A G R I C U LT U R A L  A N D  F O O D  S C I E N C E
W. König et al. (2019) 28: 155–164

155

Effects of sodium nitrite treatment on the fermentation 
quality of red clover-grass silage harvested at two dry matter 

concentrations and inoculated with clostridia
Walter König, Emilia König, Kari Elo, Aila Vanhatalo and Seija Jaakkola

Department of Agricultural Sciences, P.O. Box 28, FI-00014 University of Helsinki, Finland

e-mail: walter.konig@helsinki.fi

Legumes are particularly susceptible to clostridial fermentation when ensiled because of their high buffering capacity 
and water-soluble carbohydrate contents. The aim of the study was to investigate if a sodium nitrite treatment (900 
g t-1 herbage in fresh matter [FM]) impairs butyric acid fermentation of red clover-timothy-meadow fescue silage 
compared with formic acid-treated (4 l t-1 FM) and untreated silage. The sward was harvested after wilting at low 
dry matter (DM) (LDM, 194 g kg-1) and high DM (HDM, 314 g kg-1) concentrations and half of the herbage batches 
were inoculated with Clostridium tyrobutyricum spores before additive treatments. No butyric acid fermentation 
was observed in HDM silages probably because of the relatively high DM and nitrate contents of the herbage mix-
ture. In LDM silage butyric acid was detected only in formic acid-treated silage, and the number of clostridia copies 
was higher in formic acid-treated than in sodium nitrite treated silage. Sodium nitrite treatment was superior to FA 
treatment in suppressing clostridial fermentation in the LDM silages. 

Key words: clostridia, formic acid, nitrite, silage additive, legumes

Introduction
Clostridia can be found in silage primarily because of soil and slurry contamination during harvesting. They can 
be either saccharolytic or proteolytic, and some consume lactic acid, which causes an undesirable rise in silage 
pH (Muck 2010). Clostridial growth in silage is favoured by high ambient temperature (> 25–30 °C), high buffering 
capacity (BC), and low dry matter (DM) and water-soluble carbohydrate (WSC) contents of forage (Pahlow et al. 
2003). Clostridia form spores that can survive harsh conditions like low pH values. At the vegetative stage they in 
many ways reduce silage nutritive value and cause health problems for animals (Queiroz et al. 2018) and problems 
for semi-hard and hard cheese production (Driehuis 2013). 

Weissbach et al. (1974) discovered that increasing herbage DM content and fermentability coefficient (FC) higher 
than 45 predicts butyric acid-free silages. The FC combines herbage DM and the quotient of WSC/BC by the for-
mula: FC = DM (g kg-1)/10 + 8 × WSC (g kg-1 DM)/BC (g kg-1 DM) (Schmidt et al. 1971) provided that herbage nitrate 
content is ≥ 4.4 g kg-1 DM (Kaiser and Weiss 1997). Nevertheless, Driehuis and van Wikselaar (2000) found butyric 
acid amounts up to 18.7 g-1 kg DM in silages with a DM content ranging from 368 to 674 g-1 kg DM. The explanati-
on could be related to herbage and silage osmolality (Hoedtke 2007). Osmolality is defined as the number of so-
lute particles in one kg of solvent (Koeppen and Stanton 2012). According to Xiao et al. (2017) increasing external 
osmolality restricts bacterial cell growth. Since lactic acid bacteria have a better osmotolerance than clostridia, 
higher external osmolality has a positive effect on improving silage quality (Hoedtke 2007). The pH value which 
impairs clostridia growth decreases with decreasing DM content of the ensiled forage. In addition, the inhibitive 
effect of pH depends on the clostridia species, type of acid, and particularly on the concentration of undissociat-
ed acid molecules as reviewed by McDonald et al. (1991). Formic acid (pKa 3.77) has a stronger acidity than, e.g. 
acetic acid (pKa = 4.8), but the concentration of the undissociated molecules is lower compared to other alipha-
tic carboxylic acids at same pH levels (Lück and Jager 1995). This may explain at least partly the differences in the 
effects of formic acid in inhibiting clostridia and butyric acid fermentation.

The antimicrobial effect of sodium nitrite is based on the released nitrous acid and the disproportionation reac-
tion of nitrous acid into nitrate and nitric oxide (Quastel and Woolridge 1927). Nitric oxide and nitrite bind to the 
amino groups of the dehydrogenase system of the microbe cell (e.g. pyruvate dehydrogenase complex) which im-
pairs cell growth (Woods et al. 1981, Woods and Wood 1982). Lactic acid bacteria do not possess a pyruvate de-
hydrogenase system. They are utilizing a lactate dehydrogenase instead of forming lactate from pyruvate (Garvie 
1980). The pyruvate dehydrogenase is more receptive to nitric oxide than lactate dehydrogenase, and therefore, 
lactic acid bacteria are more resistant to nitrite than clostridia.

Manuscript received September 2019



A G R I C U LT U R A L  A N D  F O O D  S C I E N C E
W. König et al. (2019) 28: 155–164

156

Silage quality along with aerobic stability has increased when a mixture of sodium nitrite (SN) and hexamethyle-
ne tetraamine (HMTA) and SN together with sodium benzoate (SB) and sodium propionate (SP) have been used 
as silage additive (Hellberg 1967, Lingvall and Lättemäe 1999, Knicky and Spörndly 2009). Hexamethylene tetraa-
mine releases formaldehyde which can react in diverse ways with amino acids, proteins and enzymes. However, 
according to Knicky and Spörndly (2009) and König et al. (2019), the addition of HMTA to SN-mixtures did not 
improve silage quality. 

