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Esta obra se publica bajo licencia Creative Commons 4.0 Internacional. (Atribución-No Comercial-
Compartir Igual) a menos que se indique lo contrario, http://www.creativecommons.org.ar/licencias.html
ARTÍCULO DE INVESTIGACIÓN
Effects of copper, zinc, selenium and
manganese parenteral supplementation on
reproductive performance of Holstein cows
Efectos de la suplementación parenteral de cobre,zinc, selenio y manganeso sobre el desempeño reproductivode las vacas Holstein
Efeitos da suplementação parenteral de cobre, zinco,
selênio e manganês no desempenho reprodutivo de
vacas Holstein
Melendez P1, Palomares R2, Barraza-Rodriguez JE3
1 School of Veterinary Medicine, Texas Tech University, Amarillo, TX, USA
2 Group for Reproduction in Animals Vaccinology and Infectious Diseases (GRAVID). Department of
Population Health. College of Veterinary Medicine, University of Georgia, Athens, GA, USA.
3 Private Practice, INSER S.A., Gómez Palacio, Durango, México.
Correspondence: pedro.melendez@ttu.edu
Abstract The objective of this investigation was to study the supplementation
of injectable trace minerals (ITM), based on Cu, Zn, Mn, and Se
on reproductive performance of dairy cows from Torreon, Mexico,
a geographical region characterized by a semi-desertic climate. The
study consisted of 2 field trials. Trial 1 compared the application of
2 doses of ITM during the dry period (at dry-off and at prepartum)
(n= 75) with a control group (n=79). Trial 2 compared the application
of 1 dose of ITM at 35 d postpartum (n=258) with a control group
(n=258). In both trials, conception rate at first service (CRFS) and days
to conception were evaluated. In Trial 1, CRFS was not different between
groups, but calving to conception interval tended to be shorter
in 10 days in the treated than the control group (P=0.14). In trial 2,
CRFS was not different between groups either, but time to pregnancy
was significantly 14 days earlier than the control group (P ≤ 0.05). It is concluded that although CRFS was similar between groups, the application
of an ITM reduced the time to pregnancy in treated than the
control groups, which have a great impact on herd’s fertility and profit.
Keywords: Copper; Zinc; Selenium; Manganese; Fertility; Days
Open; Dairy Cattle
Resumen El objetivo de esta investigación fue estudiar la suplementación de
oligoelementos inyectables (ITM), con base en Cu, Zn, Mn y Se sobre
el desempeño reproductivo de vacas lecheras de Torreón, México, una
región geográfica caracterizada por un clima semidesértico. El estudio
consistió en 2 ensayos de campo. El ensayo 1 comparó la aplicación
de 2 dosis de ITM durante el período seco (al secarse y antes del parto)
(n = 75) con un grupo de control (n = 79). El ensayo 2 comparó la
aplicación de 1 dosis de ITM a los 35 días después del parto (n = 258)
con un grupo de control (n = 258). En ambos ensayos, se evaluaron
la tasa de concepción en el primer servicio (CRFS) y los días hasta la
concepción. En el Ensayo 1, el CRFS no fue diferente entre los grupos,
pero el intervalo entre el parto y la concepción tendió a ser más corto
en 10 días en el grupo tratado que en el grupo de control (P = 0,14).
En el ensayo 2, la CRFS tampoco fue diferente entre los grupos, pero el
tiempo a la preñez fue significativamente 14 días antes que en el grupo
control (P ≤ 0,05). Se concluye que aunque la CRFS fue similar entre
los grupos, la aplicación de un ITM redujo el tiempo a la gestación en
los grupos tratados que en los de control, lo que tiene un gran impacto
en la fertilidad y las ganancias del hato.
Palabras clave: Cobre; Zinc; Selenio; Manganeso; Fertilidad; Días
Abiertos; Vacas Lecheras
Resumo O objetivo desta pesquisa foi estudar a suplementação de oligoelementos
injetáveis (ITM), à base de Cu, Zn, Mn e Se no desempenho
reprodutivo de vacas leiteiras de Torreón, México, uma região geográfica
caracterizada por um semidesértico. clima. O estudo consistiu em
2 ensaios de campo. O ensaio 1 comparou a aplicação de 2 doses de
MIT durante o período de seca (na secagem e antes do parto) (n = 75)
com um grupo controle (n = 79). O ensaio 2 comparou a aplicação de
1 dose de ITM 35 dias após o parto (n = 258) com um grupo controle (n = 258). Em ambos os ensaios, a taxa de concepção do primeiro serviço
(CRFS) e os dias para a concepção foram avaliados. No ensaio 1, o
CRFS não foi diferente entre os grupos, mas o intervalo entre o parto
e a concepção tendeu a ser menor em 10 dias no grupo tratado do
que no grupo controle (P = 0,14). No ensaio 2, o CRFS também não foi
diferente entre os grupos, mas o tempo até a gravidez foi significativamente
14 dias antes do grupo controle (P ≤ 0,05). Conclui-se que
embora o CRFS tenha sido semelhante entre os grupos, a aplicação de
um MIT reduziu o tempo a gestação nos grupos tratados do que nos
grupos controle, o que tem grande impacto na fertilidade e no ganho
de rebanho.
