agronomy Impact of Diversiﬁed Chemical and Biostimulator Protection on Yield, Health Status, Mycotoxin Level, and Economic Proﬁtability in Spring Wheat ( Triticum aestivum L.) Cultivation

: Biostimulators with chemical protection are a challenge in sustainable agriculture to obtain high yield, healthy, and pesticide-free wheat. The aim of this four-year spring wheat ﬁeld experiment was to assess the effectivity of using herbicide, mixed fungicides protection, and a humic biostimulator. The following treatments were tested: biostimulator (S), sulfosulfuron (H), H + S, H + propiconazole + cyproconazole/spiroxamin + tebuconazole + triadimenol (H + F1 + F2), and H + F1 + F2 + S. Evaluations of wheat yield and fungal diseases (Septoria tritici blotch, eyespot, sharp eyespot, Fusarium spp.) were performed using visual and qPCR methods. Thirteen mycotoxins were analyzed by LC–MS/MS. Infestations of six weeds were examined visually. Temperatures and precipitation data of the vegetative seasons were monitored. Precipitation most affected the occurrence of leaf diseases despite the same chemical/biostimulator treatments (up to 48% Septoria tritici blotch severity for the S treatment). The highest mean yield was obtained for H + F1 + F2 + S (5.27 t ha − 1 ), while the lowest level of mycotoxins was obtained for H + F1 + F2 (221.68 µ g kg − 1 ). For H + S, a greater reduction of mycotoxins was determined compared to the H treatment (27.18%), as well as a higher severity of eyespot (18%) and sharp eyespot (24%). In 2017-2020, the most effective reduction of weed infestation and Fusarium spp. DNA on ears was indicated for H + F1 + F2 (16 g and 0.88 pg g − 1 DNA, respectively). The greatest saved production value (890 € ) was determined for H + F1 + F2 + S.


Introduction
Cereal crops are the basic group of cultivated plants used worldwide for consumption, fodder, and industrial purposes. Cereals are rich in proteins, carbohydrates (including starch), fiber, phosphorus, zinc, silicon, fluorine, calcium, potassium, and B vitamins [1]. According to OECD/FAO [2], the estimated growth in wheat consumption by people will progress due to the growing human population. To increase the supply of wheat grain, crop protection methods contributing to higher yields and reduced occurrences of fungal diseases and mycotoxins need to be developed.
Wheat is susceptible to fungal pathogens which cause losses in yield and grain quality. Pathogenic fungi are responsible for leaf and stem diseases, contributing to severe yield and grain quality losses (e.g., Septoria tritici causes Septoria tritici blotch, Tapesia yallundae is responsible for eyespot, while Rhizoctonia cerealis causes sharp eyespot) [3]. Fungi belonging to Fusarium spp. are common microorganisms infecting cereals. In East-Central Europe, F. culmorum, F. graminearum, F. avenaceum, F. poae, and F. oxysporum occur most frequently [4]. Fusarium diseases in wheat cultivation include seedling blight, foot rot, and Fusarium timulators based on glutamic and organic acids, soluble carbohydrates, and microelements contributed to a higher yield, but their impact on fungal diseases and mycotoxins was not examined [20]. Biostimulators from brown algae can reduce mycotoxins level and Fusarium spp. occurrence; however, their effect on yield and leaf diseases was not investigated [21]. Humic and fulvic acids, which are components of humic biostimulators, have a positive effect on the development of lateral roots, aerial parts growth stimulation, or mitigation of the effects of water shortages and soil salinity [16]. However, their impact on fungal diseases severity and the reduction of mycotoxins level was poorly investigated. Moreover, there are limited studies concerning the effect of biostimulators combined with pesticides on health status and weed infestation in agricultural plants [17] with the practical aspect of economic efficiency.
The new insights of this study include a comprehensive assessment of the impact of various levels of chemical protection combined with a biostimulator or the exclusive use of a biostimulator as well as climatic conditions of East-Central Europe on the health status of wheat. The collateral goals were as follows: (1) evaluation of the impact of herbicide, herbicide with fungicides, and herbicide with fungicides and biostimulator on wheat yield and ergosterol content; (2) examination of fungal diseases severity and mycotoxins concentration for different crop protection strategies; (3) study of the mutual relationship between climatic conditions and quantitative and qualitative wheat grain parameters according to the diversified level of chemical/biostimulator protection; (4) and the determination of the economic profitability of different protection strategies in agricultural practice.
Taking into account the fact that the zonal registration of plant protection products in the European Union coincides with the climate zone of East-Central Europe, the results of our research can also be applied to other countries in the region.

Field Experiment and Meteorological Data
Spring wheat (Triticum aestivum L.) of the Mandaryna variety was cultivated in the experimental plots (4 m × 5 m; total area 640 m 2 ) over four years in northeastern Poland (53 • 11 43.6 N 23 • 01 02.7 E; 165 m AMSL) with a humid continental climate and warm summer subtype. After wheat harvest in each year, lupine was grown on the field as an aftercrop. The climatic conditions of this area are similar to other countries of East-Central Europe [6]. Certified seeds were sown on 4 April 2017, 6 April 2018, 3 April 2019, and 7 April 2020. Seedlings (except controls) were sprayed with commercial pesticides including herbicide sulfosulfuron (H, active substance; a.s.: 75%), applied at BBCH 31  Mean precipitation in the vegetative season was 295 mm in 2017 with a temperature of 13.25 • C, 204 mm and 16.41 • C in 2018, 183 mm and 14.9 • C in 2019, and 160 mm and 13.7 • C in 2020. The temperature and precipitation data of the vegetative seasons were obtained from the meteorological station located at the experimental plots (53 • 11 43.6 N 23 • 01 02.7 E).

Evaluation of Wheat Yield and Fungal Diseases
Wheat yield was assessed by harvesting all ears from 20 m 2 with a plot harvester; weighting and weight from 20 m 2 was extrapolated to 1 ha. Ergosterol content was assessed using an Infratec 1241 device (Foss, Hilleroed, Denmark), based on NIR (near-infrared radiation). Fungal diseases (Septoria tritici blotch, eyespot, sharp eyespot) were evaluated visually at the milk-dough growth stage (BBCH 79) in the stem base, flag, and second leaf on 25 randomly collected plants from each plot, according to the EPPO (European and Mediterranean Plant Protection Organization) scale. Disease severity was determined as low at <20%, moderate at 20-40%, and high at >40%.

Quantitative Determination of Fusarium spp.
F. culmorum, F. avenaceum, F. graminearum, F. poae, and F. oxysporum reference strains were grown for 5 days in 23 • C on potato dextrose agar (PDA). Next, 100 mg of mycelium was scraped from the solid medium and DNA isolation was performed according to the modified for filamentous fungi CTAB method with a NucleoSpin Plant II Kit (Macherey-Nagel, Düren, Germany) as recommended by the manufacturer.

Weed Infestation
To assess weed infestation, all plants excluding wheat were uprooted from 1 m 2 o control and all treatments. The plant material was collected in the BBCH 54 stage of whea (heading). Weeds were cleaned from the soil particles. On the day of harvesting, the num ber and mass of the following most common species were determined: shepherd's purse (Capsella bursa-pastoris), white goosefoot (Chenopodium album), common knotgrass (Polyg onum aviculare), red pimpernel (Anagallis arvensis), yellow foxtail (Setaria glauca), black bindweed (Fallopia convolvulus), and wall speedwell (Veronica arvensis).

Weed Infestation
To assess weed infestation, all plants excluding wheat were uprooted from 1 m 2 of control and all treatments. The plant material was collected in the BBCH 54 stage of wheat (heading). Weeds were cleaned from the soil particles. On the day of harvesting, the number and mass of the following most common species were determined: shepherd's purse (Capsella bursa-pastoris), white goosefoot (Chenopodium album), common knotgrass (Polygonum aviculare), red pimpernel (Anagallis arvensis), yellow foxtail (Setaria glauca), black bindweed (Fallopia convolvulus), and wall speedwell (Veronica arvensis).

Economic Optimum Rate
To assess the economic profitability of each protection strategy, the following calculations were performed: where E is economic the efficiency (>1), Spv is the saved production value (€), Ct is the total cost of treatment (cost of plant protection products, biostimulator, average cost of fuel per hectare), Ys is the yield saved from a particular strategy compared to the control (t ha −1 ), C is the average cost of wheat at harvest for each study year (t ha −1 ), and Ym is the minimum yield saved in a particular strategy compared to the control, justifying the profitability of the treatment. An economic efficiency above 1 indicates that the strategy is profitable in agricultural practice. The above equations were calculated for average yield and costs from the four-year study. The average costs of treatment per 1 ha in relation to the prices in Poland were as follows: biostimulator (6.16 €), herbicide (24.78 €), herbicide + biostimulator (30.94 €), herbicide + fungicide F1 + fungicide F2 (63.32 €), and herbicide + fungicide F1 + fungicide F2 + biostimulator (69.48 €). The average price of 1 t of wheat was 163.45 €.

Statistical Analysis
Analyses were conducted using one-way ANOVA and a post hoc Fisher's test (Table S1). A principle component analysis (PCA) between variables was performed. A resulting correlation matrix was visualized as a heatmap. Statistical significance was established as p ≤ 0.05. For the examined traits, Pearson's correlation (r) was carried out for p ≤ 0.05. All data were elaborated in STATISTICA 12 software (StatSoft, Tulsa, OK, USA).

Quality Parameters of Wheat Grain under Diverse Chemical/Biostimulator Treatments
Despite frequent single herbicidal protection, the highest yield in the years 2017-2020 was determined for the sulfonylurea herbicide with a biostimulator (H + S; 6.5 t ha −1 ), herbicide combined with morpholine/triazole fungicides (H + F1 + F2; 6.3 t ha −1 ), and the herbicidal and fungicidal treatment combined with a humic biostimulator (H + F1 + F2 + S; 6.1 t ha −1 ) ( Table 2). In the four-year period, an average yield ranged from 3.43 t ha −1 in 2017 to 6.5 t ha −1 in 2018. Low yields for all combinations in 2017 are connected with high total precipitations, and they resulted in greater fungal diseases incidence. However, single biostimulator application caused a lower yield (4.8 t ha −1 ) compared to that of the control (5.3 t ha −1 ). Septoria tritici blotch was observed on leaves, while eyespot and sharp eyespot were noticed on the stem. However, according to EPPO recommendations, the severity of Septoria tritici blotch was determined as high only in 2017 (>40%) for selected combinations (Table 2). Additionally, in 2018, eyespot was noticed as moderate (20-40%) for the control and sulfosulfuron (H), the sulfosulfuron with biostimulator (H + S), and the herbicide combined with fungicides and biostimulator (H + F1 + F2 + S). A moderate severity of sharp eyespot was determined in 2017 and 2018 for selected combinations. In 2019 and 2020, the severity of all examined fungal diseases was determined as low (<20%). Other diseases and pests were not detected.
Ergosterol is a marker of fungal infection in plants. The most effective reduction of its concentration was determined in fungicidal treatments (Table 2) (p < 0.05). Additionally, ergosterol content was also lower following the application of a biostimulator in 2017 and 2019. The total concentration of ergosterol may be related to the occurrence of other fungi, which were not assessed in this study due to their low incidence.

