Introduction

One of the major challenges of the drinking water sector is to guarantee the microbial safety and quality of the drinking water1. Ideally, high-quality surface- or groundwater is collected and subjected to a variety of physical, chemical, and biological treatment steps, depending on the source water quality2. Regardless of the applied treatment train, the aim remains the same. Namely, to inactivate pathogenic microorganisms, to remove chemical contaminations and organics, and to improve the esthetic characteristics of the water. However, low levels of microorganisms and organics persist in the treated water, and as a result of biochemical and physical interactions during distribution, drinking water may contain between 103 and 106 cells/mL at the tap3. While the majority of these naturally present microorganisms does not compromise the safety of the water for human consumption, their regrowth may result in the deterioration of the water quality, such as deviating odor and taste4, and lead to technical problems5,6. In general, microbial regrowth in the drinking water distribution systems (DWDS) highly depends on the treatment applied to the source water but also on the source water quality.

Over the last decades, Europe has made substantial progress to improve the quality of freshwater bodies. The removal of phosphate from laundry detergents7, the improvements in wastewater treatment and the reductions in the agricultural use of nitrogen and phosphorus8 contributed significantly to control nutrient loading to waterbodies. Yet, despite the progress achieved, 75% of the European waterbodies remain at ecological risk9. In addition to water pollution, there is increasing evidence that climate change will affect water supply and demand10. This will be translated into more intense and longer droughts in some regions and excessive precipitation in others11,12. Those events, in turn, enhance the risk of decreased volumes of freshwater resources for the coming decades13 and contribute to further freshwater degradation.

For the time being, the impact of nutrient pollution and groundwater scarcity may seem more relevant for developing countries. Nevertheless, industrialized countries will also need to adapt to the rapidly changing conditions. With decreasing freshwater resources, nutrient-rich freshwater waterbodies14 and greywater15,16,17 will need to be (re)used more frequently for drinking water production to ensure the drinking water supply. This might pose a point of attention in the near future, as the increase in the concentration of nutrients in the raw water may subsequently increase the nutrient concentration in the drinking water, resulting in the potential regrowth of opportunistic pathogens, overall regrowth, and further biofilm development in the DWDS. This extensive regrowth may in turn exacerbate the already challenging problems found in the DWDS, such as clogging6 and corrosion5, and changes in esthetic features4. Also, increasing temperatures have already been linked to changes in water quality, either by promoting planktonic regrowth or accelerating biofilm development18,19. Opportunistic pathogens, including indicator organisms, have also been documented to occur at higher temperatures20,21. In a scenario of climate change, where bulk water temperatures and nutrient concentrations are higher, the potential for regrowth is, therefore, also expected to increase. In addition, the current prospects include increased occurrences (and duration) of flooding events. During periods of heavy rainfall, contamination between sewage and drinking water pipes (particularly where water infrastructure is old), sewage overflow, or bypass into local waterways is also possible22.

To circumvent external contamination and control naturally present microbial (re)growth, residual disinfectants such as free chlorine and chloramine are commonly added before distribution. Those approaches are being challenged as the use of free chlorine may induce the formation of by-products that can be a toxic nuisance to humans23, and the use of chloramine may promote the development of nitrifying bacteria5. The latter oxidize the ammonia to nitrite and subsequently to nitrate. However, both compounds can become toxic for humans23. In addition, some by-products can also cause a deviating odor and taste (e.g., trichloroanisoles)24. This forms a driving factor for drinking water utilities to avoid chlorination. In this context, water utilities tend to strive more for biostability, which implies producing microbially safe drinking water without the use of a disinfection residual25, as already applied in different European countries such as Switzerland, the Netherlands, and Germany26,27,28,29.

When producing biostable water, microbial growth is controlled by one or more disinfection strategies such as membrane filtration (e.g., reverse osmosis (RO)30), UV irradiation, ozone or AOP. The latter is often applied in combination with extensive biological treatment such as sand filters or biological active carbon (BAC) filtration. To further avoid microbial regrowth during distribution, focus is placed on organic carbon removal. Guidelines have been proposed for assimilable organic carbon (AOC, <10 µg C/L in non-chlorinated systems, <100 µg C/L in chlorinated systems) and biodegradable dissolved organic carbon (BDOC, <150 µg C/L) concentrations25,31,32, as this is considered to be the main limiting nutrient for microbial growth in drinking water.

