Exploring the relationship between mastitis risk management, milk yield and global warming potential in dairy farms
Contributo in Atti di convegno
Data di Pubblicazione:
2025
Abstract:
Mastitis represents a significant challenge for the dairy industry,
causing reduced milk yield, economic losses, and increased environmental
impact. This study presents a predictive model to assess
the risk of mastitis according to farm structures and management,
and its impact on milk production and Global Warming Potential
(GWP). The model incorporates factors such as bedding materials,
hygiene practices, milking systems, and herd health monitoring.
It has been tailored to an Italian production environment, considering
Holstein cows reared in free stall housing. The impact of
mastitis on the GWP of milk production has been assessed using
the Life Cycle Assessment method with a ‘cradle to farm gate’
approach. A simulation study has been performed considering
27,456 scenarios with a milking parlor (MP) and 1,152 scenarios
with the automatic milking system (AMS). In MP scenarios, the
average milk production was 29.99 ± 1.96 kg, reflecting a 13%
decrease compared to the baseline (optimal situation without any
mastitis). Factors such as overcrowding, health surveillance, cleanliness
of resting areas, and post-dipping practices were identified
as key influences on production. Overcrowding led to an average
16.26% reduction in milk yield, while continuous health surveillance
reduced milk loss by 10%. Bedding material also played a
relevant role, with sand and straw related to smaller reductions in
production. GWP in MP scenarios ranged from 1.37 to 1.78 kg
CO2eq / kg FPCM. The optimal performance in MP scenarios
occurred with effective health management, continuous surveillance,
sand bedding, and proper pre- and post-dipping routines,
achieving 34.16 kg FPCM and 1.07 kg CO2eq / kg FPCM in deep litter
systems. In AMS scenarios, the average FPCM production was
34.75 ± 4.26 kg, with an average GWP of 1.43 ± 0.26 kg CO2eq / kg
FPCM. Continuous health monitoring and cleanliness of resting
areas had a significant impact on milk yield, as well as the AMS
type influenced performance. The optimal performance in AMS
scenarios was observed with no overcrowding, sand bedding, cleanliness,
and health group separation, yielding 43.12 kg FPCM and
0.93 kg CO2eq / kg FPCM in deep litter systems. The model provides
a framework for optimising dairy farm practices, highlighting the
critical role of health monitoring, hygiene, and bedding selection
in achieving sustainable milk production.
causing reduced milk yield, economic losses, and increased environmental
impact. This study presents a predictive model to assess
the risk of mastitis according to farm structures and management,
and its impact on milk production and Global Warming Potential
(GWP). The model incorporates factors such as bedding materials,
hygiene practices, milking systems, and herd health monitoring.
It has been tailored to an Italian production environment, considering
Holstein cows reared in free stall housing. The impact of
mastitis on the GWP of milk production has been assessed using
the Life Cycle Assessment method with a ‘cradle to farm gate’
approach. A simulation study has been performed considering
27,456 scenarios with a milking parlor (MP) and 1,152 scenarios
with the automatic milking system (AMS). In MP scenarios, the
average milk production was 29.99 ± 1.96 kg, reflecting a 13%
decrease compared to the baseline (optimal situation without any
mastitis). Factors such as overcrowding, health surveillance, cleanliness
of resting areas, and post-dipping practices were identified
as key influences on production. Overcrowding led to an average
16.26% reduction in milk yield, while continuous health surveillance
reduced milk loss by 10%. Bedding material also played a
relevant role, with sand and straw related to smaller reductions in
production. GWP in MP scenarios ranged from 1.37 to 1.78 kg
CO2eq / kg FPCM. The optimal performance in MP scenarios
occurred with effective health management, continuous surveillance,
sand bedding, and proper pre- and post-dipping routines,
achieving 34.16 kg FPCM and 1.07 kg CO2eq / kg FPCM in deep litter
systems. In AMS scenarios, the average FPCM production was
34.75 ± 4.26 kg, with an average GWP of 1.43 ± 0.26 kg CO2eq / kg
FPCM. Continuous health monitoring and cleanliness of resting
areas had a significant impact on milk yield, as well as the AMS
type influenced performance. The optimal performance in AMS
scenarios was observed with no overcrowding, sand bedding, cleanliness,
and health group separation, yielding 43.12 kg FPCM and
0.93 kg CO2eq / kg FPCM in deep litter systems. The model provides
a framework for optimising dairy farm practices, highlighting the
critical role of health monitoring, hygiene, and bedding selection
in achieving sustainable milk production.
Tipologia CRIS:
4.1 Contributo in Atti di convegno
Elenco autori:
Ferronato, Giulia; Simonetto, Anna; Gilioli, Gianni; Zecconi, Alfonso
Link alla scheda completa:
Link al Full Text:
Titolo del libro:
ASPA 25th Congress Book of Abstract
Pubblicato in: