For acetic acid vapour treatments, three 300 g subsamples from the same seed lot and from the same block were placed directly in three 23 L chambers (one subsample per chamber): one for the low dose of acetic acid, one for the high dose, and one with no acetic acid that was used as control in which a humidity/ temperature probe was placed. The latter sample was not included in the study since it was only used to monitor relative humidity (RH) and temperature in the two other chambers in which no probe could be added as acetic acid affects it. Sterile distilled water was added to all the chambers, and RH and temperature were monitored in the control chamber. The assumption was that all chambers were similar and therefore so were RH and temperature. When RH remained constant (i.e. at approximately 50 to 60%), acetic acid was added to the treatment chamber. An initial amount of acetic acid was added at the start of the treatment and additional amounts were added as required to maintain the amount of acetic acid vapour above approximately 10 mg L^-1 of headspace for the low dose and 20 mg L^-1 for the high dose. The level of acetic acid in the chamber was monitored using a gas chromatograph. After 120 min of treatment, the chambers were vented, and the seeds were placed in paper bags and left to dry and degas overnight at room temperature, before being stored at 4°C.

For the dry heat treatment, seeds from each subsample were placed in a 21.6 cm × 27.9 cm envelope that was placed flat on the shelf of a dryer set at 70°C for 5 d. All envelopes from the same block were placed on the same shelf. After the treatment, the envelopes were removed and stored at 4°C.

Vitaflo®-280 (carbathiin 0.514 mL a.i. kg^-1 of seeds/thiram 0.437 mL a.i. kg^-1) was applied on seeds one subsample at a time. After treatment, seeds were stored at 4°C.

To evaluate the effect of treatments on F. graminearum contamination, 50 seeds per subsample were plated onto potato dextrose agar medium (PDA Difco) (seven to eight seeds per Petri dish). Dishes were placed under fluorescent light (23 cm away from the light), with a photoperiod of 16 h at room temperature (20-22°C) for 7 d. After the incubation period, seeds showing Fusarium mycelia were counted and an agar plug (0.5 cm diam) containing actively growing mycelia was transferred onto sucrose nutrient agar (SNA; Nirenberg 1981) to identify F. graminearum based on the descriptions by Nelson et al. (1983) and, consequently, to determine the number of seeds infected by F. graminearum. To evaluate B. sorokiniana contamination rates, 50 additional seeds per subsample were plated onto PDA-benomyl medium as described by Pouleur and Couture (2013). After 7 d of incubation in darkness at room temperature, the number of seeds showing typical B. sorokiniana dark green mycelia and conidia were directly counted.

One hundred seeds per subsample of each treatment were planted in a sand substrate in five seed trays (32.4 cm wide × 52.7 cm long × 7.9 cm deep), with 20 seeds per tray. Each tray contained five rows of 20 seeds, each row corresponding to the five treatments per block per lot. The experimental unit was the 100 seeds planted in the five trays. The trays were placed in a growth cabinet in which temperature was maintained at 25°C, with 75% RH, a 13,000 lux light intensity, and a 16 h photoperiod. Trays were watered as needed during the first few days, then every day thereafter. Fertilization consisted in applying a solution of 2.5 g L^-1 of 20-20-20 (Plant-Prod, Brampton, ON) in tap water 7 d, 10 d and 16 d after planting. Germination rate was estimated 7 d after seeding and, 14 d later, seedling emergence, root rot index and yield (aerial parts) of the 21-d-old seedlings were assessed. For assessing root rot, each seedling emerging from the 100 seeds planted was rated according to the 0-9 Horsfall-Barratt scale (Horsfall and Barratt 1945), and a root rot index was calculated using the following formula: ∑ (class x number of plants in class) / total number of seedlings assessed. The aerial parts of the seedlings were placed in separate paper bags for each treatment combination and replicate, and dried at 70°C for 48 h before being weighed.

