Keywords:

Climatic change

Methane

Bovines Dual Purpose

Grazing

Supplementation

Ruminant grazing feeding and methane production

Alimentación de rumiantes a pastoreo y producción de metano

Alimentação de ruminantes em pastagens e produção de metano

Juan Vergara-López

University of Zulia, Faculty of Agronomy

Bolivarian Republic of Venezuela

Abstract

Climate change limits the release of radiation from the earth’s

atmosphere, a product of the accumulation of greenhouse gases (GHG) such

as CO

, methane, ammonia, among others. Ruminants contribute methane to

the atmosphere when fed with low quality forage diets, which in the light of

dierent conservationist organizations, qualies them as major pollutants.

When Venezuela signed the Kyoto Protocol in 2004, it undertook to establish

a GHG measurement system, as well as scientic research on the subject;

however, there are still no research groups in the country dedicated to the

permanent measurement of GHG contributions from these production

systems. Grazing pastures and forages of medium to low quality, with high

contents of cell wall of low degradability, produce a positive balance towards

the generation of methane of enteric origin, which could be mitigated if these

feeding schemes are improved, tending to improve the digestibility of basic

diets. Methane production by these production systems in the state of Zulia

is calculated at 209 Gg, 7.1 % of the total inventoried at the national level;

however, the lack of research in this area, as well as of systematic inventories

of local herds, prevents obtaining accurate data in this regard.

Rev. Fac. Agron. (LUZ). 2023, 40(Supplement): e2340Spl05

ISSN 2477-9407

DOI: https://doi.org/10.47280/RevFacAgron(LUZ).v40.supl.05

Animal production

Associate editor: Dra. Rosa Razz

Agronomic

Engineer,

MSc. Animal

Production.

Professor.

Department

Animal

Science,

Faculty

Agronomy,

Universidad del Zulia, Maracaibo, Zulia, Venezuela.

Received: 02-10-2023

Accepted: 15-11-2023

Published: 11-12-2023

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Rev. Fac. Agron. (LUZ).

2023, 40 (Supplement): e2340Spl05. October-December. ISSN 2477-9407.

Resumen

El cambio climático limita la liberación de radiación de la

atmósfera terrestre, producto de acumulación de gases de efecto

invernadero (GEI) como el CO

, metano, amoniaco, entre otros.

Los rumiantes aportan metano a la atmósfera al ser alimentados

con dietas forrajeras de baja calidad, lo que a la luz de diferentes

organizaciones conservacionistas, les calica como grandes

contaminantes. Venezuela al suscribir el Protocolo de Kyoto en 2004

se compromete a establecer un sistema de medición de GEI, así

como investigación cientíca al respecto, sin embargo, actualmente

aún son inexistentes en el país los grupos de investigación dedicados

a la medición permanente de los aportes de GEI por parte de estos

sistemas de producción. La alimentación basada en pastos y forrajes

de mediana a baja calidad, con altos contenidos de pared celular de

baja degradabilidad, producen un balance positivo hacia la generación

de metano de origen entérico, lo que podría mitigarse si se mejoran

dichos esquemas alimenticios a n de mejorar la digestibilidad de

las dietas básicas. La producción de metano por estos sistemas de

producción en el estado Zulia, se calculan en 209 Gg, es decir, 7,1

% del total inventariado a nivel nacional, sin embargo, la carencia de

investigación en esta área, así como de inventarios sistemáticos de

rebaños locales, impide obtener datos certeros en este sentido.

Palabras clave: cambio climático, Metano, Bovinos Doble Propósito,

Pastoreo, Suplementación.

Resumo

A mudança climática limita a liberação de radiação da atmosfera

terrestre como resultado do acúmulo de gases de efeito estufa

(GEE), como CO

, metano, amônia, entre outros. Os ruminantes

contribuem com metano para a atmosfera ao serem alimentados

com dietas de forragem de baixa qualidade, o que, de acordo com

várias organizações de conservação, os qualica como grandes

poluentes. Quando a Venezuela assinou o Protocolo de Kyoto em

2004, comprometeu-se a estabelecer um sistema de medição de

GEE, bem como pesquisas cientícas a esse respeito. No entanto,

ainda não existem no país grupos de pesquisa dedicados à medição

permanente das contribuições de GEE desses sistemas de produção.