Evaluation of Fusarium spp. and Their Metabolites Concentration in Wheat Grain
The occurrence of Fusarium spp. may be related to climatic conditions. Our results show that the total Fusarium spp. concentration in the four years of the study was variable. The highest content of Fusarium spp. in all combinations (up to 17.52 pg DNA g −1 dm) was determined in 2017 ( Figure 2) and was related to the highest precipitation and a lower temperature in this year of the study. Species composition was also diverse in individual years of the study.  Figure 3). Figure S1 shows the example of a chromatogram of mycotoxin standards and mycotoxins detected under the herbicide treatment of wheat in 2020. The total level of mycotoxins was the highest in 2018 (983 µg kg −1 for the control) and the lowest in 2017 (13.5 µg kg −1 for the sulfonylurea herbicide combined with morpholine and triazole fungicides). Generally, treatments with morpholine and triazole fungicides were the most effective in reducing the total amount of mycotoxins (13.5 µg kg −1 , 278.5 µg kg −1 , 314.1 µg kg −1 , 280.6 µg kg −1 in 2017-2020, respectively; reduction of 53%, 72%, 62%, 69%, respectively). In 2020, the lowest total precipitation and Fusarium spp. concentration, but also the greatest level of mycotoxins, were observed. Interestingly, despite the lack of fungicides application, the sulfosulfuron treatment combined with a humic biostimulator (H + S) reduced mycotoxins content to 466.8 µg kg −1 in 2018 (27%), 589.8 µg kg −1 in 2019 (12%), and 671.5 µg kg −1 in 2020 (2%), compared to exclusive herbicide application ( Figure 3).  Figure 3). Figure S1 shows the example of a chromatogram of mycotoxin standards and mycotoxins detected under the herbicide treatment of wheat in 2020. The total level of mycotoxins was the highest in 2018 (983 µg kg −1 for the control) and the lowest in 2017 (13.5 µg kg −1 for the sulfonylurea herbicide combined with morpholine and triazole fungicides). Generally, treatments with morpholine and triazole fungicides were the most effective in reducing the total amount of mycotoxins (13.5 µg kg −1 , 278.5 µg kg −1 , 314.1 µg kg −1 , 280.6 µg kg −1 in 2017-2020, respectively; reduction of 53%, 72%, 62%, 69%, respectively). In 2020, the lowest total precipitation and Fusarium spp. concentration, but also the greatest level of mycotoxins, were observed. Interestingly, despite the lack of fungicides application, the sulfosulfuron treatment combined with a humic biostimulator (H + S) reduced mycotoxins content to 466.8 µg kg −1 in 2018 (27%), 589.8 µg kg −1 in 2019 (12%), and 671.5 µg kg −1 in 2020 (2%), compared to exclusive herbicide application ( Figure 3).    Deoxynivalenol (DON) was predominant only in 2017, while NIV was determined to have the highest concentration in 2018-2020 (Table 3). Additionally, HT-2, FUM B1, and FUM B2 were noticed only in 2017.

Weed Infestation
Weed infestation is a main factor affecting crop quantitative and qualitative parameters. Thus, exclusive fungicidal treatments are not performed in agricultural practice. In the four-year period of the research, seven common weed species were noticed: Capsella bursapastoris, Chenopodium album, Polygonum aviculare, Anagalis arvensis, Setaria glauca, Fallopia convolvulus, and Veronica arvensis. The number of weeds was the highest in 2017 (up to 84 pieces per 1 m 2 ) and was caused by the greatest precipitation (293 mm).
Biostimulator application resulted in the greatest biomass of weeds compared to the control (430 g) (Figure 4). Herbicide combined with fungicides and enriched by a humic biostimulator caused a higher number and biomass of weeds compared to the treatment without biostimulator addition (84 pieces per 1 m 2 and 145 g, a 44% increase). Interestingly, the most efficient reduction of weed infestation in 2017-2020 was noticed for the sulfonylurea treatment combined with morpholine and triazole fungicides (up to 12 pieces per 1 m 2 and 16 g in 2019). However, weed biomass is a more effective method for weed infestation evaluation. Deoxynivalenol (DON) was predominant only in 2017, while NIV was determined to have the highest concentration in 2018-2020 (Table 3). Additionally, HT-2, FUM B1, and FUM B2 were noticed only in 2017.

