METHOD TO EVALUATE THE QUANTITY OF METHANE PRODUCED BY A DAIRY RUMINANT AND METHOD TO REDUCE AND CONTROL THIS QUANTITY

Abstract

The present invention relates in particular to a method to evaluate the quantity of methane produced by a dairy ruminant. The method comprises determination of the ratio between the quantity of fatty acids with 16 carbon atoms or less and the sum of the total fatty acids of the milk, said quantity of methane being defined by the following equation: Quantity CH4=(FA<C16/Total FAs)*a*(milk production)b in which: quantity CH4 (in g/litre of milk)=quantity of methane produced; FA<C16=quantity of fatty acids with 16 carbon atoms or less; Total FAs =total quantity of fatty acids; expression of the ratio (FA<C16)/(Total FAs) as a % of total FAs; milk production=quantity of milk produced in kg of milk/animal and per year; a and b are numerical parameters in which a lies between 10 and 13, and b lies between −0.40 and −0.45.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This present application is a continuation of U.S. patent application Ser. No. 12/452,243, filed Dec. 18, 2009, which is a national phase entry under 35 U.S.C. §371 of International Application No. PCT/EP2009/057919, filed Jun. 24, 2009, which claims benefit of French Application No. 08 54230 filed Jun. 25, 2008. The disclosures of all of said applications are incorporated by reference herein.

BACKGROUND OF THE INVENTION

The present invention lies in the area of animal feed, and more precisely in the area of feed for milk-producing animals.

It more particularly concerns a method to evaluate the quantity of methane produced by a dairy ruminant, and a method to control the quantity of methane produced by a dairy ruminant.

The digestion of organic matter by ruminants comprises a microbial fermentation phase in the rumen. During this phase, plant polysaccharides (such as cellulose, hemicellulose, pectin, and starch) are broken down by the anaerobic bacteria living in the rumen.

This gives rise to the production of various volatile fatty acids (VFAs) (acetate, propionate, and butyrate [in increasing order of importance], carbon dioxide [CO₂] and hydrogen [H₂]).

Since the rumen is an anaerobic medium, the production of energy (ATP) occurs by “hydrogen transfer”.

Hydrogen inhibits the activity of most bacteria via different mechanisms. The hydrogen produced must therefore be eliminated by the rumen to promote good microbial digestion.

Methanogenesis, leading to the formation of methane (CH₄), is the main route allowing this elimination. It can be symbolized by the following reaction:

[CO₂+4H₂]=CH₄+2H₂O

This conversion is ensured by methanogenic bacteria which live in association with protozoa (which form the rumen's microfauna).

Methane (CH₄), together with carbon dioxide (CO₂), nitrous oxide (N₂O), and the three halogen carbons (Chlorofluorocarbons CFCs, hydrofluorocarbons HFCs, and perfluorocarbons PFCs), is one of the main greenhouse gases (GGs).

Its contribution to the greenhouse effect is very considerable. One molecule of CH₄ is effectively equivalent to 21 molecules of CO₂, according to official equivalence tables.

These GGs are believed to have an effect on climate change and in particular on global warming. Since the World Earth Summit in Rio in 1992, the fight against these changes has become an international commitment which, in 1997, translated as quantitative commitments taken under the Kyoto protocol.

The European Council has set itself the target of reducing GGs by 20% between now and 2020. In 2003, livestock farming generated 47.7 MMTCDE (million metric tons of carbon dioxide equivalent) of which 28.3 MMTCDE in the form of methane derived from the digestive fermentation of ruminants (Leseur, 2006; Martin et al., 2006).

These methane emissions represent 26% of emissions by the farming sector and 5% of French GG emissions (Leseur, 2006).

It therefore appears necessary to reduce the methane emissions of ruminants.

Different solutions have been put forward to reach this objective.

The first consists of limiting the consumption of products derived from ruminants and in particular dairy products, the effect of which would be to reduce the number of these dairy ruminants and hence logically the emissions of methane.