The preservation of legumes is challenging because of low DM content, high buffering capacity, relatively low WSC 
content and low nitrate content (König et al. 2017). Therefore, butyric acid fermentation in legume silages is com-
mon (Driehuis 2013). König et al. (2017) found that an additive based on a mixture of hexamethylene tetraamine 
(HMTA) and sodium nitrite (SN) impaired clostridia populations in white lupin-wheat silages more effectively than 
formic acid. The effect was not depending on the DM of the herbage. Red clover is the most commonly used fo-
rage legume for silage production in Finland. However, little information is available on how sodium nitrate as a 
sole additive inhibits clostridial fermentation in red clover-based silage harvested at different DM concentrations.

The main target of this study was to investigate if a sodium nitrite solution improves red clover-grass silage quality 
and impairs butyric acid fermentation compared with formic acid-treated and untreated silage. Two experiments 
were conducted to study the effect of additive treatments on the quality of wilted low dry matter (LDM, targe-
ting at 200 g kg-1) and wilted high dry matter (HDM, targeting at 300 g kg-1) silage without and with inoculation of 
clostridia spores. We hypothesized that irrespective of the DM content of ensiled herbage (200 or 300 g kg-1) 1) 
both sodium nitrite and formic acid reduce butyric acid fermentation products and clostridia spores compared to 
the untreated control silage and 2) sodium nitrite treatment is superior to formic acid treatment for its effect on 
butyric acid amount and clostridia spore counts in silage. 

Material and methods
Treatments and silage preparation

The study comprised two ensiling experiments. The field area used for the experiments was a second-year legu-
me-grass mixture of red clover (Trifolium pratense), timothy (Phleum pratense) and meadow fescue (Festuca pra-
tensis) at the Viikki Research Farm of the University of Helsinki, Finland (60°N, 25°E). The field was not fertilized in 
spring. The grass was cut on 9th of August 2016 as a second cut of the summer using a disc mower (Krone EasyCut 
3210 CV, Maschinenfabrik Bernard Krone GmbH, Spelle, Germany). Representative samples were collected from 
the experimental field area for botanical analyses before harvesting. The samples were taken from six randomly 
chosen areas of 0.25 m2 of size.

After cutting the herbage was wilted on the field in experiment 1 (Exp. 1) for 21 hours to get a low DM (LDM) si-
lage and in experiment 2 (Exp. 2) for 45 h to get a high DM (HDM) silage. During wilting, the weather was partly 
cloudy with some light rain showers and average temperature was 18 °C. After wilting, a batch of the herbage was 
gathered from the field and chopped using a laboratory chopper (Winter climbers®, Ried Im Innkreis, Austria) to 
give a chop-length of 1–4 cm. After that, the herbage was thoroughly mixed, and a batch of herbage for each silo 
was randomly collected, weighed and filled into a 1.5 l glass silo (Weck®, Wher-Oflingen, Germany). Four replica-
te silos were made per treatment. The fermentation gases were allowed to leak through the rubber seal between 
glass silo and lid. The amount of herbage filled into a silo was 900 g (LDM) and 750 g (HDM). The density of the 
LDM and HDM compacted herbage was 119 kg DM m-3 and 157 kg DM m-3, respectively.

Clostridium tyrobutyricum spores were produced (Bionautit, Helsinki, Finland) and used to inoculate the herba-
ges before ensiling to increase the challenge for silage additives. C. tyrobutyricum strain DSM 2637 was obtained 
from the Leibniz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbH. Strain DSM 2637 
was transferred into 5 ml of RCM broth (Reinforced Clostridium Medium, LAB M) and grown for two days at 30 °C 
under anaerobic conditions in an anaerobic chamber. C. tyrobutyricum spores were produced according to Klijn 
et al. (1995) with some modifications. Spores were produced by growing 100 ml cultures in RCM broth for 8 days 
at 30 °C in an anaerobic chamber. In total, 300 ml of C. butyricum cultures were centrifuged (15 min, 3000 g), and 
pellet containing spores were suspended in 30 ml of skimmed milk (LAB M) and stored in small portions at –20 °C 
(“suspension II”). After 8 days of storage at –20 °C, the number of spores were estimated as colony forming units 
(CFU) by plate counts on RCM agar. Plates were incubated for six days at 30 °C in an anaerobic chamber.



A G R I C U LT U R A L  A N D  F O O D  S C I E N C E
W. König et al. (2019) 28: 155–164

157

Half of the silos were filled with herbage batch inoculated with C. tyrobutyricum at the rate of 1 * 105 colony for-
ming units (cfu) g-1 fresh weight (FW). The inoculation solution was spread with a pipette while herbage was si-
multaneously thoroughly mixed. Immediately thereafter the herbage was treated in the same way with 4 l t-1 FM 
formic acid (FA; Sigma Aldrich, St. Louis, USA; 950 g kg-1) or with 900 g t-1 FM sodium nitrite (SN; aqueous solution, 
Sigma Aldrich, St. Louis, USA) (Table 1). The additives were applied as a water solution with a volume of 10 ml kg-1 
FM, including additive and water. For the control (CON) silages, the herbage was treated with 10 ml kg-1 FM tap 
water. Silos were stored at ambient room temperature (20–22 °C) and opened 106 days after ensiling.

