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Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities

Published online by Cambridge University Press:  24 January 2024

Michael De Coste
Affiliation:
Faculty of Applied Science, University of British Columbia Okanagan, Kelowna, BC, Canada
Sana Saleem
Affiliation:
Faculty of Applied Science, University of British Columbia Okanagan, Kelowna, BC, Canada
Haroon R. Mian*
Affiliation:
Faculty of Applied Science, University of British Columbia Okanagan, Kelowna, BC, Canada
Gyan Chhipi-Shrestha
Affiliation:
Faculty of Applied Science, University of British Columbia Okanagan, Kelowna, BC, Canada
Kasun Hewage
Affiliation:
Faculty of Applied Science, University of British Columbia Okanagan, Kelowna, BC, Canada
Madjid Mohseni
Affiliation:
Faculty of Applied Science, University of British Columbia, Vancouver, BC, Canada
Rehan Sadiq
Affiliation:
Faculty of Applied Science, University of British Columbia Okanagan, Kelowna, BC, Canada
*
Corresponding author: Haroon R. Mian; Email: [email protected]
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Abstract

Indigenous communities in Canada are disproportionately affected by issues related to water security, especially access to clean water to meet human needs. The issues these communities face are diverse and widespread across Canada, with many causes and consequences. This review summarizes the types and magnitudes of risks associated with the water security of these communities, the consequences considering health and social perspectives, and the means of responding to these issues. Risks are broadly divided into quantitative risks (e.g., water quality and availability) and qualitative risks (e.g., lack of funding and jurisdictional conflicts). These risks lead to unique consequences, resulting in challenges in developing generalized risk response frameworks. Management of these risks includes a mix of techniques relying on legislative and technical approaches. Nevertheless, the affected communities should be included in the decision-making process that should be holistic, incorporating indigenous knowledge. Good governance, cooperation between communities, policy improvement and the development of an institutional mechanism for clean water supply will provide a pathway and guidelines to address the water security challenges among indigenous communities.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Impact statement

This review focuses on assessing the key risks to water security faced by small, remote, indigenous communities throughout Canada. This assessment includes a discussion of these risks from a quantitative perspective, which are well-established risks to water quality, and a qualitative perspective, overviewing the risks from organizational or legislative standpoints that are often neglected or overlooked in studies of these communities. The outline of these factors provides important background to the types and severity of risks to the water security of these communities, with special attention paid to their potential impacts. This review also provides a framework for mitigating these risks and investigating reactive, proactive and governance-based response strategies. A policy of respectful cooperation and collaboration between communities, researchers and the government is identified as the most successful strategy in implementing risk mitigation strategies, providing a path to address these water security concerns in Canada and other colonial states.

Introduction

The concept of water security, describing the accessibility of an adequate amount of water of acceptable quality to ensure human health, is vital to the survival of Small, Remote, Indigenous (SRI) communities (Longboat, Reference Longboat2015). However, a lack of access to water to fulfill these needs is a persistent problem in many of these SRI communities throughout North America, stemming from various complex risks. The issues in Canada alone are diverse and widespread, with communities facing issues stemming from pollution, inadequate resources, aging infrastructure and a lack of training in water systems personnel (Hanrahan, Reference Hanrahan2017). Drinking water advisories, regulatory warnings that drinking water is unsafe to consume, are also common, with indigenous communities in Canada being 2.5 times more likely to face these issues than other communities of similar sizes and 70% of indigenous communities experiencing an advisory between 2004 and 2013 (Patrick, Reference Patrick2011; Lucier et al., Reference Lucier, Schuster-Wallace, Skead, Skead and Dickson-Anderson2020). Further disparities also exist within SRI communities, with older residents having higher difficulties accessing clean water and younger women, especially those with children, having higher difficulties accessing enough water (Duignan et al., Reference Duignan, Moffat and Martin-Hill2022). Operators of the water treatment systems within these communities often cite a lack of funding and support as crucial factors, resulting in an inability to adequately meet the demand for water within the communities (Murphy et al., Reference Murphy, Corston-Pine, Post and McBean2015). Many of these communities’ water treatment systems cannot meet the demand and face additional strains caused by nearby industries, development or tourism (Arsenault, Reference Arsenault2021). In some parts of Canada, as high as 19% of residents in some communities will go longer than 24 h without consuming water due to issues relating to taste and availability (Ratelle and Yakeleya, Reference Ratelle and Yakeleya2022). These issues are commonly encountered in other colonial states, with upwards of 194,000 citizens in communities in Australia with populations less than 1,000 reporting unhealthy water based on local guidelines (Wyrwoll et al., Reference Wyrwoll, Manero, Taylor, Rose and Grafton2022), while Indigenous households in the United States are 19 times more likely to lack sufficient indoor plumbing compared to White households (Wilson et al., Reference Wilson, Montoya, Arsenault and Curley2021).

Regulatory failures to achieve water security for these communities have been widespread and longstanding. These issues include the inability to provide adequate infrastructure, regulatory frameworks and prioritization of communities most in need, despite a now 45-year-old pledge by the Canadian federal government to provide sufficient drinking water to SRI communities (Boyd, Reference Boyd2011). Protocols developed by the federal government in response to the failure of water systems in 2000 in the community of Walkerton and subsequent deaths have been demonstrated to have failed a related community that has faced over 17 years of similar water issues (Chambers, Reference Chambers2017). Federal drinking water evaluation methods have also been challenged, with studies noting a narrow scope and a lack of consideration for socioeconomic factors that significantly impact the capacity of these communities to treat water effectively (Brown et al., Reference Brown, Wachowiak-Smolikova, Spence, Wachowiak and Walters2016). Media portrayals of water security issues within these communities are also often delayed compared to other crises within the country, with minimal coverage of Inuit and Metis communities. This coverage often focuses only on responses rather than attempts at mitigation (Lam et al., Reference Lam, Cunsolo, Sawatzky, Ford and Harper2017). Despite this, new federal legislation still presents the opportunity to provide self-governance, improved capacity for addressing emergencies, uniform standards and increased accountability. Recent achievements include lifting over 80% of long-term drinking water advisories (Willms and Shier, 2006; Indigenous Services Canada, 2023).