However, dairy products have been present in the food of human beings since time began. Man is known to be the only animal species to eat dairy products after weaning. Also, at nutritional level, these dairy products contain calcium, proteins, and lipids with very special nutritional properties which cannot be dissociated from a balanced diet at all stages of life.

Additionally, the increase in the planet's population appears scarcely compatible with a reduction in numbers of livestock intended to feed this increasing population.

Another solution consists of changing the feed of dairy ruminants (cows, sheep, goats, etc.) by directing the mechanisms of rumination towards decreased methane production.

Different techniques have been suggested to reach this objective.

The first consists of increasing the quantity of milk produced per cow (intensified livestock farming).

The second provides for additives in the feed that are toxic for protozoa and/or methanogenic bacteria so that milk can be produced with a reduction in the emitted quantities of methane.

Finally, a third technique consists of adding sources of plant lipids high in unsaturated fatty acids to the feed of dairy ruminants, preferably from the Omega-3 family, or in the form of other unsaturated fatty acids although their effects on methanogenesis are less powerful (than those of Omega-3 fatty acids). These fatty acids are toxic for methanogenic bacteria, either directly or via the toxic effects on protozoa which live in association with these methanogenic bacteria.

However, these different techniques can only be of real interest if there is a practical method, that is easy to implement, to evaluate the quantity of methane produced by ruminants.

Yet, measurement of methane emissions at the present time is only possible at experimental stations, but in cumbersome costly manner.

The present invention sets out to overcome this shortcoming.

SUMMARY OF THE INVENTION

Therefore, according to a first aspect, the present invention concerns a method to evaluate the quantity of methane produced by a dairy ruminant, characterized by the fact that it comprises determination of the ratio between the quantity of fatty acids with 16 carbon atoms or less, called FA<C16, and the sum of the total fatty acids in the milk, said fatty acids being those present in the milk produced by said ruminant, said quantity of methane being defined by the following equation:

Quantity CH₄=(FA<C16/total FAs)*a*(milk production)^b

in which:

• quantity CH₄ (in g/litre of milk)=quantity of methane produced;
• FA<C16=quantity of fatty acids with 16 carbon atoms or less;
• Total FAs=total quantity of fatty acids;
• expression of the ratio (FA<C16)/(Total FAs) as a % of Total FAs;
• milk production=quantity of milk produced in kg milk/per animal/per year;
• a and b are numerical parameters, with a lying between 10 and 13 and b lying between −0.40 and −0.45.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a graph which shows the prediction of production of CH₄ based on the production of Volatile Fatty Acids (VFAs).

DETAILED DESCRIPTION

Therefore, according to a first aspect, the present invention concerns a method to evaluate the quantity of methane produced by a dairy ruminant, characterized by the fact that it comprises determination of the ratio between the quantity of fatty acids with 16 carbon atoms or less, called FA<C16, and the sum of the total fatty acids in the milk, said fatty acids being those present in the milk produced by said ruminant, said quantity of methane being defined by the following equation:

Quantity CH₄=(FA<C16/total FAs)*a*(milk production)^b

in which:

• quantity CH₄ (in g/litre of milk)=quantity of methane produced;
• FA<C16=quantity of fatty acids with 16 carbon atoms or less;
• Total FAs=total quantity of fatty acids;
• expression of the ratio (FA<C16)/(Total FAs) as a % of Total FAs;
• milk production=quantity of milk produced in kg milk/per animal/per year;
• a and b are numerical parameters, with a lying between 10 and 13 and b lying between −0.40 and −0.45.

This method is easy to implement since the present applicant has evidenced that the quantity of methane produced is directly related to the quantity of fatty acids in the milk. Also, the assay of fatty acids in milk is an operation that is currently given very wide application and does not require any sophisticated or costly means.

In one preferred embodiment, a and b are respectively 11.368 and −0.4274.

Another aspect of the invention relates to a method to reduce and control the quantity of methane produced by a dairy ruminant.