Chemical analysis and aerobic stability
A pre-ensiling sample of the herbage was taken from the chopped herbage for immediate DM determination and 
for later analyses. Dry matter content was determined by drying the samples at 105 °C for 24 h in an oven (Mem-
mert, Memmert GmbH, Schwabach, Germany). Fresh samples were frozen (–20 °C) for analyses of buffering ca-
pacity (BC), total and soluble nitrogen, water-soluble carbohydrates (WSC), nitrate and clostridia. For analyses of 
ash, neutral detergent fibre (NDF) and in vitro digestibility samples were dried at 50 °C for 48 hours in a venti-
lated drying chamber (Memmert, Memmert Gmbh, Schwabach, Germany). After that, the samples were ground 
through a 1-mm sieve using a laboratory mill (KT-3100, Koneteollisuus Oy, Helsinki, Finland). Ash was determin-
ed by keeping the samples at 550 °C for 16–17 hours in an oven (Nabertherm B150, Nabertherm GmbH, Bremen, 
Germany). All other chemical methods and calculation of digestible organic matter in DM (DOMD) were reported 
in detail by König et al. (2017). 

After opening the silos, every silage was mixed, and samples were taken for immediate DM, pH (SevenCompactTM 
S220, Mettler-Toledo Ltd, Leicester, Great Britain) and aerobic stability analyses. Samples for fermentation quality 
and clostridia were stored at –20 °C for later analyses. The DM content of silages was determined similar to herbage 
samples and corrected for the loss of volatile compounds (lactic acid, VFA (volatile fatty acids), NH

3
-N and ethanol) 

according to Huida et al. (1986). The volatile compound concentrations were analysed as reported by Puhakka et 
al. (2016). Silage WSC content was investigated with the same method as herbage samples.

Aerobic stability was measured over a period of 12 days and expressed as time elapsed until the temperature 
rose 2 °C over the mean ambient temperature (22 °C). A more detailed description of the method is given by Kö-
nig et al. (2017).

Clostridium analyses using qPCR
For each DNA extraction, 30 grams of pre-ensiling herbage or silage were weighed, and samples were homo-
genized in 200 ml of ultrapure water. Homogenates were divided into three 50 ml tubes and centrifuged using  
10000 g for 15 min. 200 mg of pellet per sample was collected for DNA extraction. The DNA extraction was con-
ducted using the Macherey-Nagel NucleoSpin® Soil kit (Macherey-Nagel GmbH and Co. Kg, Düren, Germany) by 
using SL1 lysis buffer without SX enhancer as described by the manufacturer. 

Table 1. Additive treatments and clostridial spore inoculation of red clover-based silages

Additive/inoculation treatment Additive/inoculation Application rate of effective substance

Control (CON) No additive –

Formic acid (FA) CH
2
O

2 
(950 g kg-1) Formic acid 4 l t-1 FM

Sodium nitrite (SN) NaNO
2

Na-nitrite 900 g t-1 FM 

CON + clostridia Clostridium tyrobutyricum 1 x 105 cfu g-1 FM

FA + clostridia Clostridium tyrobutyricum 1 x 105 cfu g-1 FM

SN + clostridia Clostridium tyrobutyricum 1 x 105 cfu g-1 FM

cfu = colony forming unit; FM = fresh matter



A G R I C U LT U R A L  A N D  F O O D  S C I E N C E
W. König et al. (2019) 28: 155–164

158

The DNA sequences of PCR primers for Clostridium butyricum, C. tyrobutyricum, C. sporogenes and C. perfringens 
were as in our previous study (König et al. 2017). The qPCR reactions were performed in a Lightcycler 480 optical 
384-well plate (Roche Diagnostics, Mannheim, Germany) with a total volume of 10 μl. Using EpMotion 5075 pi-
petting system (Eppendorf, Hamburg, Germany), 2.5 μl of diluted DNA and 7.5 μl of the master mixture was ad-
ded. The master mixture was composed of 5 μl 2x SYBR Green master mix (Roche Diagnostics), 0.5 μl (5 pmol μl-1) 
each of forward and reverse primers, and 1.5 μl DNase/RNase-free water. 

Lightcycler 480 instrument (Roche Diagnostics) was used for qPCR. Each DNA sample was run in quadruplicate. 
The temperature profile of the qPCR was as follows: initial denaturation step for 5 min at 95 °C, followed by 45 
amplification cycles for 10 s at 95 °C, 20 s at 55 °C, and 30 s at 72 °C. A melting curve analysis was run at the end 
of the PCR program. 

The standard curves were generated using DNA extracted from the following reference strains: C. perfringens 
DSM strain 756, C. sporogenes DSM strain 795, C. butyricum DSM 10702 and C. tyrobutyricum DSM 2637 (Leib-
niz-Institute DSMZ German Collection of Microorganisms and Cell Cultures GmbH, Germany). Six standard diluti-
ons (from 0.004 to 12.5 ng μl-1) were always amplified on the same plate and using the same primers and reaction 
conditions as samples. Each standard dilution was run in triplicate in the qPCR. The raw data from Lightcycler 480 
was analyzed with LinRegPCR (Ruijter et al. 2009). Average numbers of Clostridium gene copies were calculated 
per gram of silage.

Calculations and statistical analysis
The fermentation coefficient for pre-ensiling herbages was calculated as FC = DM (g kg-1)/10 + 8 × WSC (g kg-1 DM)/
BC (g kg-1 DM) (Schmidt et al. 1971). The minimum DM content of ensiled herbage (DM

min
) needed to ensure high 

fermentation quality of silage was calculated using the equation DM
min

 (g kg-1) = 450 – 80 × WSC (g kg-1 DM)/BC 
(g kg-1 DM) (Weissbach 1999). A corrected N content was calculated by deducting all added SN nitrogen from the 
analyzed amount of total nitrogen and ammonia nitrogen. 

