30)
1,846 (23)
7 (35)
17
2–200
Chicken
27
899
3
21
2–171
Beef
9
313
1
15
2–200
Pork
4
126
26
15–60
Lamb
2
16
4–12
Processed meats- consumed cold
6
97
2
16
8–24
Other meats*
16
395
1
20
4–85
Fish
34 (16)
281 (4)
6
2–33
Seafood
13 (6)
803 (10)
1 (5)
22
2–466
Oysters
3
565
1
97
2–466
Salads
12 (6)
587 (7)
3 (15)
29
4–176
Sandwiches
11 (5)
1,321 (16)
1 (5)
42
11–862
Eggs
9 (4)
773 (10)
36
7–500
Desserts
9 (4)
439 (6)
45
8–102
Grains
5 (2)
178 (2)
37
24–48
Dairy
5 (2)
81 (1)
12
9–27
Specialty/ethnic dishes
5 (2)
46 (<1)
1 (5)
6
3–24
Soup
2 (<1)
80 (<1)
13–67
Fruit
2 (<1)
60 (<1)
1 (5)
6–54
Vegetables
1 (<1)
54 (<1)
Fruit juice
1 (<1)
502 (6)
Miscellaneous
37 (17)
1,004 (13)
6 (30)
10
3–164
Unknown
4 (2)
69 (<1)
17
10–26
Total
214 (100)
8,124 (100)
20 (100)
17
2–862

* Includes meats in above categories that may be mixed together and meats not in above categories, or where type of meat was not known.

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Selected food vehicles, aetiological agents and settings combinations

Meats, particularly chicken were associated with 33 per cent of Salmonella and 60 per cent of C. perfringens outbreaks (Table 5). Restaurants, commercial caterers, and take-away settings were associated with 61 per cent of Salmonella outbreaks (Table 6). Meats were associated with a significant number of outbreaks across a range of settings (Table 7).

Table 5. Foodborne disease outbreaks and number of people affected, Australia, 1995 to 2000, by selected aetiological agents and food vehicle implicated

Vehicle
Aetiological agent
Salmonella C. perfringens Norovirus Campylobacter Unknown
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Meats 25 (33) 658 (17) 18 (60) 572 (73) 1 (17) 96 (32) 1* (17) 4 (3) 11 (28) 401 (24)
Chicken
10
335
6
312
1
96
6
112
Beef
4
67
2
32
3
214
Pork
2
37
1
29
1
60
Lamb
2
16
Processed meats–consumed cold
4
61
Other meats
5
158
7
183
1
15
Eggs
8 (11)
701 (17)
Sandwiches
7 (9)
1205 (29)
3 (8)
103 (6)
Desserts
6 (8)
254 (6)
1(17)
51(17)
2 (5)
134 (8)
Fruit
2 (3)
60 (1)
Seafood
2 (3)
14 (< 1)
2 (7)
76 (10)
2(33)
111 (37)
1 (3)
27 (2)
Dairy
1 (1)
12 (< 1)
1 (3)
27 (3)
3 (50)
42 (31)
Fish
1 (1)
26 (< 1)
1 (3)
9 (< 1)
Fruit juice
1 (1)
502 (12)
Salads
1 (1)
21 (< 1)
1 (17)
74 (54)
8 (20)
459 (28)
Vegetables
1(1)
54 (1)
Specialty/Ethnic dishes
2 (7)
32 (4)
1 (3)
5 (< 1)
Grains
1(17)
29 (10)
3 (8)
125 (8)
Soups
2 (5)
80 (5)
Miscellaneous
18 (24)
573 (14)
6 (20)
70 (9)
1(17)
10 (3)
8 (20)
309 (19)
Unknown
2 (3)
43 (1)
1 (3)
10 (1)
1 (17)
16 (12)
Total
75 (100)
4,123 (100)
30 (100)
787 (100)
6 (100)
297 (100)
6 (100)
136 (100)
40 (100)
1,652 (100)

* Poultry.

† Includes meats in above categories that may be mixed together and meats not in above categories, or where type of meat was not known.