Palavras-chave: Cobre; Zinco; Selênio; Manganês; Fertilidade; Dias
Abertos; Gado Leiteiro
Milk production, health status and fertility of dairy cows are strongly
related each other, significantly accounting for of the system’s profitability.
Moreover, these three variables are the expression of an adequate
cow-comfort, a consistent nutritional program, a high genetic
merit of the animals, adequate herd health protocols and an efficient
human resources team. [1]
One of the most critical times in the productive cycle of the dairy
cow is the transition period (21 d before parturition to 21 d postpartum).
Most diseases occur at that moment, primarily due to the lower
dry matter intake and the typical immunosuppression that cows experience.
[2] During the transition period, cows undergo a negative energy
and protein balance, which must be managed properly. In addition, the
characteristic immunosuppression taking place during this time should
be attenuated, and the severity of hypocalcemia diminished to its minimum
expression. If body condition score (BCS) at calving and its loss
during the first month of lactation can be targeted efficiently, the cow
will be healthier and will produce more milk. In fact, cows that lose BCS
during prepartum and cows that lose excessive BCS during the postpartum
period will have a higher incidence of periparturient diseases. [1, 2) Furthermore, cows with one or more disease events during the postpartum
period will be affected by poor fertility and lower milk yield. [3]
The use of additives in diets fed during the transition period may
ameliorate the nutritional burden and metabolic imbalances of transition
dairy cows, including certain microminerals that are essential
for life, since they are constituents of several enzymes, hormones and
important proteins. [1, 4]
The high metabolic demands associated with milk production induce
oxidative stress, which is an imbalance between the levels of oxidation-
derived free radicals (known as reactive oxygen species, ROS)
and antioxidant molecules. [5] Trace minerals such as selenium, copper,
zinc and manganese play a major role in the antioxidant systems, as
they are part of the structure and function of enzymes necessary to
reduce the high levels of ROS during oxidative stress in dairy cows. For
instance, Cu, Zn and Mn act as cofactors for the enzyme superoxide
dismutase, which catalyzes the chemical transformation of superoxide
anions into hydrogen peroxide. Then, the enzyme glutathione peroxidase
a metallo-protein containing selenium, metabolizes the reduction
of hydrogen peroxide into hydroxyl radicals and H2O. Copper interacts
at the mitochondrial level with enzymes such as cytochrome oxidase,
which is essential for energy production. In addition, zinc plays important
role in more than 2,500 enzymatic reactions. [4, 5] Oocyte zinc
reserves and release (known as zinc sparks 2 hours after fertilization)
is associated with the oocyte ability to undergo fertilization and further
embryo development. Oocytes store, compartmentalize, and then
release zinc to control maturation, fertilization, and the development
of a healthy embryo. Zinc is highly associated with physiologic process
that involve active cell replication such as mitosis during embryo
growth and development [6] In addition, the supplementation with
injectable trace minerals (ITM) has improved leukocyte function, antioxidant
response, [7, 8] and total pregnancy rate [9] in dairy cows.
Accordingly, the hypothesis of this investigation was that the cows
receiving ITM supplementation have greater fertility during lactation.
Consequently, the objectives of this research were (i) to compare the
effect of a subcutaneous ITM supplement containing Se, Cu, Zn and
Mn applied at dry-off and at prepartum versus a selenium/vitamin supplement
on reproductive performance of Holstein cows (Trial 1) and
(ii)to evaluate the effect of a single dose of ITM at 35 days postpartum
versus a non-treated control group on reproductive performance of
Holstein cows (Trial 2).
2.1 ETHICAL STATEMENT
This investigation consisted of 2 field trials conducted in several
farms from Torreon city, Coahuila, Mexico; therefore, the parenteral
application of microminerals was part of the common routine of these
dairies.