This method is noteworthy in that it consists of:

• • giving the ruminant a food ration which meets at least one of the following criteria:

a) it excludes all fat of animal origin;

b) it limits the exogenous intake of vegetable oil containing more than 30% Total FA in the form of saturated FAs, in the natural state, hydrogenated, or saponified, to no more than 15 grams/animal and per 100 kg live weight;

c) it contains at least one lipid source high in omega-3 alpha-linolenic acid (ALA), i.e. of which more than 30% of the Total FAs are in the form of omega-3 FAs;

and of controlling said quantity of methane by applying the method according to one of the preceding characteristics.

Preferably, this lipid source is in the form of grazed fodder or conserved forage (wilted grass, silage, wrapped round bale, dehydrated, etc.) or oil seeds (in the natural state, raw, or cooked) high in ALA and oil-cakes of these same oil seeds.

Advantageously, said source includes flax (linseed).

Other characteristics and advantages of the invention will become apparent from the following detailed description.

1—Production of Volatile Fatty Acids (VFAs) And Production of Methane (CH₄)

The link between the production of VFAs in the rumen and the production of methane has been known and researched for many years.

It has been shown for example that the production of acetate and butyrate releases hydrogen, and therefore promotes the production of methane, whereas the production of propionate allows the hydrogen to be used and hence limits methane production (Gworgwor et al., 2006).

This can be illustrated by the following equations:

1 Glucose (C6) gives 2 Pyruvates (C3) [+4H]

1 Pyruvate (C3)+H₂O=1 Acetate+CO₂ [+2H] and:

1 Pyruvate=1 propionate (C3) [−4H]

A predictive equation has therefore been developed to predict the production of CH₄ from the production of VFAs, using the graph given in appended FIG. 1 (Moss et al., 2000). Therefore, the greater the production of C2 and C4 by fermentations in the rumen, the greater the production of CH₄.

Conversely, the greater the production of C3 by fermentations in the rumen, the more the production of CH₄ is reduced.

The synthesis equation following therefrom is defined as follows: [CH₄]=0.45 [acetate]+0.40 [Butyrate]−0.275 [Propionate]

where [x]=quantity of x, as a % of Total VFAs.

2—Influence of the Intake of A Source (Digestible In the Rumen) of Omega-3 Alpha-Linolenic Acid (ALA) On the Production of VFAs And CH₄

Omega-3-alpha-linolenic acid or C18: 3 n−3 or “ALA” is one of the mass constituents of growing plants.

It is found in abundance for example in young grass and in algae in which it accounts for the vast majority (50 to 75%) of the fatty acids in these plants. ALA is a basic constituent of chlorophyll membranes.

ALA is also found in some oilseeds such as flax seed (45% to 70%), hemp (around 15%), rapeseed or soy (around 10%).

The ALA content in the ration of dairy ruminants modifies the microbial population present in the rumen. ALA, directly and indirectly, effectively inhibits methanogenic bacteria and significantly modifies the proportions of VFAs produced, in particular by lowering the quantities of acetate and butyrate produced.

According to numerous sources in the scientific literature, when an ALA source is added to the ration of a ruminant, the production of propionic acid (C3) increases, and the proportions of acetic acid (C2) and butyric acid (C4) are reduced.

It therefore appears that:

• • the ratio [(C2+C4) to C3] is a very good index for the production of methane in the rumen;
  • the intake of ALA in the diets of dairy ruminants has a linear effect on the ratio (C2+C4)/C3 which is regularly decreased when, all other things being equivalent, the quantity of ALA ingested by the ruminant is increased.

It is to be noted, however that ALA sources can have different effects depending on the site of ALA digestion.

For example, raw flax seeds only bring a scarce reduction in the ratio [(C2+C4)/C3)], whereas extruded flax seeds and flax seed oils bring a strong increase.

The ability to modify this ratio [(C2+C4)/C3)] is therefore related to the quantity of ALA in animal diet but also to the availability of ALA in the rumen.

3—Influence of the Ratio [(C2+C4)/C3)] On Milk Composition

VFAs (C2, C3, or C4) produced by the rumen are diffused through its walls, or move on further through the intestinal barrier to enter circulating fluids.

Propionic acid (C3) is used as “glucogenic” source and contributes towards milk production as lactose precursor.