As pastagens e forragens de média a baixa qualidade, com alto teor de

parede celular e baixa degradabilidade, produzem um saldo positivo

na geração de metano de origem entérica, que poderia ser mitigado

se esses esquemas de alimentação fossem aprimorados por meio da

melhoria da digestibilidade das dietas básicas. A produção de metano

por esses sistemas de produção no estado de Zulia é estimada em

209 Gg, 7,1 % do total nacional. No entanto, a falta de pesquisas

nessa área, bem como a falta de inventários sistemáticos dos rebanhos

locais, nos impede de obter dados precisos a esse respeito.

Palavras-chave: mudanças climáticas, Metano, Gado de dupla

nalidade, Pastagem, Suplementação.

Introduction

Despite being one of the most important oil producers in the world,

Venezuela is a country that contributes a low level of Greenhouse Gas

(GHG) emissions, a similar situation in the case of methane of enteric

origin (MARNR, 2005). In 1994, Venezuela ratied the United Nations

Framework Convention on Climate Change (UNFCCC) and in 2004

acceded to the Kyoto Protocol through Ocial Gazette No. 38.081 of

December 7, 2004 (Venezuela, 2004, 2010). Venezuela’s adherence to

this convention imposes a series of commitments to be fullled, such

as the generation of inventories of GHG emissions by source and their

absorption by sinks, updated periodically; development of national

and/or regional programs to mitigate climate change and adapt to

the potential eects, strengthening scientic and technical research,

promoting the development of technologies, practices and processes

to control, reduce or prevent anthropogenic GHG emissions.

Reading the document of the First National Communication

on Climate Change in Venezuela (MARNR, 2005), the lack of

institutions and research groups actively registering GHG emissions

scientic data, especially in agricultural production systems, is clearly

documented. This leads the discussion to the non-existence of GHG

emission estimates in livestock production systems in Venezuela,

which places the country in a condition of non-compliance with the

commitments acquired with the adhesion to the convention.

On the other hand, ruminant feeding in these systems is based

on medium to low quality pasture and forage, which implies a high

contribution of methane to the atmosphere (Niggli et al., 2009; Vargas

et al., 2012). However, the supplementation options used by livestock

producers are usually commercial concentrate feeds or raw materials

with high contents of easily digestible carbohydrates, which favor the

digestion of the base diet and consequently, a decrease in emissions

(Hristov et al., 2013).

At present, the product of a political and economic crisis that has

driven the costs of goods and services to a state of hyperination,

as well as the foreign origin of raw materials for the formulation of

concentrated feed, an activity highly dependent on foreign currencies

controlled and limited by the state, are factors that have increased the

costs of these supplements. This situation has resulted in a decrease in

production levels in dual-purpose livestock, but also in an increase in

the generation of GHGs such as methane and, consequently, a decrease

in the eciency of dietary energy use (Waghorn and Hegarty, 2011;

Vargas et al., 2012).

Under a situation like the one described, it is necessary to

generate research oriented to the ecient use of pastures and forages

as basic feeds in the diet of ruminants, as well as the valuation of

supplementary raw materials whose detailed knowledge of chemical

composition, digestibility and biological quality in general, will allow

a rational use that complements the basic pasture and guarantees an

optimal rumen functioning, with minimum emission of GHGs such

as methane.

The objective of this review is to analyze the existing information

in the literature on ruminant feeding systems and, based on the

available regional herd data, to calculate the production of enteric

methane by these herds in order to determine if there really is a high

contribution of this gas to the pool of GHG produced in the country.

Methods

This review is referred to the calculation of methane production

by regional bovine herds, however, the inexistence of specialized

national literature on this aspect of digestive physiology in Venezuelan

institutions, lead to the use of literature originated in other latitudes,

where there is the capacity to carry out measurements of methane

production of enteric origin under dierent experimental conditions.

This bibliographic support allowed documenting the physiological

and metabolic processes that give rise to methane as a result of the

use of dierent dietary regimes; however, it is pointed out that such

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Vergara-López.

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Table 1. Representative livestock categories.

Main livestock

categories

Livestock subcategories

Mature milking cows

or bualoes

High-producing cows that have calved at least once

and are used primarily for milk production.

Low-producing cows that have calved at least once

and are used primarily for milk production.

Other mature cattle

or non-lactating

bualoes

Females

Cows used to produce calves for meat

Cows used for more than one productive purpose:

milk, meat, leather.

Males

Bulls used primarily for reproductive purposes

Steers used mainly for traction

Growing cattle or

bualoes

Preweaned calves

Replacement heifers

Growing cattle or bualoes/post-weaning calves

Connement cattle fed diets >90 % concentrates

Source: IPCC (2006, 2019).