The results for fermentation quality parameters and clostridial copy numbers were statistically analyzed separa-
tely for the two trials. Before analyses logarithmic transformations were done for clostridial copy numbers. Nor-
mally distributed variables were analyzed by ANOVA using the Mixed procedure of SAS (SAS 9.3, Institute Inc., 
Cary, NC) with a model yij = µ + αi + εij, where yij is the overall mean observation, αi the effect of treatment and 
εij the error term.  

The effects of additives and clostridia addition (no clostridia inoculation vs clostridia inoculation) and their inte-
raction were first tested using orthogonal contrasts. The inoculation with clostridia had only minor numerical and 
statistical effects on silage quality, obviously due to the very high epiphytic clostridial contamination of herbage. 
Therefore, the data were pooled over inoculation treatments and only the differences between the additive treat-
ment means were tested using Tukey’s test. 

Non-normal distributed data were tested with the Kruskal-Wallis non-parametric test (SPSS, version 21, IBM, Ar-
monk, USA) and when significant, the differences between the treatment means were analyzed by pairwise tes-
ting (Dunn-Bonferroni). Statistically significant differences (p<0.05) between the treatments are expressed using 
different letters (a, b). 

Results 
Herbage characteristics prior to ensiling

The ensiled herbage was composed mainly of red clover (Table 2). The DM content was 199 g kg-1 and 314 g kg-1 
for the LDM and HDM herbage, respectively. Since also the WSC content was slightly higher and BC lower in HDM 
than LDM herbage the calculated FC was higher for HDM (42) than LDM (28) herbage. However, on FM basis the 
WSC content was almost twice as high in HDM as in LDM herbage. The LDM herbage contained 13.3 log copies g-1 
FM and the HDM herbage contained 9.9 log copies g-1 FM of clostridia ssp. The nitrate content was the same for 
both LDM and HDM herbage (4 g kg-1 DM). 



A G R I C U LT U R A L  A N D  F O O D  S C I E N C E
W. König et al. (2019) 28: 155–164

159

Silage aerobic stability and fermentation quality 

The additive treatments are compared within experiments, not between LDM and HDM silages in experiments 
1 and 2, respectively. All the 48 investigated silages were aerobically stable for 12 days, and therefore no results 
are presented.

The effects of additives on fermentation quality of silages are presented in Tables 3 and 4. In Exp. 1, no differences 
were observed between additive treatments in silage pH while in Exp. 2 the pH of FA silage was higher compared 
with other silages. In both experiments, FA decreased ammonia-N proportion compared to CON and SN silages. 
After correcting ammonia-N for added nitrogen, the proportion in both FA and SN silage was lower when com-
pared with CON silage. In HDM silages less ammonia-N was observed in SN than in CON silage and less corrected 
ammonia-N in SN than in FA treated silage.

The use of FA resulted both in LDM and HDM silages in lower concentrations of lactic and acetic acids and higher 
amounts of WSC compared with the untreated control and SN treated silages. In Exp. 2, acetic acid content was 
lower in SN than CON silage.

In both experiments, SN silage ethanol concentration was lower than that of FA silage, and in Exp. 2 also lower 
than in CON silage. In contrast to the other treatments, FA did not prevent butyric acid fermentation in Exp. 1. No 
butyric acid was detected in Exp. 2. The sum of clostridia copy numbers in Exp. 1 was higher in FA silage than in 
SN silage and in Exp. 2 higher than in CON silage. In both experiments, the copy number of C. tyrobutyricum was 
higher in FA than CON silages.

Table 2. Botanical and chemical composition and ensilability characteristics of low dry matter (LDM) 
and high dry matter (HDM) red clover-grass herbage (g kg-1 dry matter, unless otherwise stated)

LDM HDM

Botanical analysis, g kg-1 fresh matter

Trifolium pratense 659

Phleum pratense / Festuca pratensis 311

Weeds 30

Chemical composition

Dry matter (DM), g kg-1 199 314

Calculated DM
min

, g kg-1 1) 366 345

Ash 88.3 83.3

Crude protein 188 177

Soluble N, g kg-1 N 367 318

Neutral detergent fibre 460 467

Water soluble carbohydrates (WSC) 82.6 95.7

WSC, g kg-1 fresh matter 16.4 30.1

Nitrates 4.0 4.0

In vitro digestible organic matter 679 673

Buffering capacity (BC) as lactic acid g kg-1 DM 78.6 72.6

BC as mEq kg-1 DM 872 805

Fermentation coefficient 2) 28.3 42.0

Clostridia, log copies g-1 fresh matter 13.3 9.9
1) Minimum DM content of ensiled herbage needed to ensure high fermentation quality of silage, DMmin (g 
kg-1) = 450 – 80 × WSC (g kg-1 DM)/BC (g kg-1 DM) (Weissbach 1999); 2) Fermentation coefficient FC = DM (g 
kg-1)/10 + 8 × WSC (g kg-1 DM)/BC (g kg-1 DM) (Schmidt et al. 1971)



A G R I C U LT U R A L  A N D  F O O D  S C I E N C E
W. König et al. (2019) 28: 155–164

160

1) Kruskal-Wallis non-parametric test followed by Dunn-Bonferroni pairwise test, otherwise Tukey’s test; Means followed by 
different superscript letters in rows are statistically different at p<0.05; SEM = Standard error of the means; Cor Ammonia-N = 
ammonia-N proportion is corrected by deducting all nitrogen applied through Na-nitrite additive

