YSI (Xylem Analytics, France) EXO2 mulitparameter probe which contained sensors for the following water quality parameters: temperature, specific conductivity, dissolved oxygen, pH, turbidity, fluorescence Dissolved Organic Matter (fDOM), chlorophyll-a and phycocyanin and equipped with anti-fouling wiper, was used in this study. The EXO total algae sensor contains two excitation beams: a blue excitation beam that directly excites chlorophyll-a molecule, and an orange excitation beam that excites phycocyanin pigment, with a narrow excitation and emission wavelengths bandpass (±5 nm). All experiments were made using the EXO calibration cup filled with around 400 mL of water to be analyzed. Data communication was ensured using USB signal output adapter and the KOR software. The direct readings of the probe were recorded using the manufacturer original calibrations. During all the assays, mixing was manually achieved by shaking.

The following cultures were grown separately in their corresponding media: Microcystis aeruginosa (CCAP 1450/1) in Cyanobacteria BG-11 media (Sigma Aldrich), Chlorella vulgaris (CCAP 211/11B) Desmodesmus subspicatus in Algae Culture Broth (Fluka Analytical). C. vulgaris and D. subspicatus are two freshwater green algae, selected for their known capacity of chlorophyll-a. M. aeruginosa is the most common toxic cyanobacterial species responsible for bloom in eutrophic fresh water (PAERL and OTTEN, 2013). After inoculation with 50 mL of a previous grown algae culture in a stationary phase, cultures were incubated in batch of 500 ml culture media in 1 L Erlen flasks. Incubation was performed at room temperature (20-25 °C) under a 6h rotating light-darkness flux (10 000 lux∙m^-2) with agitation by rotatory movement (100 rpm). After around 2 weeks of incubation, cell counts were conducted by light microscopy using a counting chamber at 40x.

Water samples were sourced either as tap water from Le Pecq drinking water distribution system (France) either as river raw water (Seine River collected at le Pecq, France). Tap water residual chlorine was neutralized by addition of sodium thiosulfate (20 mg∙L^-1) for 30 min. Serial dilutions in 500 mL of M. aeruginosa, C. vulgaris, and D. subspicatus cultures were performed. In a second set of assays, two concentrations of green algae (Chlorella or Desmodesmus, at 10 000 and 100 000 cells∙mL^-1) were added in sequence to a range of concentration of M. aeruginosa (5.10E+3 to 10E+6 cells∙mL^-1). The effect of natural turbidity and fluorescent/colored dissolved organic matter was respectively studied by using raw Seine River water (turbidity of 62 NFU, Total Organic Carbon of 4.2 mg∙L^-1 and Dissolved Organic Carbon [DOC] of 2.8 mg∙L^-1) and commercial humic acid solution (Sigma Aldrich reference 53 680). A stock solution of the acid humic solution at 1 g∙L^-1 was made by dissolving 1 g in 1 L of deionized water followed by a filtration through a glass fiber filter (GF/F Whatman, nominal pore size 0.7 µm).

In the first culture assays in mono-suspensions, five concentrations of M. aeruginosa between 5 000 and 300 000 cells∙mL^-1 from three independent culture batches were measured by the EXO2 probe. This range of concentration includes the alert levels as recommended respectively by the Australian Drinking Water Guidelines (2011) equivalent to 65 000 cells∙mL^-1 of M. aeruginosa and WHO guidelines for safe recreational water environments with Level 1 (20 000 cells∙mL^-1) and Level 2 (100 000 cells∙mL^-1) thresholds. As observed by ZAMYADI et al. (2012a), the repeatability of the probe measurements in tap water were good over the full range of quantification with standard deviation from 1.1% to 7.7%. Figure 1 shows also the good linearity of the relationship between BGA-PC and M. aeruginosa cell concentrations even when all data from the three different batches were pooled with a global linear coefficient about 0.99. Similarly good linearity was recorded when M. aeruginosa cells were spiked into river water (turbidity of 61.7 NFU; DOC of 2.8 mg∙L^-1). Although no interference for quantifying cyanobacteria cells below 5.10E+5 cells∙mL^-1 was shown in turbid surface water, somewhat a difference in BGA-PC reads can be observed at concentration above 10E+6 cells∙mL^-1. At this concentration, quantification of Microcystis may be underestimated of about 25%. Using bentonite for simulating turbidity, ZAMYADI et al. (2012b) showed that this bias could reach up to 60%.