The non-existence of national herd inventories available for

consultation prevents having ocial gures for their use in the

calculations pursued in this document; however, it was necessary

to use indirect sources, such as FAO’s FAOSTAT database (2023),

which has an inventory of the Venezuelan herd until the year 2021

of 16,221,020 cattle. On the other hand, the Venezuelan Minister of

People’s Power for Productive Agriculture and Lands, in October

of this year, referred on the social network Twitter that Venezuela

has 17,292,202 animals to date, of which 11,931,619 females and

5,360,583 males, while the state of Zulia has 18.60 % of the herd

and is the largest producer (Castro, 2023). The proportions referred

by Castro (2023), the only ocial source of this information, allow

calculating a herd of 3,216,350 animals for the state of Zulia. From

the ULA-CIAAL (2011) document, a proportion of cows of 35 %

can be extracted, which results in 1,125,723 cows and the rest of the

age categories in 2,090,627 animals, estimated inventories that were

used for the calculation of CH

of enteric origin incorporated into the

environment.

Discussion

Ruminant feeding

Ruminants have become one of the most important species from

the agri-food point of view, due to the production of milk and meat

that serve as a source of protein for the human diet, as well as other

benets, such as work and companionship. These animals feed on

plant species, predominantly grasses, which in turn serve as substrate

for the microorganisms that cohabit the rumen, predominantly

bacteria, fungi, protozoa and bacteriophages (Dearing et al., 2017;

Wang et al., 2017; Xia et al., 2020).

In the Venezuelan DPPS, crossbred Bos taurus × Bos indicus

animals are fed grazing as a basic diet (Urdaneta, 2009). Peña et

al. (1997) and Pariacote et al. (2012) report that in the Rosario and

Machiques de Perijá municipalities of Zulia state, this livestock

production system predominates, using Brahman, Holstein and Brown

Swiss breeds with dierent levels of crossbreeding and grazing on

grasses with high proportion of cell wall contents (Adesogan et al.,

2019).

information is generated under genetic, productive, climatic and

dietary conditions very dierent from Venezuelan conditions.

Literature was used preferably with a feeding management

based on grazing or by the inclusion of vegetable sources for animal

feeding, however, for the purpose of contrasting dierent dietary

schemes, articles that used some type of strategic supplementation

through concentrated feeds or raw materials were also considered. It is

important to point out that predominantly, research on this subject has

been carried out in countries with strengths in these measurements.

Thus, to document basic principles, classical literature (Church,

1988; Johnson and Johnson, 1995, Kurihara et al., 1999), necessary to

record the physiological basis of ruminant GIT, as well as the role of

the ruminal microbiota in the production of GHG (Hoover and Miller,

1991), was found. Similarly, opinions of environmental organizations

such as Greenpeace (2009, 2018) and journalists such as Lombardero

(2007) are documented, necessary to discuss the stigmatization and

defense of ruminants as GHG generators.

Regional Estimates of Enteric Methane Production

The Intergovernmental Panel on Climate Change (IPCC)

generates scientic information on the current state of climate change

and potential impacts on the environment and economy (IPCC, 2006,

2019; Smith et al., 2014). In the 1996 IPCC Guidelines and Good

Practice Guidance (IPCC, 1996), the simplest and most common

methodological approach to combine information on the extent

to which human activity takes place (called activity data or DA) is

performed with coecients that quantify emissions or removals per

unit of activity. These are called Emission Factors (EF). The basic

equation is therefore: Emissions = DA × EF.

IPCC methodologies use the concepts of good practices alluding

to the care of overestimates and uncertainties; “Tiers” referring to

levels of complexity, from the use of values reported in literature

to the use of models based on feed quality and productive states

of the herd; key categories to refer to the constituent age groups of

the regional herds; among other key concepts for the denition of

particular regional conditions. In a recently revised version, the IPCC

manual (2019) points out the use of Tier 2 or 3 methodologies, for

which it is necessary to have gross energy consumption (GEC) gures

and methane conversion factors for specic categories of livestock

or models based on the consumption of specic nutrients; however,

since there is no research of this type in Venezuela, this methodology

cannot be used.

On the other hand, in the methodology described in IPCC (2006),

it species that the main livestock categories and subcategories can

be classied according to the guidelines in Table 1, which are adapted

to the livestock categories used in dual purpose production systems

(DPPS) in the Maracaibo Lake basin.