On the contrary, acetic (C2) and butyric (C4) acids are used by the de novo synthesis mechanisms to produce the saturated fatty acids of milk with 2 to 16 carbon atoms.

This synthesis, which takes place in the mammary epithelial cells, uses acetyl coA, a compound derived from C2 and/or C4 for these syntheses of C14: 0 and C16: 0.

These 2 fatty acids are then “shortened” (peroxisomal beta-oxidation) to produce short and medium-chain fatty acids of milk. These fatty acids can then optionally be desaturated into mono-unsaturated fatty acids under mammary desaturase activity.

4—Theoretical Model

The quantity of CH₄ produced per litre of milk therefore takes into account:

a) the animal's yearly milk production.

The more a dairy cow (for example) produces milk, the more the production of methane per litre of milk is decreased. Therefore, some authors propose the following equation:

Quantity of methane produced (kg per cow per year)=55.7+0.0098*(milk production, in kg per year and per animal).

b) ration composition, and in particular the quantity of available ALA in the rumen.

c) the ratio (C2+C4)/C3 in the rumen of these animals.

This VFA ratio is to be read as having a strong biological causal link with milk composition, in the form of the ratio between:

i) the sum of milk FAs with 16 or less than 16 carbon atoms,

and

ii) the sum of all the milk FAs.

The quantity of CH₄ produced per dairy female can therefore be calculated in relation to milk production (kg milk, per year, per animal) and to the FA composition of the milk from this animal.

It therefore appears that the person skilled in the art may have at hand a precious tool to evaluate the production of methane by dairy animals, in relation to their production level (easy to measure) and to the composition of the milk (easy to measure).

This indirect, but accurate, measurement of methane production can be used as a guide for the rationing systems of dairy ruminant animals, so as to reduce their contribution towards the greenhouse effect and to allow rapid measurement of the effects of these changes.

5—Test And Interpretation of Results

Numerous tests are available in the general bibliography which describe the effects of an intake of a food ALA source (most often in the form of flax) on the production of methane by cows, goats, and other female dairy ruminants.

Other tests are available which describe the effects of these same ALA sources, in the form of flax, on the fatty acid (FA) composition of milk.

Matching and synthesis of these results have been carried out to validate the theoretical model. These results are given in Table 1 below.

The focus here was to measure the production of CH₄ per litre of milk as a function of:

• • milk production (kg/animal/year);
  • the ratio between milk FAs having 16 carbon atoms or less as a % of total FAs.

Evidently, we could have chosen other FAs or other sums or ratios of FAs to illustrate the effects of de novo synthesis of saturated FAs in the udder, using the C2 produced in the rumen with CH₄ emission.

However, the sum of saturated FAs with 16 carbon atoms or less is particularly representative of this de novo synthesis from C2. Additionally, reading of the C16 fatty acids or of the sums of FAs with 12, 14, 16 carbon atoms, even the ratio between C16 and the sum of saturated FAs would also be relevant criteria.

This compiling of results was notably made from tests which firstly gave the FA profiles of milk and secondly gave measurements of methane produced per litre of milk, in tests using extruded flax seeds as ALA source and on cows having different production levels.