While this may be true for the majority of heterotrophic bacteria, the exclusive limitation of organic carbon fails to address autotrophic bacteria. Indeed, contrary to the common assumption that organic carbon is the major problem to be addressed in practice, different studies have reported a weak correlation between AOC and the growth of invasive pathogens and have instead suggested phosphate as another important limiting nutrient in surface and drinking water33,34,35. In addition, microbial drinking water quality is often checked by only regarding the heterotrophic bacteria (e.g., HPC at 22 °C or 37 °C)36. However, as phosphate and ammonium accumulate in surface water9 used as a drinking water source, autotrophs may grow to unwanted extents (e.g., Sydney, Australia37).

To understand and control microbial growth in DWDS it is crucial to revisit the current concept of biostability. All things considered, there is a clear gap between what is already known from research and what is currently implemented in practice. There is thus a need for a framework that connects both, as a balance between complexity and feasibility with regard to future challenges that will stress the water quality and availability. We propose a new framework for redefining and managing biostability, by regarding all growth-limiting factors for microbial growth, including the energy availability, and by maximizing the ratio of the number of microorganisms present to the nutrients and energy available.

Revisiting the concept of biostability

WHO states that “water entering the DWDS must be microbially safe and ideally should also be biologically stable”36. Biological stability was primarily defined by Rittmann & Snoeyink as “the inability of water or a material in contact with water to support microbial growth in the absence of a disinfectant”38. However, in our opinion, one can never achieve such true biostability, as a microbial ecosystem is dynamic and always evolving, and the perception of stability is limited by the technology being used to study the ecosystem. For example, with the current scientific knowledge, it is known that even when heterotrophic plate count results are perfectly constant over time or throughout distribution, there may still be considerable changes in the microbial abundance. With the rise of direct and sensitive approaches to monitor the microbial abundance and composition in the network such as flow cytometry39,40 and sequencing methods41, the challenge has thus shifted toward defining the “degree of acceptable change”. A complete overview of the current knowledge about biological stability in drinking water is given by Prest et al1. Here, we try to address all aforementioned challenges into a framework for biostability and we revisit the fundamental aspects that govern it. From our point of view, biostability implies stability of both the bacterial abundance and bacterial community composition.

To define a stable bacterial community composition, the main concept is based on microbial resource management42. This means that we aim to steer the microbial community of the water to a state that is resistant toward invasion and/or growth of unwanted microorganisms, and does not show excessive regrowth during distribution. More specifically, we are introducing the r/K-strategist concept, which has, to the best of our knowledge, not been applied to microbial drinking water ecosystems yet (Fig. 1). This concept originates from macro-ecology43, and has been expanded to microbial ecosystems such as aquaculture44, soil45 and anaerobic digestion46. Although it may “oversimplify” the ecosystem’s dynamics, the r/K-strategist concept is preferred amongst other ecological concepts such as the resource-ratio theory47,48 or C/S/R theory49 as it forms a balance between practical feasibility and complexity. Within the r/K framework, (micro)organisms are classified as either r-strategists, characterized by a high growth rate at high nutrient concentrations, or K-strategists, characterized by a high substrate affinity. In drinking water, we consider the naturally present community to consist out of K-strategists, whereas pathogens and indicator organisms are rather classified as r-strategists, analogous to applications in aquaculture50. Using this approach, biostability can be achieved by steering the bacterial community toward K-strategists through nutrient limitation. Also, research has shown that by limiting the nutrients in the water entering the distribution network, the biological activity in both the water and biofilm will decrease and EPS production and subsequent bio-adhesion will decrease6,51,52. Thus, by focusing on nutrient limitation as a strategy to limit bacterial growth in the network, it is hypothesized that this approach may also limit biofilm formation.

Fig. 1: Growth rate of K- and r-strategists in function of the concentration of growth-limiting factors.
figure 1

At concentrations lower than the critical K/r threshold concentration [S] (blue), K-strategists (naturally present bacteria) will dominate the community, whereas, at higher concentrations, unwanted regrowth of r-strategists (opportunistic pathogens and indicator organisms) can occur. Adapted from De Vrieze et al46.