Water vulnerability within these communities is affected by various factors and can vary significantly between communities. As of 2011, roughly 1.5% of homes in Canadian indigenous communities had no direct water service, with 26.5% relying on individual wells or truck delivery, with 39% of these systems experiencing high risk of failure and 34% experiencing medium risk (Neegan Burnside Ltd., 2011). Recent progress has brought the current number of affected communities to 28 across Canada, with 32 long-term advisories in effect; however, this does not consider individual homes or communities of less than five houses (Indigenous Services Canada, 2023). Though many SRI communities have appropriate equipment and infrastructure for treating sufficient amounts of water, this equipment must be properly maintained and operated (Smith et al., Reference Smith, Guest, Svrcek and Farahbakhsh2005; Lucier et al., Reference Lucier, Dickson-Anderson, Skead, Skead, Kosmas and Schuster-Wallace2022). Though economic factors are prevalent drivers of water vulnerability, other factors such as availability, existing water quality, types of contaminants, community demographics and social engagement can vary from one community to the next, making the development of generalized approaches challenging (Plummer et al., Reference Plummer, de Grosbois, Armitage and de Loe2013). While source water planning has been proposed to address water quality concerns for some of these communities, for many of them, it is infeasible or does not address the actual issues at play, which are often tied to a lack of funding (Collins et al., Reference Collins, McGregor, Allen, Murray and Metcalfe2017). Within these communities, those citizens without access to running water and proper wastewater systems are 63% more likely to experience illness resulting in missed work or school, with an economic cost of over $100 million as a result of physician care, drug costs and the cost of lost production (O’Gorman and Penner, Reference O’Gorman and Penner2018). Given the complex nature of the state of SRI water security, this review seeks to summarize the critical risks to these communities from the standpoint of both quantitative and qualitative risks. The expected consequences of these risks are summarized, considering individual health impacts, societal costs and environmental impacts, and the current methods of addressing these risks are summarized. Findings of the most successful approaches are discussed. A collaborative stance between researchers, regulators and SRI community members is explored in depth as the path forward for managing these water security risks.

Risks to indigenous communities

Overview of risks

Though the risks facing indigenous communities are diverse and governed by a complex series of factors, they can broadly be categorized as either quantitative risks, those directly quantifiable, or qualitative risks, reflecting issues related to governance and management.

Quantitative risks

In water security, quantitative risks describe those risks to the systems that can be directly quantified and described, such as bacterial or chemical contaminant levels, quantities of clean water and the effects of distribution systems. The variety of potential risks from one community to another presents difficulties in generalizing studies of these issues; however, there are many commonalities in the quantitative risks these SRI communities face. Table 1 provides a summary of these common risk factors. A national analysis of Indigenous reserves in Canada has found that 43% of boil water advisories in affected communities result from unacceptable microbiological quality (Fernando et al., Reference Fernando, Tun, Poole, Patidar, Li, Mi, Amarawansha, Fernando, Khafipour, Farenhorst and Kumar2016). The high presence of bacteria in these waters increases vulnerability to the growth of antibiotic-resistant strains. Analysis of source water in one community found the presence of coliforms in many stages of the water distribution system, with 46 different bacterial phylae also present and antibiotic-resistant genes found in all source waters and several treatment stages (Fernando et al., Reference Fernando, Tun, Poole, Patidar, Li, Mi, Amarawansha, Fernando, Khafipour, Farenhorst and Kumar2016). A study of source water contamination within an Indigenous fly-in community found significant levels of fecal bacteria contamination, with water samples from homes serviced by cisterns, distribution trucks, and the community standpipe having unacceptable levels of E. coli contamination (Farenhorst et al., Reference Farenhorst, Li, Jahan, Tun, Mi, Amarkoon, Kumar and Khafipour2017). Though there have been many quantitative studies investigating the impacts of biological contaminants on the health of residents, there is a gap in the coordination of these studies and their consideration of health impacts (Bradford et al., Reference Bradford, Bharadwaj, Okpalauwaekwe and Waldner2016; Lane et al., Reference Lane, Trueman, Locsin and Gagnon2020; Hu et al., Reference Hu, Mian, Abedin, Li, Hewage and Sadiq2022; Khan et al., Reference Khan, Murdock, Mahmud, Cloutier, Benoit, Bashar, Patidar, Mi, Daneshfar, Farenhorst and Kumar2022). The most common health issue assessed from these quantitative studies of water contamination was gastrointestinal issues, with these studies generally limited to single communities (Bradford et al., Reference Bradford, Bharadwaj, Okpalauwaekwe and Waldner2016).

Table 1. Assessment of common quantitative risks and their levels of severity

Chemical contamination is another common risk to these systems, with the types of contaminants also varying vastly from community to community (Hu et al., Reference Hu, Mian, Dyck, Mohseni, Jasim, Hewage and Sadiq2020). A study of 47 communities in Atlantic Canada assessed vulnerability to lead, manganese and arsenic contamination from 12 years of sampling data. Elevated concentrations were found of each contaminant in several communities (with some exceeding regulatory guidelines by up to 100%), and many communities also had issues with sampling frequency, leading to some contaminants being underreported (Lane et al., Reference Lane, Trueman, Locsin and Gagnon2020). A study of 91 indigenous communities south of the 60th parallel investigated the presence of metal contaminants, with samples taken from 1,516 households. Exceedances of the maximum acceptable concentration of five metals were discovered, with up to 8.4% of households exceeding the maximum acceptable lead concentration and exceedances of proposed operational guidelines of many other metal contaminants reported (Schwartz et al., Reference Schwartz, Marushka, Chan, Batal, Sadik, Ing, Fediuk and Tikhonov2021a). A similar study investigated the presence of pharmaceutical contaminants in surface water samples from 95 indigenous communities throughout Canada. 83% of the participating communities were found to have quantifiable levels of 35 different pharmaceutical contaminants, with 68% of the chosen surface water sampling locations demonstrating contamination (Schwartz et al., Reference Schwartz, Marushka, Chan, Batal, Sadik, Ing, Fediuk and Tikhonov2021b). Disinfection by-products (DBPs), contaminants introduced by the water treatment process, were discovered in the water systems of 22 communities in Quebec. Six unique DBPs were found, with maximum contamination levels of 635 μg/L (Mian et al., Reference Mian, Hu, Hewage, Rodriguez and Sadiq2021).

The causes and subsequent severity of these risks are governed by the community’s location and the water distribution system the community employs. Environmental drivers of contamination risk to water wells in an Albertan Indigenous community were investigated, finding that bacterial counts peaked roughly 2–4 months following yearly precipitation and overland flow peaks (Mah et al., Reference Mah, Hnidan, Davies and Ulrich2018). More remote northern Indigenous reserves in Saskatchewan were found to have a drinking water advisory count five times greater than reserves in the south and two times as many advisories as villages in the north (McLeod et al., Reference McLeod, Bharadwaj, Daigle, Waldner and Bradford2020). Many indigenous communities rely on a water truck-to-water cistern method of water distribution. However, this method is highly susceptible to contamination from bacteria. A study of 142 households in Saskatchewan using this system found that summer months increased coliform contamination risk in cisterns by up to 7 folds (Bradford et al., Reference Bradford, Waldner, McLaughlin, Zagozewski and Bharadwaj2018). In two indigenous communities in Manitoba, Campylobacter was detected in 68% of source water samples, with samples taken from homes using fiberglass cisterns or the community standpipe having a 100% detection rate, in comparison to 43% and 20% for piped water and water trucks (Khan et al., Reference Khan, Murdock, Mahmud, Cloutier, Benoit, Bashar, Patidar, Mi, Daneshfar, Farenhorst and Kumar2022). Roughly 31% of the homes in an Indigenous reserve in Manitoba rely on a truck-to-cistern delivery system for supplying water, with levels of contamination that are significantly higher and more frequent (Amarawansha et al., Reference Amarawansha, Zvomuya and Farenhorst2021). A survey of six Indigenous prairie communities identified household water cisterns as the highest risk (Baijius and Patrick, Reference Baijius and Patrick2019).