Weed Infestation
Weed infestation is a main factor affecting crop quantitative and qualitative parameters. Thus, exclusive fungicidal treatments are not performed in agricultural practice. In the four-year period of the research, seven common weed species were noticed: Capsella bursa-pastoris, Chenopodium album, Polygonum aviculare, Anagalis arvensis, Setaria glauca, Fallopia convolvulus, and Veronica arvensis. The number of weeds was the highest in 2017 (up to 84 pieces per 1 m 2 ) and was caused by the greatest precipitation (293 mm).
Biostimulator application resulted in the greatest biomass of weeds compared to the control (430 g) (Figure 4). Herbicide combined with fungicides and enriched by a humic biostimulator caused a higher number and biomass of weeds compared to the treatment without biostimulator addition (84 pieces per 1 m 2 and 145 g, a 44% increase). Interestingly, the most efficient reduction of weed infestation in 2017-2020 was noticed for the sulfonylurea treatment combined with morpholine and triazole fungicides (up to 12 pieces per 1 m 2 and 16 g in 2019). However, weed biomass is a more effective method for weed infestation evaluation.

Economic Optimum Rates of Different Protection Strategies
Economic calculations indicated that all protection strategies were profitable in agricultural practice (E > 1), except for the exclusive biostimulator treatment (E = −1.55) ( Figure 5). However, the greatest economic efficiency was noticed in the case of the exclusive sulfosulfuron treatment (E = 3.36) despite the lowest saved production value (98.07 € for 0.6 t ha −1 ). Moreover, the highest yield saved (1.2 t ha −1 ) and the greatest saved production value (196.15 €) due to the protection strategies were determined in the herbicidal and fungicidal treatment combined with a biostimulator (H + F1 + F2 + S). Furthermore, taking under consideration the total costs of the treatment and the greatest minimum yield, the lowest economic efficiency among the chemical trials was noticed for sulfonylurea, morpholine, and triazoles (H + F1 + F2) (E = 2.41) ( Figure 5).

Economic Optimum Rates of Different Protection Strategies
Economic calculations indicated that all protection strategies were profitable in agricultural practice (E > 1), except for the exclusive biostimulator treatment (E = −1.55) ( Figure  5). However, the greatest economic efficiency was noticed in the case of the exclusive sulfosulfuron treatment (E = 3.36) despite the lowest saved production value (98.07 € for 0.6 t ha −1 ). Moreover, the highest yield saved (1.2 t ha −1 ) and the greatest saved production value (196.15 €) due to the protection strategies were determined in the herbicidal and fungicidal treatment combined with a biostimulator (H + F1 + F2 + S). Furthermore, taking under consideration the total costs of the treatment and the greatest minimum yield, the lowest economic efficiency among the chemical trials was noticed for sulfonylurea, morpholine, and triazoles (H + F1 + F2) (E = 2.41) ( Figure 5).