For the purposes of this review, the Tier 1 methodology was used,

which consists of EF derived from the literature, which is multiplied

by the number of animals present in a country. These factors have also

been suggested by IPCC (2006) according to the type of animal and

geographical location, factors similar to those presented by Ungerfeld

et al. (2018), which correspond to 72 kg.head

-1

.year

-1

for dairy cows

and 56 kg.head

-1

.year

-1

for other types of animals (beef cattle, bulls,

calves, heifers). However, IPCC (2019) made changes for these FE,

for which it introduces the classication of high (3,400 kg milk.

head

-1

.year

-1

) and low production (1,250 kg milk.head

-1

.year

-1

) dairy

production systems, the latter classication in which Venezuelan

production systems fall. In this sense, IPCC (2019) species 78

kg.head

-1

.year

-1

for dairy cows and 58 kg.head

-1

.year

-1

for other types

of animals (beef cattle, bulls, calves, heifers).

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Rev. Fac. Agron. (LUZ).

2023, 40 (Supplement): e2340Spl05. October-December. ISSN 2477-9407.

These grasses are fermented by rumen microorganisms producing

volatile fatty acids (VFA) that feed the energy metabolism of these

animals, taking advantage of their capacity to degrade cellulose

(Church, 1988; Reyes Gutiérrez, 2012). Grazing of tropical grasses,

incorporating structural carbohydrates in dierent proportions,

produces more methane and promotes a higher acetic acid:propionic

acid ratio than fermentation of non-structural carbohydrates (Hyland

et al., 2016; Valencia-Salazar et al., 2022). In these diets, energy losses

to form methane are 8 to 12 % of the gross energy (GE) consumed

by the animal, but in the case of diets where commercial concentrates

(more than 90 % grain and high energy) are incorporated, methane

losses can be as low as 2 to 3 % of GE intake (Johnson and Johnson,

1995; Methol, 2005; Hyland et al., 2016).

Cattle production systems are the main producers of methane

among domestic ruminants, generating 7-9 times more methane

than sheep and goats. In cattle and other ruminants, approximately

80 % of methane is generated in the rumen, a product of cellulose

digestion by rumen microorganisms, while about 20 % comes

from the decomposition of fecal matter (Román and Hernández-

Medrano, 2016). At the rumen level, the conversion of CO

to CH

in microbial fermentative processes confers to the carbon product of

this conversion a Global Reheating Power (GRP) 21 times greater

than CO

(de Blas et al., 2008). As a result of these processes,

carbohydrates and proteins are cleaved to their simplest chemical

elements, such as monosaccharides and amino acids, which are

assimilated by microorganisms by specic metabolic pathways and

result in volatile fatty acids (VFA), CO

, CH

and heat (McDonald et

al., 1979; Vargas et al., 2012).

When analyzing the phenomenon physiologically, the production

of enteric methane in ruminants is carried out by pathways that

require important energetic inputs, which are provided by the diet.

There are several dietary factors that aect the digestion process

of raw materials in the ruminant GIT, among them the relationship

between the consumption of pasture, forage and concentrate feeds.

Animals with high contents of concentrates are subject to a decrease

in the pH of the rumen content due to a high digestibility of this

product and a decrease in the buering power of this medium due to

a dilution eect of the forage content. This decreases the populations

of cellulolytic ora to the benet of amylolytic ora, which decreases

ber digestion, leading to a decrease in acetic acid production and

an increase in propionic acid, which in turn leads to a decrease in

pH by release of protons (H

) increasing enteric methane production

(Oldham et al., 1977; Johnson and Johnson, 1995; de Blas et al.,

2008; Vargas et al., 2012).

Dietary factors and enteric methane emission in ruminants

The incorporation of highly digestible diets improves the use of

the energy contained in their carbohydrates, which translates into a

decrease in methane emissions. There are pasture species that are

more ecient in milk production, partly because of their low enteric

methane production due to a greater eciency in protein and energy

metabolism. Likewise, as the age of the plant increases, methane

production increases due to the eect of the increase in lignocellulosic

fractions (Carmona et al., 2005).