Qualitative risks

Qualitative risks (for instance, funding, regulation and training) are also very common to the water security of SRI communities. However, more attention has often been given to quantitative issues, with qualitative concerns neglected. These risks can impact all aspects of the water treatment systems of these communities, outlined in Figure 1. Indigenous communities’ qualitative issues should be examined in more detail to overcome the constant risk of water system failure. Most studies consider individual and typical qualitative issues in specific geographical contexts. The most common qualitative risks faced by indigenous communities are jurisdictional conflicts (Marshall et al., Reference Marshall, Desjardine, Levison, Anderson and McBean2020), lack of consultation and participation on the policy level (Latchmore et al., Reference Latchmore, Schuster-Wallace, Longboat, Dickson-Anderson and Majury2018), limitations in funding and capacity (Marshall et al., Reference Marshall, Desjardine, Levison, Anderson and McBean2020), absence of regulatory frameworks (Simms et al., Reference Simms, Harris, Joe and Bakker2016) and retention of qualified operators (Reading et al., Reference Reading, Perron, Marsden, Edgar, Saravana-Bawan and Baba2011).

Figure 1. Flow diagram of water treatment with key qualitative risks at each stage.

Mascarenhas (Reference Mascarenhas2007) researched Six First Nation Communities in southwestern Ontario and highlighted governance factors affecting the health and welfare of communities. The University of Victoria also investigated the water systems of indigenous communities, identifying technical and financial challenges affecting water services. Additionally, conflicting responsibility, new regulations and other operational factors were identified as critical (Reading et al., Reference Reading, Perron, Marsden, Edgar, Saravana-Bawan and Baba2011).

McCullough and Farahbakhsh (Reference McCullough and Farahbakhsh2012) interviewed 16 indigenous communities in Ontario to identify the challenges behind the water system failure. Regulatory framework issues, infrastructure gaps and organizational capacities were highlighted, with indigenous communities being burdened by colonial history and facing jurisdictional issues. Bradford et al. (Reference Bradford, Bharadwaj, Okpalauwaekwe and Waldner2016) conducted a scoping review and found that uncertain water provision, funding delays and lack of framework further exacerbate management and infrastructural challenges in the water systems of the indigenous communities. BC Ministry of Health (2016) provided an update on the progress made in drinking water protection in BC. They highlighted challenges such as recruiting and retaining qualified staff, lack of public consultation and permission process and economic struggles as factors affecting service delivery. McFarlane and Harris (Reference McFarlane and Harris2018) reviewed the academic literature on the governance of small drinking water systems and identified high levels of non-compliance in operations and slow developments in addressing water system and infrastructure issues.

Marshall et al. (Reference Marshall, Desjardine, Levison, Anderson and McBean2020) highlighted the issues faced by the indigenous communities with a partnership with an Anishinaabe community in southern Ontario. They identified jurisdictional issues leading to SRI communities being underrepresented as stakeholders with the same rights and considerations as other groups and a lack of funding and capacity impacting the water system of indigenous communities.

Impacts to indigenous communities

The relationships between economies, societies and ecosystems are complex and diverse, especially as they relate to the Sustainable Development Goal of clean water and sanitation (DeWit et al., Reference DeWit, Lawson-Johns, Lottner and Guinchard2023). The impacts of the aforementioned risks, much like the risks themselves, are also diverse and vary based on various circumstances. These impacts can broadly be divided into health, societal and environmental categories.

Health impacts

The impacts of a lack of good quality running water have been investigated from a physical and mental health standpoint. The availability of running water has been associated with an 80% decrease in the odds of reporting depression while functioning wastewater systems halve the odds of gastrointestinal illness (O’Gorman, Reference O’Gorman2021). Interviews with communities in Alberta and the Northwest Territories found that ≈ 82% of respondents relied on bottled water rather than locally available tap water as their primary water source, with health and ease of access cited as the primary reason for this preference and significant gender discrepancies present in the responses to both queries (Spicer et al., Reference Spicer, Parlee, Cisaakay and Lamalice2020). Likewise, a study in Ontario analyzed perceptions of water safety in five communities, finding that Indigenous community residents were two times as likely to rely on bottled water and four times more likely to report illness from tap water (Dupont et al., Reference Dupont, Waldner, Bharadwaj, Plummer, Carter, Cave and Zagozewski2014). Community surveys with other indigenous communities in Ontario yielded similar insight into perceptions of water safety. Between 8 and 61% of respondents, depending on the community, would follow drinking water advisory guidelines, with access to safe water during advisories being rated as inadequate to very inadequate (Baird et al., Reference Baird, Plummer, Dupont and Carter2015). Risk perception was analyzed in two Saskatchewan communities, finding that while drinking water health standards were exceeded for most communities, there was no association between this factor and risk perception (Ford et al., Reference Ford, Waldner, Sanchez and Bharadwaj2019).

Societal impacts

The aforementioned drinking water advisories are one of the most common means of reacting to the discovery of low or inadequate water quality, with boil water or do-not-consume advisories being widespread across the country. Though these can be effective in the short term, they carry their own impacts on SRI communities. A series of surveys and interviews were conducted to investigate the effectiveness of drinking water advisories in Ontario. There was a high degree of uncertainty regarding the proper protective actions to be undertaken during the advisories, with 79% of male respondents and 46% of female respondents indicating adherence to advisory guidelines (Lucier et al., Reference Lucier, Schuster-Wallace, Skead, Skead and Dickson-Anderson2020). An analysis of the trends in drinking water advisories in Ontario during the 10 years from 2004 to 2013 found that the advisories are becoming more common and longer. These advisories most commonly occurred in summer months and were linked to equipment malfunctions, which could be mitigated through additional operator training (Galway, Reference Galway2016). These advisories have also been found to result in significant disparities in the availability of “good” drinking water generationally and by gender. A study of the Six Nations of the Grand River in Ontario found that the younger generations were more dissatisfied with water quality. Women within the communities often had challenges obtaining adequate clean water (Duignan et al., Reference Duignan, Moffat and Martin-Hill2022).