Table 6. Foodborne disease outbreaks and number of people affected, Australia, 1995 to 2000, by selected aetiological agents and setting where the food was prepared

Setting prepared
Aetiological agent
Salmonella C. perfringens Norovirus Campylobacter Unknown
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Restaurants
19 (25)
395 (10)
8 (27)
89 (11)
3 (50)
120 (40)
2 (33)
20 (15)
15 (38)
336 (20)
Commercial caterer
16 (21)
992 (24)
9 (30)
388 (49)
2 (33)
80 (27)
14 (35)
754 (46)
Contaminated primary produce
6 (8)
164 (4)
1 (17)
97 (33)
1 (17)
12 (9)
Take-away
(non franchised)
11 (15)
1,316 (32)
2 (5)
59 (4)
Commercial manufactured food
10 (13)
933 (23)
1 (3)
2 (< 1)
Private residence
4 (5)
26 (< 1)
2 (7)
63 (8)
2 (5)
74 (5)
Aged care
2 (3)
25 (< 1)
5 (17)
138 (18)
Institution not elsewhere specified
1 (1)
85 (2)
1 (3)
56 (7)
1 (17)
74 (54)
1 (3)
17 (1)
Camp
1 (1)
22 (< 1)
2 (33)
30 (22)
1 (3)
200 (12)
Fair, festival, other temporary/ mobile service
2 (3)
101 (3)
2 (7)
24 (3)
Hospital
1 (1)
46 (1)
1 (3)
13 (< 1)
School
1 (3)
24 (3)
2 (5)
164 (11)
Grocery store/deli/ supermarket
2 (3)
18 (< 1)
Military institution
1 (3)
8 (< 1)
Contaminated imported food
Other
1 (3)
3 (< 1)
Unknown
1 (3)
27 (2)
Total
75 (100)
4,123 (100)
30 (100)
787 (100)
6 (100)
297 (100)
6 (100)
136 (100)
40 (100)
1,652 (100)

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Table 7. Foodborne disease outbreaks and number of people affected, Australia, 1995 to 2000, by food vehicle and selected settings where the food was prepared

Vehicle
Setting
Restaurant Take-away Commercial caterer Commercial manufactured food Private residence Hospital/aged care
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Outbreaks
No. (%)
Cases
No. (%)
Meats
20 (33)
372 (34)
6 (35)
203 (15)
11 (26)
499 (22)
8 (57)
105 (11)
6 (50)
94 (40)
3 (27)
105 (46)
Chicken
10
242
6
203
5
314
2 (14)
14 (2)
2
38
1
32
Beef
2
23
2
89
2 (14)
17 (2)
2
38
1
37
Pork
1
15
1
36
Lamb
1
4
Processed meats–consumed cold
1
23
3 (21)
51 (5)
1
13
Other meats*
6
88
3
73
1 (7)
23 (2)
1
5
Eggs
2 (3)
96 (9)
4 (9)
580 (26)
2 (18)
25 (11)
Sandwiches
5 (29)
1,096 (79)
3 (7)
84 (4)
1 (7)
78 (8)
1 (9)
46 (20)
Desserts
2 (3)
84 (8)
3 (18)
68 (5)
2 (5)
111 (5)
1 (7)
102 (11)
Fruit
Seafood
3 (5)
51 (5)
1 (2)
43 (2)
2 (14)
16 (2)
1 (8)
33 (14)
Dairy
1 (2)
27 (1)
Fish
9 (15)
72 (7)
1 (2)
26 (1)
1 (8)
4 (2)
Fruit juice
1 (7)
502 (52)
Salads
3 (5)
61 (6)
4 (9)
347 (15)
2 (17)
74 (31)
1 (9)
4 (2)
Vegetables
Grains
1 (2)
48 (4)
3 (7)
106 (5)
1 (8)
24 (10)
Soup
1 (2)
67 (3)
1 (9)
13 (6)
Specialty/ ethnic dishes
2 (3)
11 ( 1)
1 (6)
3 (< 1)
1 (9)
8 (4)
Miscellaneous
16 (27)
256 (24)
2 (12)
27 (2)
10 (23)
338 (15)
1 (7)
164 (17)
1 (8)
8 (3)
2 (18)
30 (13)
Unknown
2 (3)
33 (3)
2 (5)
36 (2)
Total
60 (100)
1,084 (100)
17 (100)
1,343 (100)
43 (100)
2,264 (100)
14 (100)
967 (100)
12 (100)
237 (100)
11 (100)
231 (100)

* Includes meats in above categories that may be mixed together and meats not in above categories, or where type of meat was not known.