The non-utilization of energy due to methane gas production

is due to many factors: amount and type of feed, manipulation of

ruminal fermentation, addition of lipids, type of carbohydrate in the

diet and processing of forages (Carmona et al., 2005). These factors, if

controlled or manipulated, could become ecient alternatives for the

control of this type of emissions. Chandramoni et al. (2000) evaluated

dierent proportions of forage and concentrate feed incorporation

(F:C; 92:8, 50:50 and 30:70) in connement sheep, recording the

production of methane of enteric origin in relation to gross energy

and found that in the diet with a high proportion of forages (92:8),

methane production was higher (3.93 %) than in 50:50 and 30:70

(3.34 % and 2.98 %, respectively). The ndings of these researchers

led to the conclusion that less methane is produced in starch-rich diets

than in high-ber diets.

The inclusion of supplements high in easily digestible

carbohydrates promotes changes in the ruminal microora towards an

increase in amylolytic populations, which translates into a decrease

in the digestion of brous fractions, leading to a lower proportion of

acetate and a higher proportion of propionate (Oldham et al., 1977).

This metabolic scenario drives the rumen environment towards a

lower methane emission as described by Van Kessell and Russell

(1996).

In the Venezuelan DPPS, the use of commercial concentrate feeds,

alternative raw materials (produced or not within the production unit)

or agro-industrial by-products, traditionally constituted the elements

used as feed materials to make up for the deciencies inherent to the

medium to low quality of pastures and forages used as basic diet in

ruminants.

In a review by Ungerfeld et al. (2018), the processes by which,

carbohydrates during glycolysis and oxidative decarboxylation

of pyruvate to acetyl-CoA, reduce cofactors that are reoxidized to

continue ruminal fermentation are summarized; these cofactors

transfer electrons to protons forming H

, which is transferred from

the fermenting organisms to methanogenic Archaea, which use it to

reduce CO

to CH

(Carmona et al., 2005).

Methane, the main electron sink in the rumen, during propionate

formation also incorporates metabolic hydrogen from reduced

cofactors. Thus the production of acetate, and to a lesser extent

butyrate, from hexoses results in the release of reducing equivalents

that will be mostly available for methanogenesis, while propionate

production incorporates reducing equivalents competing with CH

formation (Bonilla-Sandí et al., 2020).

While it is true that there is a direct relationship between the level

of dry matter intake and CH

production (Hristov et al., 2013), it is

also true that the nutritional composition of the diet plays an important

role in CH

production. The presence of insoluble cell wall ber in the

diet favors a higher acetate:propionate ratio and, consequently, higher

production. In contrast, fermentation of soluble carbohydrates

results in lower CH

production (Rivas-Martínez et al., 2023).

Estimation of methane production in ruminants

Advances in the understanding of ruminal fermentation have

allowed the development of mathematical models for the prediction

of enteric methane emission in ruminants. Hristov et al. (2013) and

Ungerfeld et al. (2018) have generated prediction equations with

dierent levels of complexity, estimating such emissions by relating

dierent productive stages, chemical composition of the diet, animal

products such as milk fat, or with animal behavior such as feed intake

or with live weight.

Johnson and Johnson (1995) in a detailed review of dierent

aspects related to CH

emissions in ruminants, state that when daily

feed intake (DFA) increases, the percentage of dietary GE lost as CH

) decreases on average 1.6 % per level of intake, however, the

linear mathematical model to predict this decrease fails and therefore

limits its extrapolation from laboratory to eld. When highly available

carbohydrates are fed at limited intakes, high fractional CH

losses

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5-7 |

occur, while at high intakes of highly digestible diets, low fractional

losses occur.

Yan et al. (2000) after a meta-analysis similar to the previous one

developed CH

prediction models based on digestible energy intake

(DEC) including silage acid detergent ber (ADF) (or DMI ratios)

and feed intake level. However, in the review by Hristov et al. (2013)

it is concluded that the validity of Y

is questionable, since according

to Ellis et al. (2010), this parameter does not have the ability to

dierentiate between a change in CH

produced due to an increase in

DMI and a change in CH

due to increases in dietary fat content, to

which they propose to express energy losses in CH

based on GE (or

per unit of animal product), which will more adequately reect forage

quality and other mitigation practices, such as the inclusion of grains

or fats in diets.

For growing, grazing-fed lambs, Hegarty et al. (2010) proposed

the following relationships between feed intake, digestibility (55 to

85 %) and CH

production:

• The increase in DMI is associated with a linear increase

in average daily weight gain (ADG), with the rate of ADG

higher in feeds of higher digestibility.

• The increase in DMI is associated with an increase in CH

production. In diets with low to moderate digestibility, such

as those in Australian extensive grazing systems, CH

release

per unit of additional intake is greater than when there is a

high intake of highly digestible feeds.

