Improvements since 2000

​​​​​​The 2018 revision of the Australian and New Zealand Guidelines for Fresh and Marine Water Quality (ANZ Guidelines) is now an online platform. This is to improve usability and provide faster updates as new information becomes available.

Revisions to default guideline values (DGVs) since the ANZECC & ARMCANZ (2000) guidelines have been provided for the ‘aquatic ecosystem’ community value.

DGVs have been revised for physical and chemical (PC) stressors. This follows new knowledge, broader monitoring data collected since 2000, and an ecoregionalisation approach. More specific guidance is provided for temporary inland waters.

Additional and revised DGVs for some high priority toxicants are available.

For toxicants, the method for deriving DGVs was revised. It was then applied to update existing or derive new DGVs for many toxicants.  This included using more recent toxicity data.

Minor updates to the guidance for the ‘primary industry’ community value were made. They were based on a review of knowledge about livestock drinking water.

Sections dealing with recreational water and drinking water have been removed. The water quality and health guidelines are produced by the Australian Government National Health and Medical Research Council (NHMRC). In New Zealand, this guidance is provided by the Ministry for the Environment and the Ministry of Health.

Here we have outlined additional key changes made in revising the ANZ Guidelines.

Water Quality Management Framework

The basic Water Quality Management Framework by ANZECC & ARMCANZ (2000) has been expanded and emphasised.

Following the steps in the revised Water Quality Management Framework provides a logical approach to identifying and managing key water quality issues.

Water Quality Guidelines Improvement Program

The Water Quality Guidelines Improvement Program (WQGIP) was established in July 2020 by the National Water Committee (NWC). The WQGIP aims to keep the NWQMS and its guidelines up to date, useful and scientifically sound. The WQGIP operates on a rolling two to three-year program of activities. These are reviewed annually. They are implemented via a yearly work plan approved by the NWC and managed by DCCEEW.

A new five-year strategic plan is being developed. It will guide the ongoing use of the NWQMS.

The strategic plan is being developed in a two-stage process:

• Stage one involves working with stakeholders to identify strengths and weaknesses of the current WQGIP
• Stage two involves working with stakeholders to draft a five-year strategic plan for the ongoing revision of the WQGIP.

The report was undertaken by an independent reviewer and does not represent Government policy.

Stage one report: Analysis of the Australian and New Zealand Water Quality Guidelines Improvement Program

Final report and implementation plan: Australian and New Zealand Water Quality Strategies and Guidelines Continuous Improvement Program Strategic Plan and High-Level Implementation Plan

Transition from Burrlioz to shinyssdtools – improved software to derive water quality guideline values

The National Water Quality Management Strategy (NWQMS) governing committee, the Water Quality Policy Sub Committee (WQPSC), has agreed to the transition from the use of the Burrlioz software to the shinyssdtools software for deriving toxicant DGVs for the ANZ Guidelines.

Since 2000, DGVs (and site-specific guideline values) for toxicants in Australia and New Zealand have been derived using the Burrlioz species sensitivity distribution (SSD) software.  However, now a technically superior approach offered by the software tool, shinyssdtools, exists.

A key difference between Burrlioz and shinyssdtools is that the latter uses a process known as model averaging, where multiple distributions are used to estimate DGVs, whereas Burrlioz uses only a single distribution.

While Burrlioz is still a reliable approach, the transition to shinyssdtools represents a further improvement as part of the continual improvement philosophy of the ANZ Guidelines and the overall continual advancement in science and statistics.

shinyssdtools was origjnally developed in Canada. From 2019 to 2024, the Australian and Canadian governments funded refinements to shinyssdtools to further improve its statistical and functional underpinnings and to ensure it is fit-for-purpose for deriving DGVs for the ANZ Guidelines.

The advantages of shinyssdtools include:

• Ability to use model averaging for deriving DGVs for toxicants, resulting in more technically defensible DGVs
• The joint efforts with Canada will represent a significant step towards greater global harmonisation of water quality DGV derivation methods
• Credible and statistically defensible way of establishing maximum contaminant levels of toxicants in aquatic environments in the short to medium term.