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Discussion

This is the most comprehensive summary of foodborne outbreaks in Australia since the publication of a summary from 1980 to 1995 by Crerar, et al.11 Crerar's 16 year summary identified 128 outbreaks-an average of eight outbreaks per year and six deaths in 15 years. Our collection of outbreaks identified 214 outbreaks over six years and 20 deaths-an average of 36 outbreaks per year and an average of 52 outbreaks during the contemporaneous collection from 1998 to 2000. We believe this reflects an improvement in the documentation of outbreaks due to improved availability of records and better recollection of more recent outbreaks. It is unlikely to be due to increased diagnostic capability as primary identification methods for the most common aetiological agents in this review have not changed substantially during this period. This highlights the importance of contemporaneous reporting of outbreaks in a standardised format. The new OzFoodNet outbreak surveillance system facilitates such reporting but this must be well supported at the local and state level.14

This summary of outbreaks contains some important information for policy makers involved in preventing foodborne illnesses. These data suggest a need for initiatives in commercial catering and aged care and hospital catering settings and for special attention to be given to particular high risk foods.

High-risk settings

Outbreaks in aged-care and hospital facilities were associated with 35 per cent of all deaths. These data lend support to the recent draft National Risk Framework that prioritises catering for immune compromised people and commercial catering as high-risk settings.12 Ensuring high-risk patients do not receive high-risk foods could prevent many of these deaths. In this review the case fatality rate was three per cent for aged care and hospital settings compared to 0.3 per cent for all foodborne outbreaks. This raises the need for urgent implementation of food safety plans in these settings. While Listeria monocytogenes outbreaks occur rarely, the high case-fatality rate of approximately 20 per cent highlights the need for attention, particularly in institutions where residents are immune-compromised.18 The NSW Health Department issued a circular on listeriosis control in such settings which emphasises implementation of Hazard Analysis Critical Control Points (HACCP); separating high risk foods from high risk patients, food temperature control, and cross contamination control.19 Policy makers and regulators should ensure that HACCP is implemented in these settings.

Commercial caterers were responsible for the largest number of cases of any setting or 27 per cent of all cases. Commercial caterers are a special risk because they prepare large volumes of food and may be required to cater in venues with inadequate cooking, storage, transport, cooling, and reheating facilities. Several aspects of commercial catering make it difficult for regulators to identify and inspect these operations. Commercial caterers may be highly mobile and prepare or serve food in different settings from week to week including private residences, leased function rooms, and public venues and their operations are often conducted on weekends. Identifying and inspecting these operations for compliance with the Food Standards Code will help ensure that appropriate facilities are used and reduce the potential for outbreaks.

High-risk foods

Food vehicles that need special attention for interventions include chicken, eggs, certain fish species, salads, seafood (particularly prawns and oysters) and sandwiches.

Chicken was the most common meat associated with outbreaks. Chicken is a commonly consumed food and needs to be produced in as safe a manner as possible. The high proportion of chicken associated outbreaks due to Salmonella and Clostridium perfringens suggest the need for efforts at the point of primary production, processing, and food preparation. Reduction of contamination at the processing level and appropriate food handling in restaurants and homes and effective cooking can reduce the risk of foodborne infection. Interventions to reduce bacterial contamination at farm and processing levels can significantly reduce human infection as has been demonstrated in Iceland and Denmark.20,21

Egg-based foods were commonly reported in this series of foodborne outbreaks. We cannot be certain how many of these outbreaks were due to direct contamination from the surface of eggs, from internally contaminated eggs, or contamination of an egg-based food. Nevertheless, the high proportion of egg associated outbreaks that were due to Salmonella suggests the need for vigilance. Salmonella Typhimurium phage types 9 and 135 were the predominant pathogens identified in egg-associated outbreaks. The link between eggs and outbreaks of salmonellosis has been well established in Europe and the United States of America due to transovarian transmission of infection.22,23 There is no evidence of transovarian transmission of disease in Australia, nevertheless these data suggest that there is a need for the egg industry to monitor egg production hygiene issues closely. Additionally, control of temperature and prevention of cross contamination of eggs in processing, storage, and food preparation is extremely important. Since the compilation of these data there have been further egg-associated outbreaks, some of which were traced back to layer farms that were positive for the outbreak strain of Salmonella.24 Even quite low contamination rates (e.g. < 0.01%) of eggs can pose a significant public health problem.25

Reef fish are a significant cause of ciguatera poisoning which causes a severe illness occasionally with a fatal outcome.26 Better education of restaurateurs, fish wholesalers, and recreational fisherman is required to prevent the consumption of high-risk fish. Public health traceback investigations may identify specific reefs that are high risk for ciguatera. There are no suitable routine tests to detect ciguatera toxin in fish, nor can the toxin be detected in the fish by its appearance, odour, texture or taste. In general terms, the risk of poisoning is increased by consuming larger and presumably older fish, but poisoning can sometimes occur following the consumption of relatively small fish. These risks are increased for people who regularly consume fish soups using the head or viscera of smaller fish, where the toxin concentrations may be higher.