2.2 FARMS AND LOCATION
The research was conducted under commercial settings of dairy
farms from Torreon, Coahuila, Mexico. The investigation consisted of
two field trials considering the application of a commercial micromineral
mix composed of selenium (5 mg/mL), copper (15 mg/L), manganese
(10 mg/mL) and zinc (60 mg/mL), for intramuscular injections
(Multimin 90, Multimin USA, Inc., Fort Collins, CO). Trial 1 consisted of
the application of 2 doses of the ITM during the dry period, and Trial 2
evaluated a single dose of a subcutaneous ITM during the postpartum
period.
Farms that participated in this investigation belong to a dairy
Mexican basin with 185,000 milking cows, called “Comarca Lagunera”,
located around Torreón city, capital of the state of Coahuila, Mexico.
This dairy zone has an altitude of 1,100 meters above sea level, with
geographical coordinates of 25 ° 31 ‘ N, 103 ° 25´ W. The predominant
topography is flat, the climate is dry (desertic) with annual relative
humidity of 50%, an average annual rainfall of 240 mm and an average
annual temperature of 22 ° C (range: 14.7 ° C in January, 28.2 ° C in
June) [10].
This Mexican macrozone is characterized by having large dairy
systems with average herd size of 2,000 lactating cows. Major breed
is Holstein Friesian with an average mature equivalent 305 days milk
yield of 10,000 kg. Most dairies milk the cows twice a day and feed
total mixed rations based on corn silage, alfalfa hay, and concentrates
(corn grain, soybean meal, cotton seed, cotton meal, DDGS, canola
meal, mineral, vitamins and additives). Most herds are housed in drylot
systems with roof and fans at the feed-bunk area.
Reproductive management primarily consists of ovulation synchronization
protocols and timed artificial insemination combined with
heat detection protocols. Pregnancy diagnosis is carried out by ultrasonography
between 28 to 35 days post service. Non-pregnant cows
are resynchronized immediately, and pregnant cows are reconfirmed for gestation between 60 to 70 days post service. Pregnant cows are
reconfirmed for gestation between 50 and 75 days before expected
parturition (BEP). If the cow remains pregnant, she is dried-off and
handled in a dry cow group until 28 to 35 days BEP where the cow is
moved to a prepartum group and fed a total mixed ration with anionic
products to prevent hypocalcemia. Cows are consistently monitored
for signs of parturition. They deliver at the same prepartum lot and
calving assistance is carried out as needed. After birth, the calf is immediately
separated from the dam and the cow is milked and assessed
for reproductive tract lacerations, intrapelvic trauma, peripheral nerve
inflammations and clinical hypocalcemia (downer cow syndrome)
within the first 6 hours postpartum. Cows are treated according to veterinary
standard operating procedures. After that, cows are subjected
to a postpartum health monitoring program until 10 to 15 days post
calving. Cows are evaluated for retained fetal membranes, puerperal
metritis, mastitis, ketone bodies and left displacement of the abomasum.
Body condition score (BCS) is assessed at dry-off, at prepartum,
and at parturition, using a scale 1 to 5 in a ¼ units of increment [11].
Th herd health program was based on vaccinations and biosecurity
measures to prevent common diseases that affect dairy herds at the
Comarca Lagunera in Torreon, Mexico, including brucellosis, leptospirosis,
IBR, BVDV, and clostridial diseases. Additionally, it also included
a mastitis preventive program based on cleaning, disinfection and
adequate milking procedures.
2.3 STUDY DESIGN
2.3.1 TRIAL 1
The study 1 was conducted at the dairy “Mapulas”, consisting of
3,800 lactating cows, milked three times a day, average milk yield per
cow of 38.2 kg/day, fed a TMR, and housed in a dry lot system.
The trial consisted of comparing one group that enrolled randomly
75 cows (32 primiparous, 43 multiparous), receiving 2 doses of ITM during
the dry period. First dose of ITM (6 mL, subcutaneous, 1 mL per 100
kg of body weight) was injected at dry off and the second dose (6 mL, intramuscularly)
when cows were moved to the prepartum lot. The other
group enrolled 79 cows (33 primiparous, 46 multiparous) and treated
with a commercial product based on vitamin E and selenium, providing
sodium selenite 10.95 mg/ml and tocopherol 50 mg/m, injecting 10 mL
subcutaneously (Se-Ve®, LAPISA, S.A., La Piedad, Guadalajara, Mexico). Both groups were compared for BCS at calving, conception rate at first
service (CRFS), and calving to conception interval.