In terms of bacterial abundance, we aim to produce water that contains a bacterial load close to the carrying capacity (M)53 of the ecosystem, regarding all phases (e.g., bulk water, biofilm, loose deposits). The carrying capacity is widely applied in ecology and has been defined as the maximum number of individuals that a given level of nutrients and environmental conditions (niche) can support. In practice, this means that different initial densities of certain species in the same drinking water are expected to reach a certain carrying capacity, as based on the Gompertz growth curve (Supplementary Fig. 1). The carrying capacity can be influenced by a set of factors (such as availability of nutrients, space and temperature) and the interactions between them. By aiming at bacterial densities close to the carrying capacity, the energy input to the ecosystem will approximate the maintenance cost of the bacteria, and the net regrowth during distribution will be limited54. In our concept, we consider the growth-limiting factor concentrations (Fig. 2, x-axis) and the total bacterial abundance (Fig. 2, y-axis) as the two main determinants for biostability. The former comprises the available nutrients as well as electron donors and acceptors necessary for the bacterial energy metabolism27.

Fig. 2: The concept of biostability as a function of the potential for growth and the potential to consume resources.
figure 2

The potential for growth is measured as the concentration of growth-limiting factors (x-axis), and the potential to consume resources is measured as the bacterial load (y-axis). At a growth-limiting factor concentration below the threshold [S] (blue vertical line), selection favours the K-strategists (see also Fig. 1). The microbial abundance should be close to the carrying capacity M (red horizontal line). When these two conditions are fulfilled, the relative amount of nutrients and energy available for a bacterium (“per caput”) will be minimized (yellow diagonal line). Biostable water must comply with these three boundaries (green area). When a small change in bacterial or nutrient concentration occurs, a biostable ecosystem should be resilient (blue and red marked area around M and [S]). Three situations of biological instability are illustrated. A A bacterial load above the carrying capacity of the ecosystem will result in die-off, resulting in a release of nutrient and (necrotrophic) growth. B A too low bacterial load will result in overall regrowth. C A growth-limiting factor concentration above the K/r threshold concentration will result in regrowth of unwanted r-strategists.

Two main conditions should be fulfilled for obtaining biostable water, regarding the total bacterial load and total growth-limiting factors concentration. First, the total nutrient and energy availability (further represented as “S”) should be below the threshold concentration to select for K-strategists and not induce regrowth that can lead to water quality deterioration, and in extreme cases pose health risks (e.g., regrowth of pathogens)55 (Fig. 2, point C). Secondly, the total bacterial load should be close to the carrying capacity. If this is not the case, the system becomes prone to invasion and microbial die-off will occur, and dead biomass can become available as nutrients, resulting in necrotrophic growth by pathogens such as Legionella pneumophila (Fig. 2, point A)56. Hence, to become biostable, drinking water should contain a relatively high amount of bacteria compared to the amount of growth-limiting factors available (Fig. 2). When compliant with these conditions, biostability can be defined as a dynamic equilibrium in which a small increment of growth-limiting factors above the lower threshold (S + ΔS) leads to a density increase (M + ΔM) but falls rapidly back (to M) without bringing along major disturbances in terms of bacterial abundance and composition (Fig. 2, red and blue area, Supplementary Fig. 1, green area). As shown in Fig. 2, biostability is defined as a range determined by the boundaries explained above, wherein changes within the bacterial community structure and abundance as a response to environmental changes are allowed. For example, growth as a result of normal seasonal fluctuations is in this respect not considered as biological instability.