TABLE 1
Production of methane per litre of milk in relation to milk production
per animal and to milk FA profile, over a given range of milk FA profile
	MP
FA	4 000	5 000	6 000	7 000	8 000	9 000	10 000	11 000	12 000	13 000	14 000
70	23.7	20.9	19.1	17.8	16.8	16.0	15.4	14.9	14.4	14.1	13.8
68	23.0	20.3	18.5	17.2	16.3	15.5	14.9	14.4	14.0	13.7	13.4
66	22.4	19.7	18.0	16.7	15.8	15.1	14.5	14.0	13.6	13.3	13.0
64	21.7	19.1	17.4	16.2	15.3	14.6	14.1	13.6	13.2	12.9	12.6
62	21.0	18.5	16.9	15.7	14.8	14.2	13.6	13.2	12.8	12.5	12.2
60	20.3	17.9	16.4	15.2	14.4	13.7	13.2	12.7	12.4	12.1	11.8
58	19.7	17.4	15.8	14.7	13.9	13.2	12.7	12.3	12.0	11.7	11.4
56	19.0	16.8	15.3	14.2	13.4	12.8	12.3	11.9	11.6	11.3	11.0
54	18.3	16.2	14.7	13.7	12.9	12.3	11.9	11.5	11.1	10.9	10.6
52	17.6	15.6	14.2	13.2	12.5	11.9	11.4	11.0	10.7	10.5	10.2
50	16.9	15.0	13.6	12.7	12.0	11.4	11.0	10.6	10.3	10.1	9.8
48	16.3	14.4	13.1	12.2	11.5	11.0	10.5	10.2	9.9	9.7	9.4
46	15.6	13.8	12.5	11.7	11.0	10.5	10.1	9.8	9.5	9.3	9.1
44	14.9	13.2	12.0	11.2	10.5	10.1	9.7	9.3	9.1	8.9	8.7
42	14.2	12.6	11.5	10.7	10.1	9.6	9.2	8.9	8.7	8.5	8.3
NB:
This range of milk FA profile was deliberately limited to the range in which FAs with 16 carbon atoms or less account for 70 to 42% of the milk FAs. Not because the ensuing biological model or equation is limited to this range, but because beyond the limits of this range the composition of the milks produced can be considered firstly to be nutritionally doubtful and secondly ncompatible with the above-defined means used to obtain these milks.

In this table: MP (horizontally)=milk production (kg/animal/year) and FA=[FA<C16/Total FAs], as a %.

We have therefore drawn up a predictive table for emitted CH₄ values on the basis of milk production data and the FA profiles of these milks so produced:

	TABLE 2
	MP
FA	4 000	5 000	6 000	7 000	8 000	9 000	10 000	11 000	12 000	13 000	14 000
70	23.0	20.9	19.3	18.1	17.1	16.2	15.5	14.9	14.4	13.9	13.5
68	22.3	20.3	18.8	17.6	16.6	15.8	15.1	14.5	14.0	13.5	13.1
66	21.7	19.7	18.2	17.1	16.1	15.3	14.6	14.1	13.5	13.1	12.7
64	21.0	19.1	17.7	16.5	15.6	14.9	14.2	13.6	13.1	12.7	12.3
62	20.3	18.5	17.1	16.0	15.1	14.4	13.8	13.2	12.7	12.3	11.9
60	19.7	17.9	16.6	15.5	14.6	13.9	13.3	12.8	12.3	11.9	11.5
58	19.0	17.3	16.0	15.0	14.2	13.5	12.9	12.4	11.9	11.5	11.1
56	18.4	16.7	15.5	14.5	13.7	13.0	12.4	11.9	11.5	11.1	10.8
54	17.7	16.1	14.9	14.0	13.2	12.5	12.0	11.5	11.1	10.7	10.4
52	17.1	15.5	14.4	13.4	12.7	12.1	11.5	11.1	10.7	10.3	10.0
50	16.4	14.9	13.8	12.9	12.2	11.6	11.1	10.7	10.3	9.9	9.6
48	15.8	14.3	13.2	12.4	11.7	11.1	10.6	10.2	9.9	9.5	9.2
46	15.1	13.7	12.7	11.9	11.2	10.7	10.2	9.8	9.4	9.1	8.8
44	14.4	13.1	12.1	11.4	10.7	10.2	9.8	9.4	9.0	8.7	8.5
42	13.8	12.5	11.6	10.9	10.3	9.7	9.3	8.9	8.6	8.3	8.1

6—Validation of This Model

We have the results of several tests which accurately measured:

• • the quantity of ALA (available in the rumen) in the rations of dairy cows;
  • the effects of this ALA on the ratio (C2+C4)/C3;
  • the effects of these rations on the milk FA profile;
  • and finally tests which compared the production of CH₄ per litre of milk with different ALA contents in the rations.

The table below compares the measured values with the values “predicted” from the above-mentioned tables.