Environmental impacts

Detailed linkages have also been drawn between the declining health of nearby waterways due to misuse and pollution and the strain on the water treatment systems within many communities, revealing distinct impacts on food sources, community health and community activity (Lucier et al., Reference Lucier, Dickson-Anderson, Skead, Skead, Kosmas and Schuster-Wallace2022). Federal policies and programs addressing water health have been noted for their inflexibility and gaps in execution. Often, these policies are too generalized, resulting in low engagement and a lack of consideration for community heterogeneity (McCullough and Farahbakhsh, Reference McCullough and Farahbakhsh2012; Spicer et al., Reference Spicer, Parlee, Cisaakay and Lamalice2020). Simplistic and overgeneralized approaches to framing water issues were also cited as a concern in managing water security for indigenous communities in an analysis of the 2001 Aboriginal Peoples Survey (Spence and Walters, Reference Spence and Walters2012).

Risk response and mitigation roadmap

A framework for responding to water security risks can be divided into three categories: reactive responses addressing existing risks, proactive responses addressing recurrence and governance and management strategies to prevent risks.

Phase 1: Risk response strategies

Reactive strategies to water security risks are widespread, with the application of drinking water advisories to SRI communities being widespread. A probabilistic analysis identified the key drivers of drinking water advisories considering data sourced from 1,167 historical advisories across Canada. Occurrence and frequency were influenced by water source type and location, duration was influenced by system age and operator training, and the cause was primarily influenced by system age (Post et al., Reference Post, McBean and Gharabaghi2018). A database of drinking water advisories throughout Ontario was also used as the basis of a decision tree classifier to predict the drivers of these advisories. It was found that insufficient or no training of operators was an indicator in over 50% of the advisories considered, and the usage of groundwater wells and the age and number of people served by the system increased the likelihood of advisories (Harvey et al., Reference Harvey, Murphy, McBean and Gharabaghi2015).

Short-term responses to these risks include risk assessments, with many well-established techniques allowing risks to water treatment and distribution to be identified (Mpindou et al., Reference Mpindou, Bueno and Ramon2022). The available water system services methods for assessing biotic and abiotic elements of a drinking water source were compiled, showing how these services can be assessed for risks and subsequently improved (Gartner et al., Reference Gartner, Lindhe, Wahtra, Soderqvist, Lang, Nordzell, Norman and Rosen2022). Direct consultation with indigenous communities was used as the basis of a risk assessment tool outlining the most common risks present to the water delivery system in six communities in Atlantic Canada. This tool produces intuitive results to prioritize the most significant risks to the systems and suggests means to address them while demonstrating the value of direct consultation with indigenous communities (Lane et al., Reference Lane, Fuller, Dyment and Gagnon2022). Similar techniques were used to assess hazards within Indigenous wastewater systems, developing a sanitation safety plan as an alternative to current regulatory approaches to wastewater hazards (Lane et al., Reference Lane, Fuller, Stanhope and Stoddart2021). Responses from 54 communities were used to evaluate the effectiveness of new risk-level guidelines in Ontario indigenous communities. It was found that based on these guidelines, all of the communities were considered low risk, even though there was variable capacity for drinking water in each, indicating a need to explore other potential underlying factors of these risks (Walters et al., Reference Walters, Spence, Kuikman and Singh2012).

Phase 2: Proactive risk mitigation strategies

Prevention of the conditions leading to water insecurity is a practical next step, with source water protection, water safety plans and water sharing agreements providing more reliable water sources for communities; however, limits exist to the effectiveness of these techniques. Source water protection programs in Canada and the United States have been reviewed, focusing on previously published literature. It was found that many of these studies fail to recognize the indigenous communities as anything more than stakeholder groups, as opposed to rightsholders, relying little on their traditional knowledge and management and having minimal involvement from local elders and knowledge keepers (Marshall et al., Reference Marshall, Levison, McBean, Brown and Harper2018). A water protection program was implemented with direct consultation with an Indigenous community, using the concept of the Medicine Wheel in combination with qualitative data analysis techniques. The resulting source water protection framework identified apparent issues of concern with policy and funding and indicated a need for better risk assessment tools implementable by the communities (Marshall et al., Reference Marshall, Desjardine, Levison, Anderson and McBean2020). Following a detailed consultation between community members and researchers, traditional knowledge has also been implemented to protect source water. Community members’ assessments of risks to the water system components were used to identify management actions to mitigate risks throughout the water treatment process, identifying key bodies responsible for management while reclaiming indigenous planning methods (Patrick et al., Reference Patrick, Grant and Bharadwaj2019).

Given the growing scarcity of water resources in many remote indigenous communities in Canada, the United States and Australia, the application of water sharing in a “just” manner has been posited to ensure equal access to these resources (GCEW, 2023). Using water systems data from 804 indigenous communities, two probit models were developed to find that an Indigenous community’s participation in a water-sharing agreement will reduce the likelihood of boil water advisories (Lipka and Deaton, Reference Lipka and Deaton2015). Though water-sharing agreements have successfully alleviated some water security concerns, they are unreliable. Similarly, significant shortcomings were present in funding security, rate negotiations and the presence of clauses allowing unilateral discontinuation of service to indigenous communities by the source municipality (Huo et al., Reference Huo, Charbonneau and Alcantara2022). An analysis of 419 communities in Ontario, including 118 indigenous communities, investigated the effectiveness of water-sharing agreements between remote communities. The results indicated a distinct lack of participation of indigenous communities in water-sharing agreements (Deaton and Lipka, Reference Deaton and Lipka2021).

Phase 3: Water governance and management frameworks

Oxford’s REACH program highlights assessment, reporting and management, including community acceptance and applicability, as key elements of risk-based approaches to water safety issues (Charles et al., Reference Charles, Nowicki, Armstrong, Hope, McNicholl and Nilsson2023). Water management strategies combining legislative or management frameworks and self-governance can be a practical regulatory step in achieving water security. These management frameworks can incorporate proactive and reactive risk management, monitoring and assessing qualitative and quantitative risks (Wilson, Reference Wilson, Harris, Joseph-Rear, Beaumont and Satterfield2019). Some indigenous communities in Saskatchewan were asked to self-report the health effects of tap water to promote awareness and participation. Adverse effects were reported in 28% of these households, with concerns about environmental factors affecting water quality, insufficient access to drinking water and water avoidance or dissatisfaction being common (Waldner et al., Reference Waldner, Alimezelli, McLeod, Zagozewski, Bradford and Bharadwaj2017). These management frameworks can be implemented in terms of community-based research labs, collective and traditional knowledge in developing water policy research, and reciprocal learning methods to encourage the decolonization of water (Arsenault et al., Reference Arsenault, Diver, McGregor, Witham and Bourassa2017). Establishing generalized management frameworks by combining scientific knowledge, available practices and traditional knowledge will ensure equitable contributions from community members, effective operations of SRI water systems and low human health and environmental risks (Alcantara et al., Reference Alcantara, Longboat and Vanhooren2020). Thus, they can assist in developing pathways toward a holistic water management approach for indigenous communities (McGregor, Reference McGregor2014). Furthermore, developed management frameworks can be adaptive to local water safety plans with an emphasis on the success of the bottom-up approach (Black and McBean, Reference Black and McBean2017).