Statistical Analysis
In order to understand the significance of the results obtained, statistical analysis was performed. Figure 6a,b shows the PCA analysis indicating the influence of the type of chemical treatment, temperature, and precipitation on yield, ergosterol content, Septoria tritici blotch, eyespot, sharp eyespot, Fusarium spp., mycotoxins concentration in grain, weed number, and biomass in wheat cultivation in 2017-2020. The principal component analysis explained 71.27% of the total variability among all the examined parameters and 68.54% of the variability between the mycotoxins, Fusarium spp., and climatic conditions. During the four-year study, in 2017, the highest precipitation, disease severity, and Fusarium spp. concentration along with the lowest temperature and level of mycotoxins were observed. The heatmap of the examined parameters based on Pearson's correlation coefficients indicated a positive correlation between precipitation and Septoria tritici blotch, eyespot, and sharp eyespot (r = 0.9, r = 0.64, r = 0.83, respectively) (Figure 6c). Additionally, a correlation between eyespot and sharp eyespot (r = 0.86) was determined. Moreover, a positive correlation between precipitation and Fusarium spp. (r = 0.69) was indicated and a negative correlation was observed between precipitation and mycotoxins (r = −0.73). Weed number and biomass were positively correlated with precipitation (r = 0.64; r = 0.49, respectively), Septoria tritici blotch (r = 0.68; r = 0.47, respectively), sharp eyespot (r = 0.49; r = 0.42, respectively), and Fusarium spp. (r = 0.69; r = 0.74, respectively), and negatively correlated with temperature (r = −0.54; r = −0.29, respectively) and mycotoxins concentration (r = −0.43; r = 0.24, respectively). Ergosterol did not significantly correlate with any of the examined parameters, while wheat yield was positively correlated with temperature (r = 0.62) and eyespot (r = 0.51), and negatively correlated with Fusarium

Statistical Analysis
In order to understand the significance of the results obtained, statistical analysis was performed. Figure 6a,b shows the PCA analysis indicating the influence of the type of chemical treatment, temperature, and precipitation on yield, ergosterol content, Septoria tritici blotch, eyespot, sharp eyespot, Fusarium spp., mycotoxins concentration in grain, weed number, and biomass in wheat cultivation in 2017-2020. The principal component analysis explained 71.27% of the total variability among all the examined parameters and 68.54% of the variability between the mycotoxins, Fusarium spp., and climatic conditions. During the four-year study, in 2017, the highest precipitation, disease severity, and Fusarium spp. concentration along with the lowest temperature and level of mycotoxins were observed. The heatmap of the examined parameters based on Pearson's correlation coefficients indicated a positive correlation between precipitation and Septoria tritici blotch, eyespot, and sharp eyespot (r = 0.9, r = 0.64, r = 0.83, respectively) ( Figure 6c). Additionally, a correlation between eyespot and sharp eyespot (r = 0.86) was determined. Moreover, a positive correlation between precipitation and Fusarium spp. (r = 0.69) was indicated and a negative correlation was observed between precipitation and mycotoxins (r = −0.73). Weed number and biomass were positively correlated with precipitation (r = 0.64; r = 0.49, respectively), Septoria tritici blotch (r = 0.68; r = 0.47, respectively), sharp eyespot (r = 0.49; r = 0.42, respectively), and Fusarium spp. (r = 0.69; r = 0.74, respectively), and negatively correlated with temperature (r = −0.54; r = −0.29, respectively) and mycotoxins concentration (r = −0.43; r = 0.24, respectively). Ergosterol did not significantly correlate with any of the examined parameters, while wheat yield was positively correlated with temperature (r = 0.62) and eyespot (r = 0.51), and negatively correlated with spp. (r = −0.37). The four-year study indicated that 3-AcDON, 15-AcDON, DON, NIV, and ZON were negatively correlated with precipitation (up to r = −0.76), while HT-2 and FUM B1 were positively correlated (r = 0.75, r = 0.82, respectively) (Figure 6c). Our study indicated negative correlations between F. culmorum, F. avenaceum, and 3-AcDON, 15-Ac-DON, DON, NIV, and ZON (up to r = −0.71) and positive correlations between F. culmorum, F. avenaceum, and HT-2 and FUM B1 (up to r = 0.88). In the four-year study, F. graminearum was positively correlated with 3-AcDON, 15-AcDON, DON, NIV, and ZON.