In this review seafood associated outbreaks included three oyster outbreaks (Salmonella, norovirus, and hepatitis A) and four prawn-associated outbreaks (hepatitis A, C. perfringens (2), and Salmonella Typhi). Hepatitis A, while rare, causes serious illness with an average of 12.5 days of work missed.27 In this summary, the hepatitis A outbreak associated with Wallis Lake oysters shows the potential of this disease to cause large widespread outbreaks. These outbreaks are difficult to investigate due to the long incubation period of hepatitis A.17

Salads were responsible for 12 outbreaks. While salads are not often considered a high-risk food the minimal post-harvest processing of salads requires good on-farm HACCP as consumers and retailers have minimal opportunity to prevent illness.28,29

Four outbreaks were associated with Asian-style pork rolls, a high risk food by virtue of the ingredients and method of preparation. One of these outbreaks was the largest single documented outbreak in our review with 862 cases.16 Pork rolls include a range of high-risk foods including eggs, chicken liver pate, and pork.

Sandwiches are not usually considered a high-risk food. This perception and the use of sandwiches in mass catering-particularly where sandwiches may be stored for many hours at room temperature for convenience-may contribute to temperature abuse and subsequent food poisoning. Temperature control of sandwiches should be a high priority with a 'use by time' label to manage sandwich safety in mass catering settings.

Barriers to surveillance and limitations of outbreaks summaries

The number of outbreaks per million residents differs greatly across states and territories. This reflects differences in detection, and investigation of outbreaks, and formal systems of documentation rather than real differences in outbreak activity. This is exemplified by the disparity in outbreaks reported to the US Centers for Disease Control and Prevention from 1993 to 1995 with interstate incidence ranging from 73 outbreaks per million population to 0.65 in some years.4 While much research is needed into the usefulness of this population-based ratio, it may be useful as a tool for evaluation of surveillance systems.30,31 The lack of any reports from Victoria in 1995 is explained by difficulties in recall or identification of records rather than an absence of outbreaks or outbreak investigation. Victoria began to systematically record outbreaks in August 1995 (personal communication, Joy Gregory, December 2003). The prospective reporting of outbreaks to OzFoodNet from 2001 should redress these reporting disparities.

This summary is biased by patterns of reporting, analysis, investigation and laboratory testing for foodborne disease outbreaks. The number of outbreaks documented by setting is very dependent on reporting biases.3 Patient and doctor behaviour is affected by the patient's symptoms. Patients are more likely to present to a doctor and be tested if their diarrhoeal illness lasts more than two days or involves bloody diarrhoea (personal communication, Gill Hall, October 2003). Outbreaks are more likely to be recognised and investigated where an established social, work, or familial group share a common meal-leading to greater recognition of restaurant and catered function outbreaks. The relatively smaller number of outbreaks associated with commercial manufactured food may reflect quality assurance processes in this sector. Alternatively, outbreaks due to high volume commercial products with wide distribution may have such low attack rates that a common source of illness is difficult to identify.

Patterns of laboratory testing may bias outbreak summaries leading to greater recognition of pathogens such as Salmonella, Campylobacter, and Shigella which are identified by routine stool cultures ordered by general practitioners. Norovirus, C. perfringens, Staphylococcus aureus, Bacillus cereus outbreaks are less likely to be detected because tests for these agents are not routinely ordered by general practitioners. Tests for these pathogens are usually requested by public health officials only after an outbreak with typical symptom or incubation period profile is recognised. Additionally, many of these agents are only excreted in stool for a short period making detection less likely if there is a delay in stool testing.

The real time collection of outbreak summaries and enhancement of foodborne disease investigation and surveillance under OzFoodNet and advances in laboratory methods will ensure better information for food safety initiatives in the future. The number of cases and deaths are very likely an underestimate of those occurring even within the reported outbreaks as complete case ascertainment could not be confirmed and cases were not followed up to confirm recovery. Immune-compromised persons may die many weeks or months after suffering a foodborne disease, however, attributing the cause of death may be difficult.32

Data collected on potential factors contributing to outbreaks were not included here because of the lack of standard systems for inspection and criteria for linking inspection findings with outbreak causation. Because environmental inspections are always conducted after an outbreak, it is difficult to know if the conditions found during the inspection were associated with the outbreak.