Table 3. The effect of additive treatment on wilted red clover-based silage fermentation quality (g kg-1 dry matter, if not 
otherwise stated) and number of clostridia as log copies g-1 fresh matter (n = 4) (experiment 1)

Additive treatments SEM

Control Formic acid Na-nitrite

Dry matter, g kg-1 213b 204a 212b 1.5

pH1) 4.08 4.08 4.05 0.023

Ammonia-N1), g kg-1N 81.0b 46.0a 74.5b 2.43

Cor Ammonia-N1), g kg-1N 81.0b 46.0a 44.9a 2.41

Water soluble carbohydrates1) 4.3a 90.2b 4.3a 2.18

Lactic acid1) 133b 23a 136b 1.9

Acetic acid 36.1b 9.0a 36.4b 0.70

Butyric acid1) 0.00a 2.68b 0.00a 1.229

Ethanol1) 3.25ab 5.42b 1.38a 0.360

Clostridia, sum1) 10.4ab 11.0b 10.3a 0.20

C. butyricum1) 10.0 10.4 9.9 0.26

C. tyrobutyricum1) 8.77a 10.18b 8.95ab 0.560

C. perfringens1) 8.12 7.56 7.56 0.226

C. sporogenes1) 6.19 6.77 6.13 0.262

Table 4. The effect of additive treatment on wilted red clover-based silage fermentation quality (g kg-1 dry matter, 
if not otherwise stated) and number of clostridia as log copies g-1 fresh matter (n = 4) (experiment 2) 

Additive treatments SEM

Control Formic acid Na-nitrite

Dry matter, g kg-1 322 322 325 4.1

pH 4.12a 4.19b 4.10a 0.008

Ammonia-N, g kg-1N 71.7c 49.0a 65.7b 0.90

Cor Ammonia-N, g kg-1N 71.7c 49.0b 46.0a 0.74

Water soluble carbohydrates1) 14.1a 79.3b 18.7a 1.85

Lactic acid1) 118a 37b 110a 1.9

Acetic acid 26.5c 9.0a 24.1b 0.53

Butyric acid 0.00 0.00 0.00 0.000

Ethanol 3.67b 3.46b 1.00a 0.202

Clostridia, sum1) 10.4a 11.3b 11.2ab 0.56

C. butyricum 9.86 9.87 9.82 0.040

C. tyrobutyricum1) 10.2a 10.6b 10.3ab 0.08

C. perfringens 6.98 7.17 7.24 0.148

C. sporogenes1) 6.06 7.79 7.09 1.110
1) Kruskal-Wallis non-parametric test followed by Dunn-Bonferroni pairwise test, otherwise Tukey’s test; Means followed by 
different superscript letters in rows are statistically different at p<0.05; SEM = Standard error of the means; Cor Ammonia-N 
= ammonia-N proportion is corrected by deducting all nitrogen applied through Na-nitrite additive



A G R I C U LT U R A L  A N D  F O O D  S C I E N C E
W. König et al. (2019) 28: 155–164

161

Discussion
Herbage

The sward used in this experiment comprised mostly red clover, which, through its ensilability characteristics af-
fects silage fermentation quality as shown by Dewhurst et al. (2003). Both red clover-grass mixtures exposed re-
latively low WSC contents, high buffer capacities and fermentability coefficients (FC) below 45, which according 
to Weissbach (1968) predicts susceptibility for butyric acid fermentation.

The WSC concentration of the crop is considered a key factor when ensiling low DM herbage. The herbage should 
contain enough WSC to be fermented by the lactic acid bacteria to obtain a low pH and inhibitory concentrations 
of lactic acid and acetic acid. The fermentation coefficient (FC = 28.3) and the calculated minimum DM (DM

min
 = 

366 g kg -1 DM) content, as well as the WSC content in LDM herbage, were below their limits according to Weiss-
bach et al. (1974) and therefore, butyric acid fermentation was expected. The HDM herbage had an FC of 42 and 
30 g kg-1 WSC in the fresh matter, which is regarded as moderately difficult to ensile (EFSA 2006). According to 
Weissbach et al. (1974), the quotient of WSC/BC should be more than 2.5 to obtain butyric acid-free silages. In 
our experiments, the WSC/BC ratio were 1.05 (LDM) and 1.32 (HDM). 

Wilting improved the FC of the herbage in the present experiment from 28 (LDM) to 42 (HDM) and simultaneously 
butyric acid fermentation was inhibited in HDM silages. Wilting is directly linked to increasing osmolality of the 
herbage, which is the actual reason for the inhibition of clostridia. According to Hoedtke (2007), e.g. WSC, amino 
acids, alcohols and mineral ions are increasing the osmolality of the plants, whereas starch and other macromole-
cules decrease the osmolality due to their high mole masses. This induces that the plants osmolality varies during 
the growing process if WSC is used to build starch and amino acids for proteins. Hoedtke (2007) questioned the 
correlation between wilting and osmolality and introduced the term osmol kg-1 DM, which describes the different 
osmolality values between different plant groups with the same DM content. Plant osmolality has a direct impact 
on microbe osmotolerance and silage quality. Increased osmolality impairs microbial growth. Therefore, the DM 
content of herbage as a prediction tool for quality silage is less effective than the osmol kg-1 DM.

