Guidelines for Canadian drinking water quality boron: Rationale for maximum acceptable concentration

Guidelines for Canadian drinking water quality boron: Rationale for maximum acceptable concentration Boron can be present in drinking water supplies through weathering of boron-containing rocks and soils, seawater spray and volcanoes as well as from anthropogenic sources such as wastewater from municipal sewage treatment and industrial processes, pesticide application and other human activities. In most Canadian drinking water supplies, boron is below 0.1 mg/L. Higher concentrations of boron (1 mg/L to 8 mg/L) can be found in certain areas of Canada, particularly in groundwater supplies in areas with naturally occurring boron. The main source for Canadians' exposure to boron is through food, although consumer products can also contribute significantly to exposure. Exposure through drinking water can contribute up to 16% of total dietary exposure. Reproduction and development are considered to be the most sensitive health endpoints for boron toxicity. Studies in humans have found possible associations between boron and effects to reproduction and development. However, these have several design limitations and cannot be used for risk assessment. Studies in animals have consistently observed adverse effects to the male reproductive system following ingestion of high levels of boron, which supports effects seen in human studies. Testicular effects observed in dogs were the most sensitive endpoint and are used to establish the HBV of 0.1 mg/L. The guideline development process considers the ability to measure a contaminant in drinking water. There are several analytical methods available for the analysis of total boron in drinking water at concentrations below the HBV. The guideline development process also considers whether the maximum acceptable concentration (MAC) is practically achievable using current drinking water treatment technologies. For municipal-scale treatment plants, the 2 most effective and commonly used treatment technologies for boron removal are RO and IX using a boron selective resin. Data from treatment plants indicate that a treated water concentration at the HBV of 0.1 mg/L is not achievable for most systems. While IX with a boron selective resin may be theoretically capable of removing boron from drinking water to below 0.1 mg/L, the operating conditions that would be required would be extremely challenging and are not considered to be practical. In general, when source concentrations are 8 mg/L or less, treated water concentrations of less than 5 mg/L are achievable using RO and IX (with BSR) that have design and operating conditions for boron removal. 2024-06-28 Health Canada open-ouvert@tbs-sct.gc.ca Health and SafetyGuidelinesCanadiandrinking water qualityboronRationalefor maximum acceptableconcentrationThe guideline developmentprocess considersability to measurecontaminantin drinking waterdevelopmentprocessalso considerswhether themaximum acceptable concentration(MAC) practicallyachievableusing currentdrinking watertreatment technologies Guidelines for Canadian drinking water quality boron: Rationale for maximum acceptable concentrationHTML https://www.canada.ca/en/health-canada/services/publications/healthy-living/guidelines-canadian-drinking-water-quality-guideline-technical-document-boron/rationale-maximum-acceptable-concentration.html Guidelines for Canadian drinking water quality boron: Rationale for maximum acceptable concentrationHTML https://www.canada.ca/fr/sante-canada/services/publications/vie-saine/recommandations-pour-qualite-eau-potable-canada-document-technique-bore/justification-concentration-maximale-acceptable.html

Boron can be present in drinking water supplies through weathering of boron-containing rocks and soils, seawater spray and volcanoes as well as from anthropogenic sources such as wastewater from municipal sewage treatment and industrial processes, pesticide application and other human activities. In most Canadian drinking water supplies, boron is below 0.1 mg/L. Higher concentrations of boron (1 mg/L to 8 mg/L) can be found in certain areas of Canada, particularly in groundwater supplies in areas with naturally occurring boron. The main source for Canadians' exposure to boron is through food, although consumer products can also contribute significantly to exposure. Exposure through drinking water can contribute up to 16% of total dietary exposure.

Reproduction and development are considered to be the most sensitive health endpoints for boron toxicity. Studies in humans have found possible associations between boron and effects to reproduction and development. However, these have several design limitations and cannot be used for risk assessment. Studies in animals have consistently observed adverse effects to the male reproductive system following ingestion of high levels of boron, which supports effects seen in human studies. Testicular effects observed in dogs were the most sensitive endpoint and are used to establish the HBV of 0.1 mg/L.

The guideline development process considers the ability to measure a contaminant in drinking water. There are several analytical methods available for the analysis of total boron in drinking water at concentrations below the HBV.

The guideline development process also considers whether the maximum acceptable concentration (MAC) is practically achievable using current drinking water treatment technologies. For municipal-scale treatment plants, the 2 most effective and commonly used treatment technologies for boron removal are RO and IX using a boron selective resin. Data from treatment plants indicate that a treated water concentration at the HBV of 0.1 mg/L is not achievable for most systems. While IX with a boron selective resin may be theoretically capable of removing boron from drinking water to below 0.1 mg/L, the operating conditions that would be required would be extremely challenging and are not considered to be practical. In general, when source concentrations are 8 mg/L or less, treated water concentrations of less than 5 mg/L are achievable using RO and IX (with BSR) that have design and operating conditions for boron removal.

Data and Resources

Similar records