• CH

production per unit of metabolizable energy (ME) intake

is lower in diets with high energy densities.

• Although an increase in the intake of any diet reduces the

intensity of emissions in the growth phase (g CH

.kg

-1

LWG),

the intensity of emissions at any DMI level is lower in highly

digestible feeds than in low digestible feeds.

• Small changes in energy intake result in small changes in CH

production, but large changes in the productive performance

of the animal.

In the meta-analysis of Hristov et al. (2013) a total of 377

observations were analyzed, which allowed to ensure with an R

0.86 that DMI (specically digestible OM) is the most important

promoter of CH

production in ruminants, so that the dietary eect

and forage quality on intake is of utmost importance. The authors

clarify that, when using such an equation, the prediction error could

be higher with increases in DMI, since changing DMI to a narrower

range (ie. 10 % increase from approximately 18 to 20 kg.day

-1

) would

result in higher variability, making further research necessary to

nurture these predictions.

Dry matter intake and DE are the most important determinants

of milk and meat production, but the meta-analysis by Hristov et

al. (2013) did not include increased production or decreased enteric

relative to production when increasing DMI. CH

increases with

increasing DMI, but if this phenomenon is viewed from a lens of

increased milk and meat production, CH

decrease would only be

achieved with increased feed eciency and genetically determined

productive potential in herds that would tend to be lower in high-tech

production systems.

Enteric methane contributions

Industrial processes and the burning of fossil fuels make a

signicant contribution of GHGs, which have been estimated

and discussed in the workshops of the IPCC, a body established

by the United Nations Environment Program (UNEP) and the

World Meteorological Organization (WMO) to generate scientic

information on the current state of climate change and possible

impacts on the environment and the economy (Smith et al., 2014).

According to the results of those workshops, agriculture contributes

about 14 % of GHGs, while, of these, methane occupies 18 %, and

animal agricultural production systems about 20 %, mostly due to

enteric fermentation (Smith et al., 2014). On the other hand, some

environmental conservationist organizations have pointed to cattle

as the main species responsible for this phenomenon. Greenpeace

(2009) in Brazil, points to the cattle-producing meat activity, not only

for the deforestation of 19,368 km

per year of the Brazilian Amazon

rainforest, but, consequently, for the increase of GHGs resulting from

this activity. The subsidiary of this same global organization in Spain,

ensures that, in this country, the livestock sector emitted in 2015 more

than 86 million tons of CO

2-eq

originated in the production of fodder

and grains for animal feed, followed by methane emissions produced

in the digestion of ruminants (Greenpeace, 2018).

In Venezuela, the extinct Ministry of Environment and Renewable

Natural Resources (MARNR), in inter-institutional workshops,

yielded gures of 2,950 Gg total CH

, while enteric fermentation

registers 757.2 Gg, i.e. 25.7 % of the total produced in the country.

For Zulia state, the national herd data referred to by Castro (2023)

and the EFs specied by IPCC (2006; 2019) and Ungerfeld et al.

(2018), allow calculating an estimated 209 Gg of CH

contributed by

this herd, which represents 7.1 % of the total CH

inventoried at the

national level and 27.6 % of the CH

of enteric origin reported in the

MARNR report (2005). Although these calculations place Venezuela

in very conservative conditions with respect to GHG emissions to the

atmosphere, it is also true that they should be taken with caution, since

the data were not produced under the conditions of the productive

systems, nor under Venezuelan agro-climatic conditions.

Conclusions

The feeding of grazing ruminants, based on the consumption of

high proportions of vegetable cell walls, generates a greater proportion

of methane of enteric origin in animal production systems.

The incorporation of supplements that improve the digestibility

of basic forage diets helps to reduce the generation of methane

of enteric origin in grazing ruminants, which also leads to a more

ecient productive performance, being able to achieve a shorter

stay of animals within the system, which translates into a lower

contribution of methane to the group of GHG that are incorporated

into the environment.

According to calculations made on the basis of data generated

by governmental institutions, the contribution of methane of enteric

origin was about 209 Gg, that is, 7.1 % of the total inventoried in

Venezuela, estimates that should be considered with caution, given

the foreign origin of the partial data used.

At present, Venezuela does not have scientic work teams with

the technological capabilities or research projects that contemplate

the permanent monitoring of GHG emissions produced in ruminant

production systems. However, there are laboratories in dierent

university or research institutions in the state, which have a

minimum installed capacity and the human talent to implement such

measurement systems.

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