Management frameworks can integrate different index and footprint-based approaches to bring a lens of quantitative risk and evaluate the performance of SRI water systems. These approaches facilitate summarizing and communicating complex water quality data to the broad community (Lumb et al., Reference Lumb, Halliwell and Sharma2006; Mian et al., Reference Mian, Hu, Hewage, Rodriguez and Sadiq2021). Continuous application and testing of proposed management frameworks will facilitate the decision-maker in collecting comprehensive data on qualitative and quantitative risks (Morrison et al., Reference Morrison, Bradford and Bharadwaj2015). This enables the establishment of robust ethical and legal frameworks to strengthen ties between water security, biodiversity and social and cross-cultural factors (Matsui, Reference Matsui2012). The proposed management frameworks can be generalized to address water security issues among indigenous communities through the application of Indigenous water relations for a more holistic approach, understanding of colonial politics as a root cause of insecurity, and applications of a “two-eyed seeing” approach against more common integration of Western and Indigenous approaches. (Wilson et al., Reference Wilson, Harris, Joseph-Rear, Beaumont and Satterfield2019). Also referred to as “braiding,” the application of these principles can ensure equity, accessibility and usability for Indigenous community members while centering their voices in the collaboration (Mehltretter et al., Reference Mehltretter, Longboat, Luby and Bradford2023).

Conclusions

The risks to water security within SRI communities are diverse and widespread. Though they can be sorted into categories of qualitative and quantitative risks, it is difficult to generalize these risks due to the variety of issues these communities face that are unique to factors such as location, climate, remoteness, proximity to developments and governance. Because of this, attempts at creating blanket solutions through regulation or technical research are often unsuccessful as they fail to address the unique needs of the communities and rely on a unilateral approach. The solution to these issues lies in respectful collaboration with SRI communities, including implementing facets of traditional Indigenous knowledge in research and involving communities in the regulatory process, ensuring true collaboration. The “braiding” of these differing approaches to knowledge provides insight to practitioners while offering a means for decolonization efforts. Through this, a pathway to water security for SRI communities in North America can be charted, ensuring that the needs of these communities now and in the future are satisfied.

Open peer review

To view the open peer review materials for this article, please visit http://doi.org/10.1017/wat.2024.3.

Acknowledgments

The authors thank RESEAU Centre for Mobilizing Innovation and Mitacs for providing the financial support to mobilize this research.

Author contribution

Conceptualization: M.D.C., S.S., H.R.M.; Investigation: M.D.C., S.S., H.R.M.; Project administration: G.C.-S., R.S.; Supervision: K.H., M.M., R.S.; Visualization: M.D.C., S.S., H.R.M.; Writing – original draft: M.D.C., S.S., H.R.M.; Writing – review and editing: M.D.C., H.R.M., G.C.-S., K.H., M.M., R.S.

Competing interest

The authors declare none.

