Actions After an Isolation

In Summary

  • A multidisciplinary team of senior management, technical and cleaning staff, plus any staff with microbiological experience should be set up to investigate and implement corrective measures. External consultants may also be used to fill any knowledge gaps. Many FBOs also include an environmental health officer in this team.
  • HACCP and similar records should be reviewed. Including a review or audit of cleaning effectiveness, including the cleaning of complex machines.
  • Clues to determining contamination source may be found from; historical records of previous isolations and extensive environmental sampling (both before, and during processing).
  • Mitigation measures in the future may be to; keep the processing environment as dry as possible, temporarily remove any equipment which must be wet-cleaned from the high risk area, repairing any cracks or damaged surfaces, ensuring drains are not blocked or clogged, introducing (or auditing) positive air pressure systems in the high risk area, and auditing personnel practices and personal hygiene practices.

 

Actions after a positive isolation of L. monocytogenes from a processing environment or final product

If it has not already been done, a multidisciplinary team should be established to handle the implications of the isolation. Spanu and Jordan, (2020) have provided detailed instructions of how to assemble a team with an appropriate skillset. Members of the team should include senior management (to ensure any findings of an investigation are implemented), plant technical and cleaning staff, along with staff that have microbiological experience. External consultants can be used to fill technical knowledge gaps if necessary. Many FBOs find there is benefit for the inclusion of EHOs and other enforcement officers into the HACCP team.

A common initial step for an L. monocytogenes isolation is to review HACCP schemes and HACCP-related records to determine if there was ineffective process monitoring that caused the issue. Typically, the review takes the form of an unannounced audit. It should be kept in mind that for some fish processes including cold smoking, there are very few critical control points that can effectively control L. monocytogenes (or reduce it to an acceptable level). Some of the CCPs that are available have questionable legality in the EU. Consequently, for an isolation associated with a cold smoking process, it is more usual to investigate the pre-requisite supply chain programme and secondary control points (also known as control points or operation pre-requisite programmes).

A review/audit should also include an assessment of cleaning effectiveness and review the degree of complex machine disassembly, the standard operating procedures for cleaning, cleaning frequencies and the chemicals used and at what concentrations. The auditor should ideally be accompanied by a plant engineer to assist in the disassembly of equipment. Poorly designed or damaged processing equipment can be a persistent source of L. monocytogenes. A good audit will visit a plant prior to the commencement of processing and note any poorly cleaned areas of equipment or the plant environment, especially if these are contaminated with food detritus after a clean down. An exceptionally thorough audit will include microbiological sample collections and tests from poorly cleaned disassembled equipment.

Clues to likely sources of L. monocytogenes can often be found by scrutinising the record of historical isolations in a plant. Many auditors will plot these isolations on a plan of the plant as a way of assessing if there are geographical connections between isolations, or a role for plant infrastructures such as drains in the spread of L. monocytogenes. Suspected geographical issues can be confirmed or excluded by extensive sample collection in the suspected problem areas. Common strategies are to vary the sample collection surfaces from those routinely sampled by the FBO and to vary the time that samples are collected. Plant resident L. monocytogenes can emerge from niches only after the commencement of processing and so it can be beneficial to sample during, as well as before, processing.

Assess staff and equipment movements between the low and high care sections of the plant. Clothes and footwear in one section of the plant should not be used in the other. Cross contamination can occur when staff circumvent the barriers protecting the high care area (HCA). The movements of plant engineering and maintenance staff and their tools should also be scrutinised.

An effective strategy in dealing with L. monocytogenes is to keep the processing plant as dry as possible (Jami et al. 2014; Overney et al. 2017). Many larger fish processors do not allow any water to be used in their HCA during routine processing. It is a good practice to remove all non-essential hoses from the HCA and to only dry clean floors of detritus (e. g. using squeegees) during production. A common practice for equipment that has an absolute requirement for wet cleaning during production is to remove it from the HCA and to clean it in an anteroom that is physically separated from the HCA. Typically, such rooms have elevated thresholds on the entrance doors to contain water and equipment is cleaned on elevated mesh or slats to prevent the underside from becoming wet from hose splashing. In some plants there was careful consideration of the location of cleaning anterooms, which were typically built as extensions to the main processing halls. A number of processers preferred situating cleaning anterooms in close proximity to drain exits to prevent wetting the drains inside the processing halls from equipment cleaning in anterooms.

Water movement through drains should be from the HCA to the low care area (LCA). Blockages in the drains that change water movement from the LCA into the HCA can result in the transfer of L. monocytogenes into the HCA. Drains should be checked to ensure there is no blockage after an L. monocytogenes isolation.

The plant walls, drains and floors should be repaired if cracked or otherwise damaged to prevent the establishment of plant resident L. monocytogenes in cracks and other damaged areas of the plant infrastructure. Rooves and the drainage from them can allow the establishment of L. monocytogenes if blocked or damaged guttering results in water draining into the plant. There is evidence in the literature that the replacement of processing equipment could result in the release of contained contamination into the plant environment. Thus, any new isolation issues may be linked to recent refurbishment.

Audit the effectiveness of positive air pressure systems for HCA to ensure that air movements are always inside to outside.

Audit employee hand washing and glove replacement frequencies. Hand and glove swabs can be undertaken to ensure hygienic handling of product. Gloves can become contaminated in dispensers if inappropriate cleaning is undertaken in the vicinity. Gloves and paper hand towels should be removed from dispensers during cleaning. Gloves taken from a dispenser can be randomly checked for sterility.

Staff locker searches can be undertaken to ensure that key equipment/utensils are not stored in personal lockers.

Where a clear trend for L. monocytogenes isolations cannot be identified, typing can be useful to discriminate if the problem is a single plant persistent strain, or lots of different isolates. Further information on L. monocytogenes typing is available.

References

Jami, M., Ghanbari, M., Zunabovic, M., Domig, K.J. and Kneifel, W. (2014) Listeria monocytogenes in aquatic food products—A review. Comprehensive Reviews in Food Science and Food Safety 13, 798-813.

Overney, A., Jacques-Andre-Coquin, J., Ng, P., Carpentier, B., Guillier, L. and Firmesse, O. (2017) Impact of environmental factors on the culturability and viability of Listeria monocytogenes under conditions encountered in food processing plants. Int. J. Food Microbiol. 244, 74-81.

Spanu, C. and Jordan, K. (2020) Listeria monocytogenes environmental sampling program in ready-to-eat processing facilities: A practical approach. Comprehensive Reviews in Food Science and Food Safety 19, 2843-2861.