Each year, both the barley and wheat seed lots were tested in separate experiments using a randomized complete block design with four blocks. Experiments were conducted using organic fertilizer and mechanical weed control. They were conducted in the province of Quebec, Canada, at two locations: at the Centre de recherche sur les grains (CÉROM), Saint-Mathieu-de-Beloeil (45°34'N; 73°12'W), on heavy clays of the Saint-Urbain series (Humaquept), and at the Agronomy Research Station of Université Laval, Saint-Augustin-de-Desmaures (46°45'N; 71°27'W), on sandy loams of the Tilly series (Haplorthod). The experimental unit in Saint-Mathieu consisted of five 6-m-long rows, with 18 cm between rows, and the one in Saint-Augustin consisted of four 5-m-long rows, also with a row spacing of 18 cm. Seeding rates were 375 seeds m^-2 for barley and 425 seeds m^-2 for wheat. In Saint-Mathieu, plots were planted on 13 May 2010, 25 May 2011, and 18 May 2012, and in Saint-Augustin they were planted on 19 May 2010, 12 May 2011, and 19 May 2012. A nitrogen contribution of 25 kg N ha^-1 was provided by a previous soybean crop and was supplemented with dry granular poultry manure (Acti-Sol^TM; Acti-Sol Inc., Saint-Wenceslas, QC) applied before planting at 55 kg N ha^-1 for barley and 75 kg N ha^-1 for wheat. The manure contained 36.8 g P₂O₅ kg^-1 and 30.2 g K₂O kg^-1. For weed control, a tillage operation with a tine harrow was carried out before seedling emergence at both locations, and once more in Saint-Augustin at the three-leaf stage (Zadoks stage 13; Zadoks et al. 1974). Grain was harvested at maturity (Zadoks stage 92; Zadoks et al. 1974) on 13 August 2010, 2 September 2011, and 16 August 2012 for barley in Saint-Mathieu, on 20 August 2010, 2 September 2011, and 18 August 2012 for wheat in Saint-Mathieu, on 11 August 2010, 13 August 2011, and 14 August 2012 for barley in Saint-Augustin, and on 19 August 2010, 24 August 2011, and 23 August 2012 for wheat in Saint-Augustin.

To determine seedling emergence, seedlings were counted along 1 m on three rows at the three-leaf stage. At maturity, plots were windrowed, harvested, and grain weight was measured to determine yield. Thousand-kernel weight and test weight were determined for each plot based on the methods described in the Official Grain Grading Guide (Canadian Grain Commission 2011).

Data from each seed lot were analyzed separately. For data collected in the laboratory and growth cabinet tests, an analysis of variance was carried out using the GLM procedure of SAS (SAS Institute Inc. 2010). For field experiments, the combined data of Saint-Mathieu and Saint-Augustin were subjected to an analysis of variance using PROC MIXED of SAS, in which seed treatments and locations were considered fixed effects and the four blocks were considered random effects. When significant (P < 0.05), treatment means were compared using Fisher’s protected least significant difference (LSD) test.

For all barley seed lots, both AAV treatments and dry heat reduced F. graminearum contamination when compared with the control, whereas Vitaflo®-280 had no effect (Fig. 1A). For the three lots highly contaminated with F. graminearum (Nd, Newdale1 and Tradition), AAV-L, AAV-H, and dry heat reduced contamination below the Fusarium spp. infection threshold of 15%, above which lots should be rejected as seed (rejection threshold) according to Nielsen (2000). In the present study, we used a rejection threshold of 15% for F. graminearum. AAV-H also reduced the level of B. sorokiniana contamination in five barley lots, and AAV-L did so in three barley lots, whereas dry heat was not effective (Fig. 1B). In barley, Vitaflo®-280 decreased the level of contamination under the rejection threshold of 30% in two of the four lots highly (> 50%) contaminated by B. sorokiniana (Newdale2 and AC Hawkeye; Fig. 1B). Among those highly contaminated seed lots, AAV-H reduced the level of infection below the threshold for AC Hawkeye only, while AAV-L and dry heat did not do so in any of the seed lots.

In wheat, all treatments, including Vitaflo®-280, reduced F. graminearum contamination to levels below the rejection threshold of 15% in three of the highly contaminated seed lots (AC Barrie, AC Brio2 and Torka; Fig. 2A), with the exception of Vitaflo®-280 in the AC Barrie seed lot. For B. sorokiniana, AAV-H significantly decreased its detection in four of the six wheat lots, and AAV-L and dry heat did so in two seed lots (Fig. 2B).