References

Alcantara, C, Longboat, S and Vanhooren, S (2020) Improving first nations water security through governance. Canadian Public Administration 63(2), 155176.Google Scholar
Amarawansha, GEA, Zvomuya, F and Farenhorst, A (2021) Water delivery system effects on coliform bacteria in tap water in first nations reserves in Manitoba, Canada. Environmental Monitoring and Assessment 193, 339.Google Scholar
Arsenault, R (2021) Water insecurity in Ontario first nations: An exploratory study on past interventions and the need for indigenous water governance. Water 13, 717.Google Scholar
Arsenault, R, Diver, S, McGregor, D, Witham, A and Bourassa, C (2017) Shifting the framework of Canadian water governance through indigenous research methods: Acknowledging the past with an eye to the future. Water 10, 49.Google Scholar
Baijius, W and Patrick, RJ (2019) “We don’t drink the water here”: The reproduction of undrinkable water for first nations in Canada. Water 11, 1079.CrossRefGoogle Scholar
Baird, J, Plummer, R, Dupont, D and Carter, B (2015) Perceptions of water quality in first nations communities: Exploring the role of context. Nature and Culture 10(2), 225249.Google Scholar
BC Ministry of Health (2016) Clean, safe, and reliable drinking water.Google Scholar
Black, K and McBean, E (2017) First nations’ water sustainability and security strategy: Tools and methodologies for community-driven processes for water treatment in indigenous communities. Technology in Society 50, 5765.Google Scholar
Boyd, DR (2011) No taps, no toilets: First nations and the constitutional right to water in Canada. McGill Law Journal 57, 81134.Google Scholar
Bradford, L, Bharadwaj, L, Okpalauwaekwe, U and Waldner, C (2016) Drinking water quality in indigenous communities in Canada and health outcomes: A scoping review. International Journal of Circumpolar Health 75, 32336.Google Scholar
Bradford, L, Waldner, C, McLaughlin, K, Zagozewski, R and Bharadwaj, L (2018) A mixed-method examination of risk factors in the truck-to-cistern drinking water system on the Beardy’s and Okemasis first nation reserve, Saskatchewan. Canadian Water Resources Journal 43(4), 383400.Google Scholar
Brown, B, Wachowiak-Smolikova, R, Spence, ND, Wachowiak, MP and Walters, DF (2016) Why do some first nations communities have safe water and others not? Socioeconomic determinants of drinking water risk. Global Journal of Health Science 8(9), 99106.Google Scholar
Chambers, L (2017) Boil-water advisories and federal (in)action: The politics of potable water in Pikangikum first nation. Journal of Canadian Studies 51(2), 289310.Google Scholar
Charles, K, Nowicki, S, Armstrong, A, Hope, R, McNicholl, D and Nilsson, K (2023) Results-Based Funding for Safe Drinking Water Services: How a Standard Contract Design with Payment for Results can Accelerate Safe Drinking Water Services at Scale. REACH Working Paper 13. Oxford: University of Oxford and Uptime Global.Google Scholar
Collins, L, McGregor, D, Allen, S, Murray, C and Metcalfe, C (2017) Source water planning for Ontario first nations communities: Case studies identifying challenges and outcomes. Water 9, 550.Google Scholar
Deaton, BJ and Lipka, B (2021) The provision of drinking water in first nations communities and Ontario municipalities: Insight into the emergence of water sharing arrangements. Ecological Economics 189, 107147.Google Scholar
DeWit, W, Lawson-Johns, J, Lottner, F and Guinchard, J (2023) High Cost of Cheap Water: The True Value of Water and Freshwater Ecosystems to People and Planet. A Report for WWF by Dalberg.Google Scholar
Duignan, S, Moffat, T and Martin-Hill, D (2022) Be like the running water: Assessing gendered and age-based insecurity experiences with six nations first nation. Social Science and Medicine 298, 114864.Google Scholar
Dupont, D, Waldner, C, Bharadwaj, L, Plummer, R, Carter, B, Cave, K and Zagozewski, R (2014) Drinking water management: Health risk perceptions and choices in first nations and non-first nations communities in Canada. Environmental Research and Public Health 11, 58895903.Google Scholar
Farenhorst, A, Li, R, Jahan, M, Tun, HM, Mi, R, Amarkoon, I, Kumar, A and Khafipour, E (2017) Bacteria in drinking water sources of a first nation reserve in Canada. Science of the Total Environment 575, 813819.Google Scholar
Fernando, D, Tun, HM, Poole, J, Patidar, R, Li, R, Mi, R, Amarawansha, GEA, Fernando, WGD, Khafipour, E, Farenhorst, A and Kumar, A (2016) Detection of antibiotic resistance genes in source and drinking water samples from a first nations community in Canada. Applied and Environmental Microbiology 82, 47674775.Google Scholar
Ford, L, Waldner, C, Sanchez, J and Bharadwaj, L (2019) Risk perception and human health risk in rural communities consuming unregulated well water in Saskatchewan, Canada. Risk Analysis 39(11), 2559.Google Scholar
Galway, LP (2016) Boiling over: A descriptive analysis of drinking water advisories in first nations communities in Ontario, Canada. Environmental Research and Public Health 13, 505.Google Scholar
Gartner, N, Lindhe, A, Wahtra, J, Soderqvist, T, Lang, L, Nordzell, H, Norman, J and Rosen, L (2022) Integrating ecosystem services into risk assessments for drinking water protection. Water 14, 1180.Google Scholar
GCEW (2023) The What, Why and How of the World Water Crisis: Global Commission on the Economics of Water Phase 1 Review and Findings. Paris: Global Commission on the Economics of Water.Google Scholar
Hanrahan, M (2017) Water (in)security in Canada: National identity and the exclusion of indigenous peoples. British Journal of Canadian Studies 30(1), 69.Google Scholar
Harvey, R, Murphy, HM, McBean, EA and Gharabaghi, B (2015) Using data mining to understand drinking water advisories in small water systems: A case study of Ontario first nations drinking water supplies. Water Resource Management 29, 51295139.Google Scholar
Hu, G, Mian, HR, Abedin, Z, Li, J, Hewage, K and Sadiq, R (2022) Integrated probabilistic-fuzzy synthetic evaluation of drinking water quality in rural and remote communities. Journal of Environmental Management 301, 113937.Google Scholar
Hu, G, Mian, HR, Dyck, R, Mohseni, M, Jasim, S, Hewage, K and Sadiq, R (2020) Drinking water treatments for arsenic and manganese removal and health risk assessment in white rock, Canada. Exposure and Health 12, 793807.Google Scholar
Huo, C, Charbonneau, P and Alcantara, C (2022) Overcoming barriers to indigenous-local water sharing agreements in Canada. Canadian Public Administration 65(3), 421.Google Scholar
Indigenous Services Canada (2023) Ending long-term drinking water advisories. Government of Canada. Available at https://www.sac-isc.gc.ca/eng/1506514143353/1533317130660. (accessed March 16, 2023).Google Scholar
Khan, IUH, Murdock, A, Mahmud, M, Cloutier, M, Benoit, T, Bashar, S, Patidar, R, Mi, R, Daneshfar, B, Farenhorst, A and Kumar, A (2022) Quantitative assessment of first nations drinking water distribution for detection and prevalence of thermophilic campylobacter species. Environmental Research and Public Health 19, 10466.Google Scholar
Lam, S, Cunsolo, A, Sawatzky, A, Ford, J and Harper, SL (2017) How does the media portray drinking water security in indigenous communities in Canada? An analysis of Canadian newspaper coverage from 2000-2015. BMC Public Health 17, 282.Google Scholar
Lane, K, Fuller, M, Dyment, T and Gagnon, G (2022) Co-development of a risk assessment tool for use in first nations water supply systems: A key step to water safety plan implementation. International Journal of Hygiene and Environmental Health 240, 113916.Google Scholar
Lane, K, Fuller, M, Stanhope, T and Stoddart, A (2021) Exploring the use of a sanitation safety plan framework to identify key hazards in first nations wastewater systems. Water 13, 1454.Google Scholar
Lane, K, Trueman, BF, Locsin, J and Gagnon, GA (2020) Inorganic contaminants in Canadian first nation community water systems. Journal of Water and Health 18(5), 728740.Google Scholar
Latchmore, T, Schuster-Wallace, CJ, Longboat, DR, Dickson-Anderson, SE and Majury, A (2018) Critical elements for local indigenous water security in Canada: A narrative review. Journal of Water and Health 16(6), 893903. https://doi.org/10.2166/wh.2018.107.Google Scholar
Lipka, B and Deaton, BJ (2015) Do water service provision contracts with neighbouring communities reduce drinking water risk on Canadian reserves? Water Resources and Economics 11, 2232.Google Scholar