Discussion
Despite the same pesticide/biostimulator protection during the four years of the study, precipitation and temperature had the most influence on the examined parameters and uncertainties between them. Moreover, biostimulator treatments are more sufficient in warmer years and higher air humidity decreases their efficacy.
Our results indicated an improvement of wheat yield after the application of a biostimulator based on humic acids. It was also determined that other biostimulators, e.g., with plant hormones, resulted in a higher yield [21], but algae extract and nitrophenol biostimulators have no effect or slightly reduce wheat yield if combined with pesticides [24]. Apart from sulfosulfuron in wheat, an improvement in yield was also indicated for pyrazosulfuron singly applied [25]. However, yield increase after herbicide application is not obvious. A lower wheat yield was determined under isoproturon protection [24].
The use of fungicides prior to the onset of disease symptoms was indicated to be the most effective strategy for controlling leaf diseases [26,27]. Biostimulators may promote mycorrhizal fungi growth but also indirectly contribute to the development of fungal plant pathogens, as revealed in our results. There are numerous studies showing the different effects of fungicides application on Fusarium spp. reduction; however, in field experiments, the efficacy of fungicides is often examined exclusively without herbicidal protection. It was noticed that 250 mg L −1 of propiconazole [28], metconazole (1 L ha −1 ), tebuconazole (1 kg ha −1 ), prochloraz (1.1 L ha −1 ), and prothioconazole (0.8 L ha −1 ) [29] singly applied are effective fungicides against Fusarium spp. Our results indicate that the use of a sulfonylurea herbicide (26.5 g ha −1 ) combined with propiconazole and cyproconazole (a total of 200 mL ha −1 ) and spiroxamine, tebuconazole, and triadimenol (a total of 600 mL ha −1 ) fungicides is the best strategy to reduce Fusarium spp. in wheat under field conditions ( Figure 2). Apart from fungicides, sulfosulfuron singly applied also reduced the amount of Fusarium spp. due to the reduction of weed number and humidity, which favors fungi development. Interestingly, glyphosate-based herbicides can intensify the colonization of crops by fungi due to glyphosate interactions with the metabolic pathways of selected microorganisms [30]. However, Sanyal et al. [31] observed a lower amount of Fusarium spp. on green pea after glyphosate treatment. This indicates that the severity of fungal diseases is dependent on the type of herbicide, plant species, and phytoalexins, which can interact with microorganisms.
In 2020, the lowest total precipitations and Fusarium spp. concentrations, but also the greatest level of mycotoxins, were observed, which indicates that, in contrast to some studies [32,33], Fusarium secondary metabolites are secreted in the climatic conditions (especially humidity) that are unfavorable for fungal growth [34]. Moreover, it can be assumed that despite a lower Fusarium spp. severity in drier years, mycotoxins concentration is higher in cereal cultivation. This shows that abiotic environmental stress conditions probably intensified the expression of mycotoxin co-products in fungal biosynthesis pathways. To the best of our knowledge, this is the first study indicating lower mycotoxins contamination due to herbicidal protection combined with a humic biostimulator (Table 3, Figure 3). It was also previously indicated that herbicide MCPA can decrease the concentration of 3-AcDON and ZON mycotoxins in wheat grain [8]. In addition to our results, it was noticed that prothioconazole (87.5 g ha −1 ), azoxystrobin (60 g ha −1 ), and fluxapyroxad (40 g ha −1 ) limit mycotoxins concentration in wheat grain [35]. Moreover, treatments based on epoxiconazole (0.5 L ha −1 ), pyraclostrobin (0.5 L ha −1 ) and, mancozeb (1 kg ha −1 ) did not reduce mycotoxins concentration or even induce DON amount [36]. We concluded that treatment including sulfosulfuron (750 g L −1 ), propiconazole (250 g L −1 ), cyproconazole (80 g L −1 ), spiroxamine (250 g L −1 ), tebuconazole (167 g L −1 ), and triadimenol (43 g L −1 ) (H + F1 + F2) is the best strategy to most effectively reduce mycotoxins accumulation in cereals; however, humic biostimulator addition to the herbicidal protection can also decrease mycotoxins concentration. Our results indicate that the level of particular mycotoxins in different years may be diverse depending on the type of treatment, climatic condition during crop season, or occurrence of variable Fusarium spp. and other fungi which secrete different profiles of secondary metabolites [37].
Moreover, it was noticed that ergosterol concentration increases during grains ageing and can be dependent on precipitation [30]; however, our study did not confirm the relation of ergosterol to climatic conditions, though a slight positive correlation with mycotoxins content was indicated (r = 0.32) during the four-year study. The number of weeds was the highest in 2017 (up to 84 pieces per 1 m 2 ) and was caused by the greatest precipitation (293 mm). The biostimulator also contributed to a greater weed infestation compared to treatments without its use. This results from the non-selective action of biostimulators, which promote wheat growth but also indirectly contribute to the increased development of weeds [38]. Similar to some other studies [39], biostimulator addition is not effective in weed control as it often causes higher weed infestation and, as a consequence, the development of fungal diseases. However, in contrast to amidosulfuron, iodosulfuron, mefenpyr-diethyl, and propoxycarbazone-sodium herbicides combined with prochloraz, tebuconazole, and proquinazid [40,41], sulfosulfuron protection combined with fungicides was the most effective in weed infestation reduction compared to single herbicide application. However, weed infestation was not observed after the application of biostimulator ComCat based on plant extracts [42].
In contrast to a "from field to fork" strategy, more complex chemical protection including herbicides and fungicides can contribute to better wheat parameters. As indicated by Hossard et al. [43], the reduction of pesticides dose by 50% caused a lower wheat yield (up to 10%); therefore, efficient programs should be developed which are based on different classes of biostimulators and could replace or modulate the positive effects of pesticides on target plants' protection. Moreover, integrated plant management with crop rotation can also increase yield and contribute to the reduction of weed infestation. Brankov et al. [44] confirmed that crop rotation with winter wheat caused a higher yield and lower weed infestation in maize cultivation. Moreover, the tillage system of crop production reduced disease severity and the concentration of the DON mycotoxin in wheat with a maize rotation system [45].
Many studies aim to minimize diseases' severity and achieve the greatest yields in different protection strategies and diversified climatic conditions. However, there are not many reports showing the economic proficiency of the results obtained in agricultural practice [46]. The findings indicated in this study enabled a compromise between the most desired protection strategy with high quality yield, low diseases severity, mycotoxins concentration, and the most beneficial economic profitability. Therefore, it can be assumed that complex protection including sulfonylurea herbicides combined with morpholine and triazole fungicides and a humic biostimulator best meets these conditions.