The additional inoculation with C. tyrobutyricum (log 5 cfu g-1 herbage) had no influence on the silage quality due 
to the highly contaminated herbage with clostridia copy numbers (log 13 DNA copies g-1 herbage). Hence, we com-
bined the inoculated results with the uninoculated generating eight replicates per treatment. The reason for the 
herbage contamination with clostridia might be the problems with huge flocks of Canada geese (Branta canadensis) 
spoiling the research area with their droppings. Typical populations of clostridia on plants before ensiling are 100–
1000 endospores per g crop (Pahlow et al. 2003). According to König et al. (2017), the number of gene copies per 
bacterial genome may vary from 1 to 15, which equals approximately 200 bacteria cells and/or endospores per 
gram fresh weight. The high numbers of clostridia DNA copies in the herbage had little effect on butyric acid fer-
mentation in both silages. Since our qPCR test did not separate the living spores and bacteria from the dead ones, 
we could assume that most of clostridia spores were inactive or damaged. 

Silages
The fermentation quality of the FA treated silage compared with untreated silage was in both experiments as 
described in various publications earlier (Muck et al. 2017). Formic acid reduced protein degradation and fermen-
tation as evidenced by low ammonia-N values and low lactic acid and acetic acid contents. The high residual WSC 
value was also characteristic to formic acid treatments. However, in LDM formic acid treatment did not prevent 
butyric acid formation compared with the control and the SN treatment. In HDM silage, formic acid treatment 
exposed higher pH values compared with control and SN, which might be related to the application level. The 
applied amount of FA per t DM in HDM herbage was 12.7 l, which was 7.1 l less than in the LDM herbage. Despite 
of that, all HDM silages were free of butyric acid. 

The reasons why FA treatment did not improve silage quality in LDM might be found in the buffering capacity, low 
DM content and low WSC content of the herbage. The immediate pH-decrease of the herbage while applying FA, 
might have impaired enterobacteria to reduce nitrate to nitrite and clostridia by utilizing nitrate as an electron 
sink. As a consequence, the butyric acid fermentation pathway was employed. When nitrate is used as an elect-
ron acceptor, clostridia produces acetic acid instead of butyric acid (Spoelstra 1985). 



A G R I C U LT U R A L  A N D  F O O D  S C I E N C E
W. König et al. (2019) 28: 155–164

162

Control and FA silages had the same pH values, but their osmo-activity might be different. This could be one 
explanation for the susceptibility of LDM FA silage to butyric acid fermentation. Formic acid treated silage has less  
osmo-active substances because FA restricts typically the fermentation. The microbes in control and SN silages fer-
mented the WSC to lactic acid, which converted 1 mole glucose into 2 moles lactic acid in the homofermentative 
pathway. The heterofermentative pathway converts 1 mole glucose into 1 mole lactic acid and 1 mole acetic acid 
or 1 mole ethanol. The fermentation of glucose increases the amounts of osmo-active particles and thus osmola-
lity. Using FA as silage additive, the fermentation of the herbage has a minor effect on osmolality. 

The fermentation profile of SN silages was similar to the control silages with the exception that the addition of SN 
decreased proteolytic activity. According to Cornforth (1996), protein-bound nitrite is of antimicrobial significance. 
The binding of nitrite to sulfide in sulfide containing proteins and enzymes is the important reaction in weakly aci-
dic conditions as described by Byler et al. (1983). The sulfide area of the enzyme is usually the active part of the 
enzyme due to the nucleophilicity of sulfide. The binding of nitrite to the sulfide group inactivates the enzyme 
function. Carpenter et al. (1987) investigated clostridial ferredoxin and pyruvate-ferredoxin oxidoreductase acti-
vity of C. pasteurianum. They found that the inhibition of ferredoxin increased with increasing levels of sodium 
nitrite and concluded that the inactivation of ferredoxin and pyruvate-ferredoxin oxidoreductase by nitrite is at 
least partly the reason for the anti-botulinal effect of nitrite.

The decision to correct the ammonia-N values of SN silages is based on the fact that sodium nitrite releases nitrous 
acid in weak acidic environments. Nitrous acid degrades further into nitric oxide and nitrogen dioxide (Spoelstra 
1985). During fermentation of carbohydrates by bacteria, these nitrous gases serve as an electron acceptor, which 
has the consequence that the fermentation pathway changes, e.g. enterobacteria form acetic acid instead of  
ethanol (Spoelstra 1985). A small part of the nitrous gases escapes into the atmosphere (5–25%), but the rest is 
reduced to ammonia, which results in silages with elevated ammonia-N values. Since the elevated ammonia-N 
values are not linked to protein degradation, but to SN addition, we decided to correct the ammonia-N values by 
subtraction of the completely applied nitrite-N.

Conclusions

In both experiments, no butyric acid formation was observed in the untreated control silage. The absence of  
butyric acid was probably related to the nitrate content of the herbage which allowed clostridia to use it as an 
electron acceptor and to avoid the lower energy gaining pathway of butyric acid fermentation.

Sodium nitrite treatment was superior to FA treatment concerning butyric acid contents and clostridial copy num-
bers in the LDM silages. The restrictive effect of formic acid on silage lactic acid fermentation and the resulting mi-
nor influence on osmolality might explain butyric acid fermentation in FA treated silages. Clostridial copy numbers 
were generally very high in all silages due to the high epiphytic contamination of herbage. This may explain why 
only minor differences were detected between additive treatments. In conclusion, the sole sodium nitrite treat-
ment is a possible alternative to formic acid as silage additive when ensiling difficult to ensile legume bi-crops. 