Longboat, S (2015) First nations water security: Security for mother earth. Canadian Woman Studies 30(2,3), 613.Google Scholar
Lucier, KJ, Dickson-Anderson, SE, Skead, D, Skead, K, Kosmas, E and Schuster-Wallace, C (2022 ) ‘That water out there is no damn good for anybody’: Experiences with declining water quality in a First Nation community. Canadian Water Resources Journal 48, 18.Google Scholar
Lucier, KJ, Schuster-Wallace, CJ, Skead, D, Skead, K and Dickson-Anderson, SE (2020) “Is there anything good about a water advisory?”: An exploration of the consequences of drinking water advisories in an indigenous community. BMC Public Health 20, 1704.Google Scholar
Lumb, A, Halliwell, D and Sharma, T (2006) Application of CCME water quality index to monitor water quality: A case of the Mackenzie River Basin, Canada. Environmental Monitoring and Assessment 113, 411429.Google Scholar
Mah, F, Hnidan, T, Davies, E and Ulrich, A (2018) Environmental risk factors for bacteriological contamination in rural drinking water wells in Samson Cree Nation. Canadian Journal of Civil Engineering 45, 99104.Google Scholar
Marshall, R, Desjardine, M, Levison, J, Anderson, K and McBean, E (2020) Moving towards effective first nations’ source water protection: Barriers, opportunities, and a framework. Water 12, 2957.CrossRefGoogle Scholar
Marshall, RE, Levison, JK, McBean, EA, Brown, E and Harper, SL (2018) Source water protection programs and indigenous communities in Canada and the United States. Journal of Hydrology 562, 358370.Google Scholar
Mascarenhas, M (2007) Where the waters divide: First nations, tainted water and environmental justice in Canada. Local Environment 12(6), 565577. https://doi.org/10.1080/13549830701657265.Google Scholar
Matsui, K (2012) Water ethics for first nations and biodiversity in Western Canada. The International Indigenous Policy Journal 3(3), 125.Google Scholar
McCullough, J and Farahbakhsh, K (2012) Square peg, round hole: First nations drinking water infrastructure and federal policies, programs and processes. The International Indigenous Policy Journal 3(1), 3.Google Scholar
McFarlane, K and Harris, LM (2018) Small systems, big challenges: Review of small drinking water system governance. Environmental Reviews 26(4), 378395. https://doi.org/10.1139/er-2018-0033.Google Scholar
McGregor, D (2014) Traditional knowledge and water governance. AlterNative 10(5), 494507.Google Scholar
McLeod, L, Bharadwaj, LA, Daigle, J, Waldner, C and Bradford, LEA (2020) A quantitative analysis of drinking water advisories in Saskatchewan indigenous and rural communities 2012–2016. Canadian Water Resources Journal 45(4), 345357.Google Scholar
Mehltretter, S, Longboat, S, Luby, B and Bradford, A (2023) Indigenous and Western Knowledge: Bringing Diverse Understandings of Water Together in Practice. Paris: Technical Report for the Global Commission on the Economics of Water.Google Scholar
Mian, HR, Hu, G, Hewage, K, Rodriguez, MJ and Sadiq, R (2021) Drinking water quality assessment in distribution networks: A water footprint approach. Science of the Total Environment 775, 145844.Google Scholar
Morrison, A, Bradford, L and Bharadwaj, L (2015) Quantifiable progress of the first nations water management strategy, 2001-2013: Ready for regulation? Canadian Water Resources Journal 40(4), 352372.Google Scholar
Mpindou, GOMK, Bueno, IE and Ramon, EC (2022) Risk analysis method of water supply systems: Comprehensive review from sources to tap. Applied Water Science 12, 56.Google Scholar
Murphy, HM, Corston-Pine, E, Post, Y and McBean, EA (2015) Insights and opportunities: Challenges of Canadian first nations drinking water operators. The International Indigenous Policy Journal 6(3), 7.Google Scholar
Neegan Burnside Ltd (2011) National Assessment of First Nations Water and Wastewater Systems: National Roll-up Report Final. Prepared for Department of Indian and Northern Affairs Canada.Google Scholar
O’Gorman, M (2021) Mental and physical health impacts of water/sanitation infrastructure in first nations communities in Canada: An analysis of the regional health survey. World Development 145, 105517.Google Scholar
O’Gorman, M and Penner, S (2018) Water infrastructure and well-being among first nations, metis and Inuit individuals in Canada: What does the data tell us? Environmental Science and Pollution Research 25, 3303833055.Google Scholar
Patrick, RJ (2011) Uneven access to safe drinking water for first nations in Canada: Connecting health and place through source water protection. Health & Place 17, 386389.Google Scholar
Patrick, RJ, Grant, K and Bharadwaj, L (2019) Reclaiming indigenous planning as a pathway to local water security. Water 11, 936.Google Scholar
Plummer, R, de Grosbois, D, Armitage, D and de Loe, RC (2013) An integrative assessment of water vulnerability in first nation communities in southern Ontario, Canada. Global Environmental Change 23, 749763.Google Scholar
Post, YL, McBean, E and Gharabaghi, B (2018) Using probabilistic neural networks to analyze first nations’ drinking water advisory data. Water Resources Planning and Management 144(11), 05018015.Google Scholar
Ratelle, M and Yakeleya, J (2022) Living water, northern indigenous communities’ use and perceptions of drinking water. The Conversation, 181238.Google Scholar
Reading, J, Perron, D, Marsden, N, Edgar, R, Saravana-Bawan, B and Baba, L (2011) Crisis on tap : Seeking solutions for safe water for indigenous peoples. Available at http://ir.lib.uwo.ca/cgi/viewcontent.cgi?article=1233&context=aprci%5Cnhttp://ir.lib.uwo.ca/aprci/211.Google Scholar
Schwartz, H, Marushka, L, Chan, HM, Batal, M, Sadik, T, Ing, A, Fediuk, K and Tikhonov, C (2021a) Metals in the drinking water of first nations across Canada. Canadian Journal of Public Health 112, 51135132.Google Scholar
Schwartz, H, Marushka, L, Chan, HM, Batal, M, Sadik, T, Ing, A, Fediuk, K and Tikhonov, C (2021b) Pharmaceuticals in source waters of 95 first nations in Canada. Canadian Journal of Public Health 112, 51335153.Google Scholar
Simms, R, Harris, L, Joe, N and Bakker, K (2016 ) Navigating the tensions in collaborative watershed governance: Water governance and indigenous communities in British Columbia, Canada. Geoforum 73, 616. https://doi.org/10.1016/j.geoforum.2016.04.005.Google Scholar
Smith, DW, Guest, RK, Svrcek, CP and Farahbakhsh, K (2005) Public health evaluation of drinking water systems for first nations reserves in Alberta, Canada. Environmental Science 5, S1S17.Google Scholar
Spence, N and Walters, D (2012) “Is it safe?” risk perception and drinking water in a vulnerable population. The International Indigenous Policy Journal 3(3), 9.Google Scholar
Spicer, N, Parlee, B, Cisaakay, M and Lamalice, D (2020) Drinking water consumption patterns: An exploration of risk perception and governance in two first nations communities. Sustainability 12, 6851.Google Scholar
Waldner, CL, Alimezelli, HT, McLeod, L, Zagozewski, R, Bradford, L and Bharadwaj, LA (2017) Self-reported effects of water on health in first nations communities in Saskatchewan, Canada: Results from community-based participatory research. Environmental Health Insights 11(1), 113.Google Scholar
Walters, D, Spence, N, Kuikman, K and Singh, B (2012) Multi barrier protection of drinking water systems in Ontario: A comparison of first nation and non-first nation communities. The International Indigenous Policy Journal 3(3), 8.Google Scholar
Willms & Shier Environmental Lawyers LLP (2006) Report of the Expert Panel on Safe Drinking Water for First Nations. Ottawa: Minister of Indian Affairs and Northern Development and Federal Interlocutor for Metis and Non-Status Indians.Google Scholar
Wilson, NJ (2019) “Seeing water like a state?”: Indigenous water governance through Yukon first nation self-government agreements. Geoforum 104, 101113.Google Scholar
Wilson, NJ, Harris, LM, Joseph-Rear, A, Beaumont, J and Satterfield, T (2019) Water is medicine: Reimagining water security through Tr’ondek Hwech’in relationships to treated and traditional water sources in Yukon, Canada. Water 11, 624.Google Scholar
Wilson, NJ, Montoya, T, Arsenault, R and Curley, A (2021) Governing water insecurity: Navigating indigenous water rights and regulatory politics in settler colonial states. Water International 46(6), 738801.Google Scholar
Wyrwoll, PR, Manero, A, Taylor, KS, Rose, E and Grafton, RQ (2022) Measuring the gaps in drinking water quality and policy across regional and remote Australia. Clean Water 5, 32.Google Scholar
Figure 0