For barley, Vitaflo®-280 was generally less effective at reducing F. graminearum contamination compared with B. sorokiniana. The lack of efficacy of Vitaflo®-280 against seed-borne F. graminearum was in agreement with previous research conducted on winter wheat (Duthie and Hall 1985). In contrast, Vitaflo®-280 was found to decrease the level of B. sorokiniana contamination under the rejection threshold of 30% for all highly contaminated wheat lots (AC Brio1, Orléans1, Torka, and Orléans2; Fig. 2B), whereas dry heat could only do so in one lot (Orléans2), and none of the AAV treatments had any effect on any of the seed lots.

For organic barley and wheat production, AAV-H seems to be the most promising treatment because it could reduce both pathogens, whereas dry heat was effective for the control of seed-borne F. graminearum, but had little to no effect on B. sorokiniana in wheat and barley lots, respectively. The efficacy of dry heat in controlling F. graminearum in wheat and barley seeds is in accordance with the results reported by Clear et al. (2002). The tolerance of B. sorokiniana in cereal seeds heated at 70°C for a few days was also observed in previous studies (Couture and Sutton 1980; Clear et al. 2002). The difference between B. sorokiniana and F. graminearum in their tolerance to heat treatment or desiccation might be due to differences in their cell components, cell wall or other parts of mycelial cells or spores.

For barley and wheat, the AAV-L, dry heat and Vitaflo®-280 treatments either increased seed germination or had no effect when compared with the control (Tables 2 and 3). Seed germination was improved by AAV-H in one barley lot (Newdale2; Table 2), but was reduced by this treatment in three wheat lots (AC Brio1, Orléans1 and Orléans2; Table 3) and in the AC Hawkeye hulless barley seed lot (Table 2); the four latter lots (AC Brio1, Orléans1, Orléans2 and AC Hawkeye) were highly contaminated with B. sorokiniana (Tables 2 and 3). Furthermore, in a wheat seed lot slightly contaminated with F. graminearum (11%) and B. sorokiniana (18%) (data not shown), germination was also reduced by AAV-H. Thus, AAV-H may damage embryos to such an extent as to reduce seed germination in hulless species like wheat or hulless barley cultivars such as AC Hawkeye. In previous studies (Pouleur et al. 2008), AAV-L had no effect on seed germination. A higher dose was tested in the present study with the objective of improving the efficacy of AAV in controlling B. sorokiniana in seeds. Emergence was assessed 14 d later and was lower in AAV-H than in the control for two (AC Brio1 and Orléans2; Table 3) of the four seed lots where germination was affected by AAV-H. In addition, there was no difference in aboveground leaf biomass between the AAV-H treatment and the control in three of those four seed lots (AC Hawkeye, Orléans1, Orléans2; no data available for AC Brio1). Perhaps the surviving seedlings compensated for those that did not emerge.

For barley (Table 2), except for AC Hawkeye, AAV-H, dry heat and Vitaflo®-280 had higher emergence and leaf yield than the control, while similar trends were observed with AAV-L in seed lots highly contaminated with F. graminearum (Nd, Newdale1, and Tradition). For AC Hawkeye, there were no differences between treatments for leaf yield, and only Vitaflo®-280 increased emergence whereas the other treatments were not different from the control. In wheat (Table 3), emergence and leaf yield of seed lots highly contaminated with F. graminearum (AC Barrie [emergence only], AC Brio2, and Torka) increased under all treatments, except for AAV-H and Torka where there was no effect. For the other seed lots (AC Brio1, Orléans1, and Orléans2), treatments either improved, reduced (AAV-H), or had no effect on emergence and leaf yield. Vitaflo®-280 increased leaf yield in three out of four barley lots (Table 2), and in three out of four wheat lots (Table 3), while AAV-H increased leaf yield in three barley lots and one wheat lot. Finally, dry heat increased leaf yield in three barley and two wheat lots, while AAV-L did so in one barley and two wheat lots.

Root rot index was lower or remained unchanged under seed treatment as compared with the control (Tables 2 and 3). Treatment with AAV-H or Vitaflo®-280 reduced root rot index in four barley and four wheat lots, while AAV-L and dry heat reduced root rot index in three barley and three wheat lots. AAV-H was more efficient than Vitaflo®-280 at controlling root rot in three barley lots and two wheat lots, while AAV-L and dry heat were more efficient than Vitaflo®-280, but only in one barley seed lot (Nd lot; Table 2).