References 
Byler, D.M., Gosser, D.K. & Susi, H. 1983. Spectroscopic estimation of the extent of S-nitrosothiol formation by nitrite action on 
sulfhydryl groups. Journal of Agricultural and Food Chemistry 31: 523–527. https://doi.org/10.1021/jf00117a015

Carpenter, C.E., Reddy, D.S. & Cornforth, D.P. 1987. Inactivation of clostridial ferredoxin and pyruvate-ferredoxin oxidoreductase 
by sodium nitrite. Applied and Environmental Microbiology 53: 549–52.

Cornforth, D.P. 1996. Role of nitric oxide in treatment of foods. In: Lancaster, J.R. (ed.). Nitric Oxide: Principles and Actions. Aca-
demic Press, San Diego. p. 259–287. https://doi.org/10.1016/B978-012435555-2/50009-7

Dewhurst, R.J., Fisher, W.J., Tweed, J.K.S. & Wilkins, R.J. 2003. Comparision of grass and legume silages for milk production. 1. 
Production responses with different levels of concentrate. Journal of Dairy Science 86: 2598–2611. https://doi.org/10.3168/jds.
S0022-0302(03)73855-7

Driehuis, F. 2013. Silage and the safety and quality of dairy foods: a review. Agricultural and Food Science 22: 16–34. https://doi.
org/10.23986/afsci.6699

Driehuis, F. & van Wikselaar, P.G. 2000. The occurence and prevention of ethanol fermentation in high dry matter grass silages. 
Journal of The Science of Food and Agriculture 80:711–718. https://doi.org/10.1002/(SICI)1097-0010(20000501)80:6<711::AID-
JSFA593>3.0.CO;2-6



A G R I C U LT U R A L  A N D  F O O D  S C I E N C E
W. König et al. (2019) 28: 155–164

163

EFSA 2006. Opinion of the Scientific Panel on Additives and Products or Substances used in Animal Feed for the establishment of 
guidelines on the assessment of safety and efficacy of silage additives, on a request from the Commission under Article 7(5) of 
Regulation (EC) No 1831/2003. The EFSA Journal 349: 1–10. https://doi.org/10.2903/j.efsa.2006.349

Garvie, E.I. 1980. Bacterial Lactate Dehydrogenases. Microbiological Reviews 44: 106–139

Hellberg, A. 1967. A combination of nitrite and hexamine as an additive in the ensiling of herbage. Journal of the British Grass-
land Society 22: 289–292. https://doi.org/10.1111/j.1365-2494.1967.tb00542.x

Hoedtke, S. 2007. Die Quantifizierung der Osmolalität in Futterpflanzen und ihre Veränderung in verschiedenen Stadien der 
Silierung. Dissertation. Institut für Nutztierwissenschaften und Technologie der Agrar- und Umweltwissenschaftlichen Fakultät 
der Universität Rostock. 161 p. (in German).

Huida, L., Väätäinen, H. & Lampila, M. 1986. Comparision of dry matter content in grass silages as determined by oven drying and 
gas chromatographic water analysis. Annales Agriculturae Fennia 25: 215–230.

Kaiser, E. & Weiss, K. 1997. Zum Gärungsverlauf bei der Silierung von nitratarmem Grünfutter 2. Mitteilung: Gärungsverlauf bei 
Zusatz von Nitrat, Nitrit, Milchsäurebakterien und Ameisensäure. [On the fermentation process during ensiling of green forage 
low in nitrate. 2. Fermentation course with the addition of nitrate, nitrite, lactic acid bacteria and formic acid]. Archiv für Tier-
enährung 50: 187–200. https://doi.org/10.1080/17450399709386130

Klijn, N., Nieuwenhof, F.F.J., Hoolwerf, J.D., van der Waals, C.D.B. & Weerkamp, A.H. 1995. Identification of Clostridium tyrobu-
tyricum as the causative agent of late blowing in cheese by species-specific PCR amplification. Applied and Environmental Mi-
crobiology 61: 2919–2924.

Knicky, M. & Spörndly, R. 2009. Sodium benzoate, potassium sorbate and sodium nitrite as silage additives. Journal of the Science 
of Food and Agriculture 89: 2659–2667. https://doi.org/10.1002/jsfa.3771

Koeppen, B. & Stanton, B. 2012. Renal Physiology. 5th Edition. Mosby Physiology Monograph Series 2012. 256 p.

König, W., König, E., Weiss, K., Tuomivirta, T.T., Fritze, H., Elo, K., Vanhatalo, A. & Jaakkola, S. 2019. Impact of hexamine addition 
to a nitrite-based additive on fermentation quality, Clostridia and Saccharomyces cerevisiae in a white lupin-wheat silage. Jour-
nal of the Science of Food and Agriculture 99: 1492–1500. https://doi.org/10.1002/jsfa.9322

König, W., Lamminen, M., Weiss, K., Tuomivirta, T.T., Sanz Muñoz, S., Fritze, H., Elo, K., Puhakka, L., Vanhatalo, A. & Jaakkola, S. 
2017. The effect of additives on the quality of white lupin-wheat silages passed by fermentation pattern and qPCR quantification 
of clostridia. Grass and Forage Science 72: 757–77. https://doi.org/10.1111/gfs.12276

Lingvall, P. & Lättemäe, P. 1999. Influence of hexamine and sodium nitrite in combination with sodium benzoate and sodium pro-
pionate of fermentation and hygienic quality of wilted and long cut grass silage. Journal of the Science of Food and Agriculture 
79:257–264. https://doi.org/10.1002/(SICI)1097-0010(199902)79:2<257::AID-JSFA186>3.0.CO;2-J

Lück, E. & Jager, M. 1995. Chemische Lebensmittelkonservierung (Chemical food preservation), 3rd edn. Springer-Verlag Berlin, 
Heidelberg, GmbH. 273 p. https://doi.org/10.1007/978-3-642-57868-7

McDonald, P., Henderson, A.R. & Heron, S.J.E. 1991. The biochemistry of silage 2nd edition. Chalcombe Publications, Marlow, 
UK. 340 p.