To implement the proposed concept of biostability in practice, and to define the “degree of acceptable change”, a framework for decision-making is necessary. This implies (1) network-specific calibration to define the desired state of stability of the microbial community, as we believe that the boundaries for biostability will depend on the ecosystem’s characteristics, and (2) defining the allowed deviation from that baseline state. More specifically, we suggest the use of flow cytometry as a fast, even online, and non-targeted technique to quantitatively (microbial abundance, total cell counts) and qualitatively (microbial community structure, flow cytometric fingerprinting) assess the total microbial community’s stability57,58. A baseline state can first be defined by validating the water quality using routine parameters and methods. Based on the baseline flow cytometric measurements, a threshold can be set on the total cell counts and change in fingerprint (e.g., mean plus three times the standard deviation)39,59. To account for progressive changes such as normal seasonal changes, the use of a dynamic baseline calculated by for example moving window analysis (MWA)60,61 or moving endpoint analysis (MEA)62 is proposed. In this regard, the total microbial community, here monitored using flow cytometry, serves as an indicator for the microbial water quality. When deviations from the baseline occur, targeted approaches such as selective plating, qPCR, or third-generation sequencing can be used to further define if this deviation was related to the proliferation of pathogens. Overall, this framework relies on the development of a dynamic and network-specific threshold, as the degree of acceptable change will depend on the drinking water network and its location, water source, and infrastructure in specific. Hence, it is difficult to impose general guidelines for bacterial abundance or community structure. For example, up to date, there are no general straightforward thresholds or upper limits in the European Drinking Water Directive 98/83/EC63 regarding the total bacterial abundance. This is different compared to bottled water, where an upper limit of e.g., 100 CFU/mL at 22 °C is defined. The proposed framework may thus serve as an addition and guidance to the conventional methods for evaluating the microbial water quality as required by the regional/national law.

Achieving high-quality source water

Both the source water quality and the water treatment are crucial for the production of biostable drinking water. Eutrophication of surface waters (in)directly stands as one of the major threats to the water biostability. One of the most visible signs of excessive nutrient inputs in surface waters are cyanobacterial blooms. Apart from food web alterations and loss of diversity, large blooms often lead to an increase in water turbidity, foul smells and clogging64. Furthermore, drinking water productions often face the additional challenge of removing toxins produced by cyanobacteria.

Taking into account the prospects for increasing and extended eutrophication events, it is critical to develop and establish sustainable technologies capable of removing nutrients from surface waters to the microgram/L level, while maintaining an ecologically friendly status. Popular methods such as constructed wetlands65, artificial floating islands66, ecological floating beds67, gravel-packed contact beds68 and pre-dams69, which rely on the growth rate of plants and demand large areas of land, will most often not be adequate or operationally affordable. Precipitation as well as adsorption strategies, on the other hand, have obtained very promising results. Both Phoslock, a lanthanum modified bentonite that removes soluble phosphorus by forming lanthanum phosphate precipitates70, and adsorptive materials71 can remove soluble phosphorus to levels below 10 µg/L. A drawback, however, is that both technologies, only target one specific nutrient. Surface waters receiving nutrients from agricultural runoff often exhibit high levels of phosphorus as well as nitrogen. Hence, a combination of methods targeting different nutrients is required to maintain microbial quality regarding all growth-limiting factors. The latter concept is applied in the field of food technology, where the microbial stability and safety is based on a combination of several factors (hurdles) that should not be overcome by the microorganisms present72. Alternatively, biological strategies consider the limitation of different available growth-limiting factors and are therefore a promising route for obtaining a good ecological status of surface waters. One recently available example is the use of the autotrophic hydrogen oxidizing bacteria to treat eutrophic water73. The use of a highly energetic electron donor allows for the combined removal of nutrients such as phosphorus and nitrogen down to levels below 10 µg/L. Another example is the self-sustaining in situ photo-microbial nutrients recovery cell, which allows for the removal and recovery of nutrients with simultaneous electricity generation and microalgae production74. In this way, excessive microbial growth can be minimized resulting in a high-quality water source for subsequent drinking water production.

Biostability during drinking water treatment and distribution

Drinking water treatment consists of different steps, which can impact the biostability of the final drinking water by changing the water characteristics in one or more ways1. Even though the drinking water exiting the production utilities is most often of high quality, microbial regrowth may still occur during distribution of biologically unstable drinking water64. Most regrowth is observed when using surface water as a source as on the one hand, the nutrient concentrations are higher compared to groundwater, and are not always sufficiently removed to avoid further regrowth during distribution3. On the other hand, surface waters are sometimes subject to extreme seasonal fluctuations, e.g., a higher water temperature in summer resulting in more regrowth39,75,76. To anticipate the increasing stress imposed on the water quality and supply by climate change and population growth, the drinking water quality at the exit of the production utility must be biostable as defined in the proposed framework, to avoid problems at the tap.