Considering the limit of detection (LoD) calculated as the mean plus 3SD of the blank and the limit of quantification (LoQ) as the mean plus 10SD of the background noise (mean = -1.36 RFU, SD = 0.13), the LoD and LoQ of the method are respectively 670 and 2 450 cells∙mL^-1 in tap water. This is consistent with the observation of BASTIEN et al. (2011) using the YSI 6600 probe. However using the manufacturer’s calibration negative values are observed for BGA-PC readings (expressed in RFU or µg∙L^-1) for M. aeruginosa concentration below 10 000 cells∙mL^-1, leading difficult the interpretation of low cyanobacteria range. Using EXO multiparameter probes outputs, linear relationships were also achieved using the chlorophyll-a output and in much lower extent with turbidity (Figure 2). Interestingly, a linear relationship was also observed between fDOM outputs and M. aeruginosa cell concentration. Some authors (FUKUZAKI et al., 2014) had recently proposed that fDOM could be used for the monitoring of marine phytoplankton by the direct production of fluorescent characteristics of algae exudates.

First, two dilution ranges from two Chlorophyceae cultures (with concentration from 5.10E+3 to 10E+6 cells∙mL^-1) were made in tap water and measured by EXO2 probe. Results showed that Chlorella vulgaris and Desmodesmus subspicatus cultures exhibit high chl-a content as expected, with good linearity coefficients (R² of 0.992 and 0.988 respectively) but can also present some fluorescence detected by the BGA-PC sensor, especially for high green algae concentrations. At concentration level of 5.10E+5 cells∙mL^-1 of C. vulgaris and D. subspicatus respectively (corresponding to high level of chlorophyll-a above 350 µg∙L^-1), around 7 and 15 µg∙L-¹ of BGA-PC can be measured in absence of cyanobacteria (Figure 3). Secondly, a dilution range of cyanobacteria Microcystis aeruginosa concentrations were measured in presence (or not) of different amounts of Chlorella or Desmodesmus cells. As shown in figure 4, when moderate to high (up to 60 µg∙L-¹) background of chlorophyll-a brought by green algae, the BGA-PC measurement of M. aeruginosa is only significantly impacted (p < 0.05) for high cyanobacteria cell concentration in presence of C.vulgaris. This observation is in contradiction with previous observation made by ZAMYADI et al. (2012) using YSI 6600 phycocyanin sensor. This suggest that the more precise excitation and emission wavelength bandpass (±5 nm) used in the new version of EXO2 probe limits successfully the impact of chlorophyll-a from eukaryotic algae fluorescence. The combined effect of turbidity and chlorophyll-a was also studied by adding different quantities of C. vulgaris cells (corresponding to respectively 16 and 30 µg∙L^-1 of chl-a) in the Seine River sample (62 NFU turbidity). No additional effect of chlorophyll-a was observed for the PC quantification from a range of M. aeruginosa cells concentration.

Fluorescent Dissolved Organic Matter, also known as yellow substances, is the optically active portion of dissolved organic matter (DOM), and is mainly sourced from terrestrial humic and fulvic substances. This form of colored dissolved organic matter have the potential to influence fluorescence readings due to their ability to alter light transmission, as well as their natural fluorescence capabilities. Some manufacturers like BBE have integrated a yellow substance correction factor in their fluorescence sensor instrument (as for the Algae Online Analyser). Assays were performed using a solution made from a commercial humic acid extract providing a constant level of 10 mg∙L^-1 of DOC. Such DOC concentration corresponds to the concentration of dissolved organic matter present in some surface waters and reservoirs (AWAD et al., 2017) and attributed to flushing of the upper organic soil horizons. For this solution, the following optical and fluorescence backgrounds were observed: fDOM background of 166 (±1) ppb, turbidity of 7.4 (± 0.1) NFU, chlorophyll-a of 25.3 (±0.1) µg∙L^-1. In comparison with BGA-PC readings made in tap water for the quantification of a range of M. aeruginosa cells concentrations, the difference of 0.8 BGA RFU at the y axis crossing correspond to the BGA-PC background from the humic acid solution. This difference could however lead to an overestimation that can be slight (around 10-15%) for high level of BGA concentration (>10E+5 cells∙mL^-1) but can reach 100% for lower concentration (5.10E+3 to 10E+5 cells∙mL^-1). These results show that the content of high fDOM (proxy of high DOC) can cause interference with BGA quantification using PC sensor, especially for a range of low cyanobacteria cell concentration.