Table 1. Assessment of common quantitative risks and their levels of severity

Figure 1

Figure 1. Flow diagram of water treatment with key qualitative risks at each stage.

Author comment: Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities — R0/PR1

Comments

No accompanying comment.

Review: Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities — R0/PR2

Conflict of interest statement

no competing interests

Comments

Comment 1

Title of the review paper: Water Security Risks in Small, Remote, Indigenous communities in North America: A critical review on challenges and opportunities. The review is all about Canada with one instance of a brief discussion on Canada and the US (line 291). I wonder whether the title should be changed to “Water Security Risks in Small, Remote, Indigenous communities in Canada: A critical review on challenges and opportunities’ reflecting the subject matter.

The purpose of the article is to outline links between groundwater quality and health, focusing on two case study countries: Kenya and Ethiopia. It was highlighted that in lower-income areas, groundwater supplies are typically installed without water quality treatment infrastructure or services. This is an important observation and true for many low-income countries and applies to surface waters too.

Comment 2

Impact Statement:

It is proposed that the first and the last sentences of the impact statement be changed as below:

First sentence: This review focuses on assessing the key risks to water security faced by small, remote, indigenous communities throughout Canada.

Last sentence: A policy of respectful cooperation and collaboration between communities, researchers, and the government is identified as the most successful strategy in implementing risk mitigation strategies, providing a path to address such water security concerns impacting not only Canada, but other North American countries.

Comment 3

Line 47: Please check: (Longboat, 2015)

Comment 4

Line 55: Please check: (Lucier et al., 2020)

Comment 5

Line 85: (Burnside, 2011) = not in reference list

Comment 6

Lines 132 & 141: (Lane et.al., 2020) – please check.

Comment 7

Lines 146 & 150: There are two references of (Schwartz et al., 2021), one referring to metal contaminants and the other pharmaceutical contaminants. These should be listed as 2021a and 2021b.

Line 146: (…Batal, M.) not Bata, M. - Please check

Comment 8

Line 184: (Mascarenhas et al., (2007) – Single author – please check.

Comment 9

Line 189: McCullough et al., (2012) – Please check referencing style

Comment 10

Line 195: BC Ministry of Health (2016) – Please check 2016 or 2019.

Comment 11

Line 305: Please check sentence for grammar.

Comment 12

Conclusions:

Although briefly discussed in the text, the importance of local water and sanitation safety planning to promote awareness and community participation in improving safe water and sanitation can be highlighted together with the section on community-based research labs, collective and traditional knowledge sharing in developing water policy research, for the success through a bottom-up approach.

Review: Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities — R0/PR3

Conflict of interest statement

Reviewer declares none.

Comments

The manuscript is a useful literature review of drinking water risks of Indigenous communities in Canada. My comments to the authors are provided below:

1. The title needs to be changed to reflect that it’s (a) about drinking water quality rather than water security risks, in general (b) limited to Canadian Indigenous communities rather than North America and (c) is a review rather than an analysis.

2. Please expand on Table 1 or add to it a list of possible health consequences (with references) of the identified problem (category).

3. The REACH program at Oxford (see Results-based funding for safe drinking water services, p.12) highlights three factors in terms of risks and threats to drinking water safety that include: (a) Assessment (what is the human health threat?) (b) Reporting (including to communities); and (c) Management (availability and applicability of management response). Including, or at least mentioning these factors, in section 3.0 would be a valuable addition to the manuscript.

4. The WWH released on 17 October ‘The High Costs of Cheap Water’. The figure on p. 21 that links SDG 6 and nature and to other SDGs is worth reflecting on in terms of what this implies in terms of mitigation of risks to drinking water quality.

5. The main report of the Global Commission on the Economics of Water published in March 2023 (The What, Why and How of the World Water Crisis: Global Commission on the Economics of Water Phase 1 Review and Findings) and is available at: https://www.waterjusticehub.org/the-what-why-and-how-of-the-world-water-crisis-global-commission-on-the-economics-of-water-phase-1-review-and-findings/. See especially pp. 40-44.

6. It would helpful to include a brief overview of findings in the USA and also Australia as both are colonial states with drinking water quality issues in their Indigenous communities. I recommend Wyrwoll et al. (2022) in NPJ Clean Water for a review of the situation in Australia.

7. It would helpful to reflect on different knowledges (e.g., Indigenous versus Western) as a response to risks. Please see ‘Indigenous and Western Knowledge: Bringing Diverse Understandings of Water Together in Practice (Technical Report)’ https://www.waterjusticehub.org/indigenous-and-western-knowledge-bringing-diverse-understandings-of-water-together-in-practice/.

Recommendation: Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities — R0/PR4

Comments

Dear Authors,

we received comments from the reviewers. They both suggest that the paper could be published once minor comments are addressed. I would kindly ask you to go carefully through their comments and suggestions, and to modify the manuscript as needed. In particular, both reviewers made comments on the paper title and on the impact that should be taken into consideration.

Kind Regards,

Alessandro

Decision: Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities — R0/PR5

Comments

No accompanying comment.

Author comment: Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities — R1/PR6

Comments

No accompanying comment.

Review: Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities — R1/PR7

Conflict of interest statement

No competing interests.

Comments

Thank you for responding in full to my comments.

Review: Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities — R1/PR8

Conflict of interest statement

Reviewer declares none.

Comments

The paper has been improved and I recommend for publication.

Recommendation: Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities — R1/PR9

Comments

I would like to thank the Authors for their careful revision. The paper can now be accepted for publication.

Decision: Water security risks in small, remote, indigenous communities in Canada: A critical review on challenges and opportunities — R1/PR10

Comments

No accompanying comment.