	TABLE 3
	Tests
	1	2	3	4	5	6
Milk	6 000	6 000	7 000	7 000	7 000	6 000
production
FA >=C16	61	42	66	64	56	42
CH4 in g/l	16.8	11.8	17.2	16.2	13.8	10.9
milk
“Prediction”
in g/l
As per Table 1	16.4	11.5	17.2	16.2	14.2	11.5
As per Table 2	16.4	11.5	17.2	15.7	14.2	11.5

The present applicant has inferred from these tests that the quantity of methane can be defined by the following equation:

Quantity CH₄=(FA<C16/Total FAs)*a*(milk production)^b

in which:

• • quantity CH₄ (in g/litre of milk)=quantity of methane produced;
  • FA<C16=quantity of fatty acids with 16 carbon atoms or less;
  • Total FAs=total quantity of fatty acids;
  • milk production=quantity of milk produced in kg per animal per year
  • a and b=numerical parameters in which a lies between 10 and 13, and b lies between −0.40 and −0.45.

Preferably, parameters a and b are 11.368 and −0.4274 respectively.

Claims

1. A method to evaluate the quantity of methane produced by a dairy ruminant, comprising: in which:

determining the ratio between the quantity of fatty acids with 16 carbon atoms or less, called FA<C16 and the sum of the total fatty acids in the milk, said fatty acids being those found in the milk produced by said ruminant, said quantity of methane being defined by the following equation: Quantity CH4=(FA<C16/Total FAs)*a*(milk production)b

quantity CH4 (in g/litre of milk)=quantity of methane produced;

FA<C16=quantity of fatty acids with 16 carbon atoms or less;

Total FAs=total quantity of fatty acids;

expression of the ratio (FA<C16)/(Total FAs) as a % of total FAs;

milk production=quantity of milk produced in kg of milk/animal and per year;

a and b are numerical parameters, with a lying between 10 and 13, and b lying between −0.40 and −0.45.

2. The method of claim 1, wherein a and b are respectively 11.368 and −0.4274.

3.-6. (canceled)

7. A method to evaluate the quantity of methane produced by a dairy ruminant, comprising: in which:

(a) assaying fatty acids of milk produced by a dairy ruminant;

(b) determining the ratio between the quantity of fatty acids with 16 carbon atoms or less, called FA<C16, and the sum of the total fatty acids in the milk, said fatty acids being those found in the milk produced by said ruminant;

(c) calculating said quantity of methane which is defined by the following equation: Quantity CH4=(FA<C16/Total FAs)*a*(milk production)b

quantity CH4 (in g/litre of milk)=quantity of methane produced;

FA<C16=quantity of fatty acids with 16 carbon atoms or less;

Total FAs=total quantity of fatty acids;

expression of the ratio (FA<C16)/(Total FAs) as a % of total FAs;

milk production=quantity of milk produced in kg of milk/animal and per year;

a and b are numerical parameters, with a lying between 10 and 13, and b lying between −0.40 and −0.45.

8. The method of claim 7, wherein a and b are respectively 11.368 and −0.4274.

9. A method to evaluate the quantity of methane produced by a dairy ruminant for use in reducing or controlling the quantity of methane produced by the ruminant, comprising: in which:

(a) assaying fatty acids of milk produced by a dairy ruminant by: (i) determining the total content of fatty acids in the milk; and (ii) determining the content of fatty acids with 16 carbons or less in the milk;

(b) determining the ratio between the content of fatty acids with 16 carbon atoms or less and the total content of fatty acids in the milk;

(c) determining the milk production of said ruminant, wherein said milk production is the quantity of milk produced in kg of milk per animal per year; and

(d) calculating said quantity of methane which is defined by the following equation: Quantity CH4=(FA<C16/Total FAs)*a*(milk production)b

quantity CH4 (in g/litre of milk)=quantity of methane produced;

FA<C16=content of fatty acids with 16 carbon atoms or less;

Total FAs=total content of fatty acids;

expression of the ratio (FA<C16)/(Total FAs) as a % of total FAs;

milk production=quantity of milk produced in kg of milk/animal and per year;

a and b are numerical parameters, with a lying between 10 and 13, and b lying between −0.40 and −0.45.

10. The method of claim 9, wherein a and b are respectively 11.368 and −0.4274.