The transition from Burrlioz software to shinyssdtools will be steadily progressed over the next few years. Decisions on retrospective application of shinyssdtools for existing GVs will be made as part of the project transition plan.

In the meantime there is still work to do to ensure that all the appropriate procedures, guidance and administrative arrangements are in place for shinyssdtools to be formally adopted for the derivation of DGVs for the ANZ Guidelines. In advance of the implementation of shinyssdtools, it will be important that information and guidance is provided to stakeholders and end-users so they are familiar with the new approach (model averaging). Users will need to know how to use the tool for ANZ Guidelines’ purposes, which will be accomplished as part of a currently in-progress update to the Warne et al. (2018) DGVs derivation method.

You can be kept informed of progress and key transition timeframes by subscribing to our newsletter.

More technical information on shinyssdtools can be found in the publications by Fox et al. (2021, 2022, 2023).

References

Fox DR, van Dam RA, Fisher R, Batley GE, Tillmans AR, Thorley J, Schwarz CJ, Spry DJ & McTavish K 2021. Recent developments in species sensitivity distribution modeling. Environmental Toxicology & Chemistry 40(2), 293-308.

Fox DR, Fisher R, Thorley JL & Schwarz C 2022. Joint Investigation into statistical methodologies underpinning the derivation of toxicant guideline values in Australia and New Zealand. Report prepared for the Department of Agriculture, Water and the Environment. Environmetrics Australia, Beaumaris, Vic and the Australian Institute of Marine Science, Perth, WA. 167 pp.

Fox D, van Dam R, Batley G, Fisher R & Thorley J 2023. Improved SSD software coming soon for the ANZG Guidelines. Australasian Bulletin of Ecotoxicology and Environmental Chemistry 9, 1-3.

Focus on typical uses

To assist the user, we give step-by-step guidance on how to apply the Water Quality Management Framework in a number of situations or typical uses.

• Developing a water quality management plan
• Applying for a development approval
• Assessing a waste discharge
• Investigating an unexpected event
• Assessing a remediation study (for sediments and waters)
• Conducting a baseline study
• Implementing a broadscale monitoring program

Guidance for each typical use is only provided to illustrate how to use the framework. You should adapt the framework to suit your specific application.

Weight-of-evidence process

Applying the ANZECC & ARMCANZ (2000) guidelines to the range of community values relied largely on a single line of evidence (chemical assessment) to determine whether or not a guideline value was exceeded.

The Water Quality Guidelines improve confidence in our assessments by:

• introducing a systematic approach to assessing a number of lines of evidence along the pressure–stressor–ecosystem receptors pathway
• promoting decisions on the basis of the integrated weight of evidence.

Learn more about weight of evidence.

Conceptual models

Natural systems are complex. To understand and manage them well, we can build conceptual models to show the current understanding of how the system works. This is an essential first step in the application of the Water Quality Management Framework.

Conceptual models can also be used when selecting indicators for water/sediment quality, and during system monitoring and assessment.

Develop and use conceptual models.

Your location (ecoregionalisation)

The simple ecoregionalisation in ANZECC & ARMCANZ (2000) has been extensively updated, based on improved ecosystem understanding.

Our ecoregionalisation approach is only used for the ‘aquatic ecosystems’ community value. We provide more relevant DGVs for PC stressors in each region, as well as more targeted and relevant biological assessment.

Australian and New Zealand users follow different approaches.

Refer to Your location.

Cultural and spiritual values

Water resources have important cultural and spiritual values, particularly for the indigenous peoples of Australia and New Zealand.

Incorporate cultural and spiritual values into water quality management.

References

ANZECC & ARMCANZ 2000, Australian and New Zealand Guidelines for Fresh and Marine Water Quality, Australian and New Zealand Environment and Conservation Council and Agriculture and Resource Management Council of Australia and New Zealand, Canberra.