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Conclusion

The outbreaks reported here are biased by multiple layers of surveillance barriers and constitute only a small proportion of the outbreaks, cases and deaths that actually occurred. Nevertheless, food safety regulators rely on these summaries as they provide evidence of repeated failures in the system. This review highlights the major areas of concern during 1995 to 2000. During the period there were several serious and large outbreaks, causing at least 20 deaths. Clearly, this burden of illness justifies the attention given to foodborne disease and food safety in Australia.33 There is an urgent need for Australia to prioritise initiatives for high-risk foods, high risk settings, and production methods to prevent outbreaks and sporadic disease.

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Acknowledgements

We would like to thank the many health department staff that investigated foodborne outbreaks that contributed to this review. Thanks also to thank Mohinda Sarna, Rod Givney, Ingrid Tribe, Jane Raupach, David Peacock, Eddie O'Brien, Tony Watson, Brian MacKenzie and Steve Munyard for providing extra information about outbreaks, Katerina Ludenowski for research assistance, and Rosemarie Schmidt for editing. We also thank the many members of the public who report outbreaks and provide information to investigators. We thank the food manufacturers and handlers involved in outbreaks for their cooperation that is so essential to the prevention of future outbreaks. Joy Gregory, Russell Stafford and Martyn Kirk are funded by the Australian Government Department of Health and Ageing's OzFoodNet program of work.

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References

1. Käferstein FK, Motarjemi Y, Bettcher DW. Foodborne disease control: A transnational challenge [Review]. Emerg Infect Dis 1997;3:503-510.

2. Dalton CB, Douglas RM. Great expectations: the coroner's report on the South Australian haemolytic-uraemic syndrome outbreak. Med J Aust 1996;164:175-177.

3. O'Brien SJ, Elson R, Gillespie IA, Adak GK, Cowden JM. Surveillance of foodborne outbreaks of infectious intestinal disease in England and Wales 1992-1999: contributing to evidence-based food policy? Public Health 2002;116:75-80.

4. Olsen SJ, MacKinnon LC, Goulding JS, Bean NH, Slutsker L. Surveillance for foodborne-disease outbreaks-United States, 1993-1997. MMWR CDC Surveill Summ 2000;49:1-62.

5. Trepka MJ, Archer JR, Altekruse SF, Proctor ME, Davis JP. An increase in sporadic and outbreak-associated Salmonella enteritidis infections in Wisconsin: the role of eggs. J Infect Dis 1999;180:1214-1219.

6. Tappero J, Schuchat A, Deaver K, Mascola L, Wenger JD, for the Listeriosis Study Group. Reduction in the incidence of human listeriosis in the United States: Effectiveness of prevention efforts? JAMA 1995;273:1118-1122.

7. Bell BP, Goldoft M, Griffin P, Davis MA, Gordon DC, Tarr P, et al. A multistate outbreak of Escherichia coli O157:H7-associated bloody diarrhea and hemolytic uremic syndrome from hamburgers: the Washington experience. JAMA 1994;272:1349-1353.

8. Commonwealth Department of Health and Family Services. Foodborne Disease: Towards Reducing Foodborne Illness in Australia. Technical Report Series No. 2. Commonwealth Department of Health and Family Services, Canberra. 1997.

9. Gregg MB, Ed. Field Epidemiology 2nd edition. Oxford Press. 2002.

10. Davey GR. Food poisoning in New South Wales: 1977-84. Food Technology in Australia 1985;37:453-457.

11. Crerar SK, Dalton CB, Longbottom HM, Kraa E. Foodborne disease: current trends and future surveillance needs in Australia. Med J Aust 1996;165:672-675.

12. National Risk Validation Project. Report to the Department of Health and Ageing, Canberra. 2002. Available from: http://www1.health.gov.au/internet/main/publishing.nsf/Content/health-pubhlth-strateg-foodpolicy-pdf-validation.htm Accessed on 22 October 2003.

13. Ashbolt R, Givney R, Gregory JE, Hall G, Hundy R, Kirk M, et al. Enhancing foodborne disease surveillance across Australia in 2001: the OzFoodNet Working Group. Commun Dis Intell 2002;26:375-406.

14. OzFoodNet Working Group. Foodborne disease in Australia: incidence, notifications and outbreaks. Annual report of the OzFoodNet network, 2002. Commun Dis Intell 2003;27:209-243.