One interesting approach to remove nutrients and microorganisms to ultra-low levels at the end of the treatment train is RO. RO is an emerging technology that physically retains bacteria and nutrients by pushing the water molecules over a membrane under high pressure. This technology is also applied for desalination of brackish water or seawater, with retention efficiencies up to 99.5%77, and performs even better when preceded by complementary technologies such as ion exchange78. Yet, because the concentration of microorganisms is low relative to the growth-limiting factors in the filtrate, the produced water is not always biostable as there are plenty of niches available for microbial growth during the subsequent distribution. Regarding the proposed framework, this means that even though the concentrations are low in absolute amounts, the nutrients and energy available per caput is high, allowing for regrowth during distribution (Fig. 2, point B). For example, bacterial growth in RO permeate showed a 2 log increase in a lab-scale setup tested by Park & Hu79.

Biofiltration (e.g., activated carbon filtration) is often applied after physicochemical treatment to avoid regrowth in the distribution network and to remove trace pollutants80. This treatment step is crucial for obtaining biostable drinking water, as nutrients will be removed by a combination of adsorption and controlled microbial growth on the filter. Furthermore, the microbial community on the filter can have an impact on the composition of the microbial community of the distribution network81 (Fig. 2, point A). Also, biofiltration allows the production of “microbially matured water” as used in aquaculture, by seeding the drinking water with a harmless naturally present microbial community that is occupying all niches in densities close to the carrying capacity of the water, hereby favoring the growth of K-strategists (Fig. 1). This way, this diverse microbial community controlling all growth opportunities, will be less prone to pathogen invasion and environmental stress. In addition, by changing the composition and concentration of growth-limiting factors (nutrients or electron donors/acceptors), the microbial community in the filter and the produced drinking water (through seeding) could be steered toward a desired composition or its functionality can be optimized to capture nutrients selectively or to an overall larger extent. With regard to the future, it is important to note that the water quality of the source will affect the performance of the biofilter, as a high nutrient loading may result in clogging or incomplete removal. Hence, striving for biostability of the final drinking water includes optimizing both the preceding multi-barrier treatment and the biofiltration process itself.

After biofiltration, residual disinfection is sometimes applied to suppress microbial growth during distribution. However, this approach is detrimental to achieving biostability, as useful microbial cells controlling the nutrients will be killed and the ratio of active microbial cells over all bioavailable nutrients lowers. Moreover, dead biomass will serve as a substrate for necrotrophic regrowth in the distribution network42. As regrowth in drinking water during distribution is almost unavoidable82, the production of biostable water through extensive steering and control of growth-limiting factors is preferred over the use of a disinfection residual as it is a more sustainable and safer (e.g., absence of disinfection-by-products) approach. Nevertheless, proper maintenance of the DWDS, clever engineering (e.g., to avoid longer HRTs) and high-resolution monitoring of the microbial dynamics becomes even more important to ensure the microbial water quality at the tap39,40,83.

Outlook

Creating biostable water is the way forward for controlling the microbial water quality in drinking water from the source to tap, and in industrial process- or cooling waters. We need to focus on the things we can control, such as the concentration of growth-limiting factors and microorganisms entering the distribution network. In this respect, we should particularly deal with the ratio of K-strategist microorganisms over the amount of available nutrients and energy sources. That ratio must be sufficiently high to prevent overall (re)growth and growth of unwanted r-strategist pathogens in particular. In this respect, it is important to regard the effect of not only the quantity but also the composition of limiting nutrients, such as for example different carbon fractions, on the biostability of the drinking water. Also, more research is needed in understanding the relation between the planktonic community, operational conditions and the detachment of unwanted species from the biofilm, to avoid discomfort (e.g., odor or taste problems) or water quality issues at the tap. In practice, interventions in terms of nutrient removal should take place as early as possible in the water treatment chain to avoid problems downstream. Also, high-resolution monitoring and understanding of microbial (re)growth in production processes and the DWDS remain of utmost importance to ensure the microbial water quality at all times.