Conclusions
Optimal chemical/biostimulator protection is crucial for obtaining safe and healthy wheat grain with low fungal diseases severity and mycotoxins level. The results of our research are a response to the current problems in the cultivation of wheat affected by fungal diseases and weeds, and therefore may have a universal character in the countries of Central and Eastern Europe. Despite the same chemical/biostimulator protection, differences related to climatic conditions of East-Central Europe in yield, disease severity, Fusarium spp. concentration, and mycotoxins level were observed in individual years of the study. Complex chemical treatment, including a sulfonylurea herbicide, morpholine, and triazole fungicides, is the most effective strategy to obtain high yield and wheat grain of good quality with a low level of fungi and mycotoxins contamination. Furthermore, the addition of a humic biostimulator reduced mycotoxins level in herbicidal treatment, but negative effects, such as fungal diseases and higher weed infestation, were observed in the treatments enriched with a biostimulator. The effectiveness of the positive action of the humic biostimulator depends on climatic conditions. Exclusive sulfonylurea treatment had a relatively high disease severity and mycotoxins level. However, considering economic profitability, herbicidal treatment combined with fungicides and a biostimulator is the most valuable and has the greatest saved production value. These research findings indicated that humic biostimulators can support chemical treatment in the reduction of mycotoxins and fungal diseases in particular climatic conditions and could be implemented in agricultural practice.
(MRM) was conducted to determine all mycotoxins. For each mycotoxin, the precursor ion and two product ions were determined: one product ion for quantification and one for qualification (Table A1).