Muck, R.E. 2010. Silage microbiology and its control through additives. Revista Brasileira de Zootecnia (supl. especial) 39: 183–
191. https://doi.org/10.1590/S1516-35982010001300021

Muck, R.E., Nadeau, E.M.G., McAllister, T.A., Contreras-Govea, F.E., Santos, M.C. & Kung Jr., L. 2017. Silage review: Recent ad-
vances and future uses of silage additives. Journal of Dairy Science 101: 3980–4000. https://doi.org/10.3168/jds.2017-13839. 
https://doi.org/10.3168/jds.2017-13839

Pahlow, G., Muck, R., Driehus, F., Oude Elferink, S.J.W.H. & Spoelstra, S.F. 2003. Microbiology of Ensiling. In: Buxton, D.R., Muck, 
R.E. & Harrison, J.H. (eds.). Silage Science and Technology. American Society of Agronomy, Inc. p. 31–93.

Puhakka, L., Jaakkola, S., Simpura, I., Kokkonen, T. & Vanhatalo, A. 2016. Effects of replacing rapeseed meal with fava bean at 2 
concentrate crude protein levels on feed intake, nutrient digestion, and milk production in cows fed grass silage-based diets. Jour-
nal of Dairy Science 99: 7993–8006. https://doi.org/10.3168/jds.2016-10925. https://doi.org/10.3168/jds.2016-10925

Quastel, J.H. & Woolridge, W.R. 1927. The effects of chemical and physical changes in environment on resting bacteria. Biochem-
istry Journal 21: 148–168. https://doi.org/10.1042/bj0210148

Queiroz, O.C.M., Ogunade, I.M., Weinberg, Z. & Adesogan, A.T. 2018. Silage review: Foodborne pathogens in silage and their 
mitigation by silage additives. Journal of Dairy Science 101: 4132–4142. https://doi.org/10.3168/jds.2017-13901. https://doi.
org/10.3168/jds.2017-13901

Ruijter, J.M., Ramakers, C., Hoogaars, W.M., Karlen, Y., Bakker, O., van den Hoff, M.J. & Moorman, A.F. 2009. Amplification effi-
ciency: Linking baseline and bias in the analysis of quantitative PCR data. Nucleic Acids Research 37: e45. https://doi.org/10.1093/
nar/gkp045

Schmidt, L., Weissbach, F., Wernecke, K.-D. & Hein, E. 1971. Erarbeitung von Parametern für die Vorhersage und Steuerung des 
Gärverlaufes bei der Grünfuttersilierung. (Development of parameters for the prediction and control of the fermentation process 
in ensiling green forage). Forschungsbericht. Oskar-Kellner-Institut fürTierernährung. Rostock. Deutschland.

Spoelstra, S.F. 1985. Nitrate in silage. Grass and Forage Science 40: 1–11. https://doi.org/10.1111/j.1365-2494.1985.tb01714.x

Weissbach, F. 1968. Beziehungen zwischen Ausgangsmaterial und Gärungsverlauf bei der Grünfuttersilierung [Relations between 
the herbage and the course of fermentation in ensiling green fodder]. Habilitation: University of Rostock, Germany.

Weissbach, F. 1999. Consequences of grassland de-intensification for ensilability and feeding value of herbage. Landbauforschung 
Völkenrode (FAL). Contributions of Grassland and Forage research to the Development of Systems of Sustainable Land Use. p. 41–53.



A G R I C U LT U R A L  A N D  F O O D  S C I E N C E
W. König et al. (2019) 28: 155–164

164

Weissbach, F., Schmidt, L. & Hein, E. 1974. Method of anticipation of the run of fermentation in silage making based on the chemi-
cal composition of the green fodder. In: Proceedings of the 12th International Grassland Congress. Moscow 1974. Russian Acad-
emy of Agricultural Sciences, Lugovaya. https://www.openagrar.de/receive/openagrar_mods_00027701

Woods, L.F.J. & Wood, J.M. 1982. A note on the effect of nitrite inhibition on the metabolism of Clostridium botulinum. Journal 
of Applied Bacteriology 52: 109–110. https://doi.org/10.1111/j.1365-2672.1982.tb04380.x

Woods, L.F.J., Wood, J.M. & Gibbs, P.A. 1981. The involvement of nitric oxide in the inhibition of the phosphoroclastic system of 
Clostridium sporogenes by sodium nitrite. Journal of General Microbiology 125: 399–406. https://doi.org/10.1099/00221287-
125-2-399

Xiao, M., Zhu, X., Xu, H., Tang, J., Liu, R., Bi, C., Fan, F. & Zhang, X. 2017. A novel point mutation in RpoB improves osmotolerance 
and succinic acid production in Escherichia coli. BMC Biotechnology 17:10. https://doi.org/10.1186/s12896-017-0337-6

 


	Effects of sodium nitrite treatment on the fermentationquality of red clover-grass silage harvested at two dry matterconcentrations and inoculated with clostridia
	Introduction
	Material and methods
	Treatments and silage preparation
	Chemical analysis and aerobic stability
	Clostridium analyses using qPCR
	Calculations and statistical analysis

	Results
	Herbage characteristics prior to ensiling
	Silage aerobic stability and fermentation quality

	Discussion
	Herbage
	Silages

	Conclusions
	References