15. Australian Bureau of Statistics. Population projections 1997 to 2051. 1998. ISSN 1329-3109.

16. Surveillance of Notifiable Infectious diseases in Victoria 1997'. Public Health and Development Division Human Services Victoria.

17. Conaty S, Bird P, Bell G, Kraa E, Grohmann G, McAnulty JM, et al. Hepatitis A in New South Wales, Australia from consumption of oysters: the first reported outbreak. Epidemiol Infect 2000;124:121-30.

18. Farber JM, Peterkin PI. Listeria monocytogenes, a food-borne pathogen [published erratum appears in Microbiol Rev 1991;55:752]. Microbiol Rev 1991;55:476-511.

19. NSW Health Department. Control of foodborne listeriosis in health care institutions. 2003 Circular No. 2003/33.

20. Stern NJ, Hiett KL, Alfredsson GA, Kristinsson KG, Reiersen J, Hardardottir H, et al. Campylobacter spp. in Icelandic poultry operations and human disease. Epidemiol Infect 2003;130:23-32.

21. Wegener HC, Hald T, Wong DLF, Madsen M, Korsdaard H, Bager F, et al. Salmonella Control Programs in Denmark. Emerg Infect Dis 2003;9:774-780.

22. Advisory Committee on the Microbiological Safety of Food. Report on Salmonella in eggs. London: HSMO 1993.

23. Outbreaks of Salmonella serotype enteritidis infection associated with eating shell eggs-United States, 1999-2001. MMWR Morb Mortal Wkly Rep 2003;51:1149-1152.

24. Tribe IG, Cowell D, Cameron P, Cameron S. An outbreak of Salmonella Typhimurium phage type 135 infection linked to the consumption of raw shell eggs in an aged care facility. Commun Dis Intell 2002;26:38-39.

25. Salmonella Enteritidis Risk Assessment. Shell Eggs and Egg Products Final Report 1998. US Food Safety Inspection Service.

26. Lehane L. Ciguatera update [Review]. Med J Aust 2000;172:176-179.

27. Dalton CB, Haddix A, Hoffman RE, Mast EE. The cost of a food-borne outbreak of hepatitis A in Denver, Colorado. Arch Intern Med 1996;156:1013-1016.

28. Stafford RJ, McCall BJ, Neill AS, Leon DS, Dorricott GJ, Towner CD, et al. A statewide outbreak of Salmonella bovismorbificans phage type 32 infection in Queensland. Commun Dis Intell 2002;26:568-573.

29. Kirk M, Waddell R, Dalton C, Creaser A, Rose N. A prolonged outbreak of Campylobacter infection at a training facility. Commun Dis Intell 1997;21:57-61.

30. Dalton CB. Foodborne disease surveillance in NSW: Moving to performance standards. N S W Public Health Bull 2004;15:2-5.

31. Boxall N, Ortega J. Annual Summary of Outbreaks in New Zealand in 2002. A report to the Ministry of Health by the Institute of Environmental Science and Research Limited (ESR). April 2003.

32. Helms M, Vastrup P, Gerner-Smidt P, Molbak K. Short and long term mortality associated with foodborne bacterial gastrointestinal infections: registry based study. BMJ 2003;326:357.

33. Hall GV, D'Souza RM, Kirk MD. Foodborne disease in the new millennium: out of the frying pan and into the fire? Med J Aust 2002;177:614-618.

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Author affiliations

1. Hunter Population Health, Conjoint Senior Lecturer in Community Medicine, University of Newcastle, Wallsend, New South Wales

2. Epidemiologist, OzFoodNet Victoria, Department of Human Services, Melbourne, Victoria

3. Coordinating Epidemiologist, OzFoodNet, Department of Health and Ageing, Canberra, Australian Capital Territory

4. Epidemiologist, OzFoodNet Queensland, Queensland Health, Archerfield, Queensland

5. Safe Food Production NSW, PO Box A2613, Sydney South, New South Wales

6. Senior Environmental Health Officer, Communicable Diseases Unit, Queensland Health, Brisbane, Queensland

Corresponding author: Dr Craig Dalton, Hunter Population Health, Conjoint Senior Lecturer in Community Medicine, University of Newcastle, Locked Mail Bag 10, Wallsend NSW 2287. Telephone: +61 2 4924 6477. Facsimile: +61 2 4924 6490. Email: cdalt@doh.health.nsw.gov.au


This article was published in Communicable Diseases Intelligence, Volume 28 No 2, June 2004.

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This issue - Vol 28 No 2, June 2004