For barley, emergence and root rot index results illustrated a significant impact of seed treatments compared with the control treatment for seed lots infected by F. graminearum, whereas seed treatments generally appeared less efficient for seed lots infected by B. sorokiniana. According to the laboratory and cabinet trials, AAV-H seems to have the best potential to improve phytosanitary seed quality and, consequently, to reduce root rot, but it may have deleterious effects on the embryos of hulless cereals.

In the field experiments, emergence was either increased, unchanged, or decreased by the treatments (Tables 4 and 5). AAV-H had a negative effect on emergence in the barley and wheat seed lots in which it reduced germination (AC Hawkeye (Table 4); AC Brio1, Orléans1, and Orléans2 (Table 5)), and also in the Nd barley seed lot (Table 4). For AC Hawkeye, all non-chemical treatments had a negative effect on emergence, while Vitaflo®-280 enhanced this variable compared with the control. In the Newdale seed lots, treatment responses varied (Table 4). For example, compared with the control, AAV-L, AAV-H, and Vitaflo®-280 significantly increased emergence in Newdale1, while dry heat and Vitaflo®-280 increased emergence in Newdale2. In the barley seed lot Tradition (Table 4) and in the wheat lot AC Barrie (Table 5), treatments had no effect on emergence as compared with the control. In general, dry heat, Vitaflo®-280 and AAV-L increased emergence in the other wheat lots (Table 4); however, with AAV-L, this increase was not significant in AC Brio1 and Orléans2, and a similar trend was observed with Vitaflo®-280 in AC Brio 2.

In contrast to leaf yield responses assessed in the growth cabinets, seed treatments had no significant positive effects on grain yield in any of the twelve lots tested (Tables 4 and 5). Better efficacy of seed treatments under controlled versus field conditions has been reported previously (Celetti and Hall 1987; Mihuta-Grimm and Forster 1989). In the present study, the drier conditions deliberately used in the growth cabinets with a sand substrate that promotes root diseases may explain the differences observed between the two environments (in the cabinets and in the field). Fernandez et al. (2010) also observed that seed treatments were less effective at reducing root discoloration caused by seed-borne Fusarium spp. and B. sorokiniana in a year when precipitation and mean temperature in late spring and early summer were higher than in the other years of the study. Also, in our field experiments, other soil-borne pathogens that were not present in the sand substrate may have interfered and caused root diseases and, consequently, masked the beneficial effect of the seed treatments. AAV-H, which affected germination in three wheat seed lots (Table 3) and in the hulless barley seed lot (Table 2), also decreased grain yield in two of these seed lots (AC Brio1 and Orléans2; Table 5), for an average yield reduction of 9%.

In general, there were no treatment effects on 1000-kernel weight, except for a negative effect of AAV-L in the Nd barley seed lot (Table 4), and a positive effect of dry heat in the Orléans1 wheat seed lot (Table 5). Similarly there was no effect of treatments on test weight, except for a negative effect of AAV-L, AAV-H, and dry heat in the AC Hawkeye barley seed lot (Table 4).

Results from the present study show that it is more difficult to control B. sorokiniana than F. graminearum in cereal seed. All non-chemical treatments could reduce F. graminearum, whereas Vitaflo®-280 was less effective, especially in barley. Dry heat appears to be a relatively easy method to use for cereal seed disinfection, and it has been routinely used since 2000 for the treatment of cereal seed lots by the Seed Increase Unit at the Indian Head Research Farm, Agriculture and Agri-Food Canada, Indian Head, SK (Agriculture and Agri-Food Canada 2011; Gehl 2007). However, for the majority of the lots tested in the present study, and based on the results of previous studies (Clear et al. 2002), the dry heat treatment has no effect on B. sorokiniana. For reducing the impact of B. sorokiniana, Vitaflo®-280 was the most effective treatment. Among the non-chemical treatments, AAV-H decreased the detection of B. sorokiniana in the greatest number of seed lots tested but this reduction, except for one barley lot, was not below the rejection threshold of 30% for seed lots highly contaminated with this pathogen. Moreover, AAV-H should not be used for hulless types of cereals since it could reduce their germination. Further research is needed in order to find treatment methods that are both acceptable for organic farming and effective at controlling F. graminearum and B. sorokiniana in wheat and barley.