2.3.2 TRIAL 2
The second study was carried out at 3 dairy farms (La Gloria, El
Clavel, La Luna) from the “Comarca Lagunera”. The three dairies belonged
to a large dairy corporation, utilizing the same feeding and reproductive
management.“La Gloria” dairy consisted of 3,200 lactating cows, milked three times
a day, average milk yield per cow of 35.1 kg/day, fed z TMR, and
housed in a dry lot system. “El Clavel” dairy consisted of 3,300 lactating
cows, milked three times a day, average milk yield per cow of 37.8
kg/day, fed z TMR, and housed in a dry lot system, and “La Luna” dairy
consisted of 11,000 lactating cows, milked three times a day, average
milk yield per cow of 37.7 kg/day, fed a TMR, and also housed in a
dry lot system. After parturition, cows were subjected to a synchronization
of ovulation timed artificial insemination protocol (Presynch-
Ovsynch) [12, 13].
This trial compared two experimental groups. Treatment group
enrolled at random 258 Holstein cows (99 primiparous, 159 multiparous),
receiving 1 dose of ITM (7 mL intramuscularly) between 35 and
38 days in milk (DIM). Control group (without treatment) randomly
assigned 258 cows (98 primiparous, 160 multiparous). Both groups
were compared for CRFS, and time to pregnancy. Treated and control
cows were housed and handled homogeneously in the same lactating
group.
2.3.3 STATISTICAL ANALYSIS
Body condition score at calving (trial 1) was analyzed by using the
non-parametric method Kruskal-Wallis test. Conception rate at first
service (trial 1 and 2) was analyzed by a logistic regression model,
considering the group effect as main effect, and parity and farm effect
as covariates (trial 2). Calving to conception interval (trial 1) was compared
by a one-way ANOVA. Days to pregnancy (trial 2) was assessed
by survival analysis, constructing Kaplan -Meier Survival Curves.
Statistical analysis was conducted using the corresponding computer
procedure of SAS for Windows 9.4 [14].
3.1. TRIAL 1
In Table 1, descriptive statistics (median) and P-value (Kruskal-
Wallis test) for BCS at dry-off, at prepartum, and at calving for ITM
and Se-Ve groups are shown. There was not statistical differences between
groups for BCS at dry-off, meaning an adequate randomization
process for experimental animal assingment. Body condition score at
prepartum and at calving did not differed statistically between experimental
groups either. In Figure 1, CRFS (%) in cows treated with ITM
during the dry period and controls is shown. In Figure 2, calving to
conception interval (days) in cows treated with ITM during the dry
period and controls is shown.
3.2. TRIAL 2
In Figure 3, CRFS (%) in cows treated with ITM during the postpartum
period and controls is shown. In Figure 4, Time to Pregnancy
Survival Curves (Kaplan-Meier statistics) in cows treated with ITM during
the postpartum period and controls are illustrated.
3.3 FIGURES, TABLES AND SCHEMES
Table 1: Median (range) and Kruskal-Wallis test P-values results for Body
Condition Score (BCS) at dry-off, prepartum and calving in Holstein cows (Trial 1)
Figure 1: Conception Rate at First Service (%) in cows treated with ITM during
the dry period and controls (Trial 1). No statistical differences (P =0.95)
Figure 2: Calving to Conception Interval (days) in cows treated with ITM during
the dry period and Controls (Trial 1). Statistical tendency (P=0.14).
Figure 3: Conception Rate at First Service (%) in cows treated with ITM during
the postpartum period and controls (Trial 2). No statistical differences (P
=0.75)
Figure 4: Time to Pregnancy Survival Curves (Kaplan-Meier statistics) in cows
treated with ITM during the postpartum period and Controls (Trial 2). Fifty percent
of treated animals became pregnant at 152 days (CI 95% = 136-170 days)
(red line) and 50% of control animals became pregnant at 167,5 days (CI 95% =
151-194 days) (line blue) (P < 0.05).
This research comprises 2 field trials conducted under commercial
conditions in Mexican herds from one of the most important dairy regions
of the country (Torreon, Coahuila). The strength of these field
trials is that they were carried out under ‘real-farming’ conditions,
with natural development of the outcome of interest, in this case “fertility
responses”. However, one of the major concerns of these type of
studies is the randomized allocation of the animals. Proper randomization
and an adequate sample size help to prevent systematic bias,
avoiding the negative impact of confounding variables. In both trials,
the selection of animals was at random, and after the treatment application
both groups (control and experimental) were housed in the
same group, handled homogeneously, without more interventions and
reproductive variables were recorded consistently and blind to the
investigators.
TRIAL 1
In this trial, the effects of two injectable doses of micro minerals
during the dry period (at dry-off and at prepartum) on reproductive
performance was evaluated. In this case, an experimental commercial
product was compared with another supplement based on vit E/Se,
which was the standard routine for this dairy. Consequently, it was no
feasible to have a control group without supplementation. BCS at calving
was within expected values (median=3.5) and similar between
both groups. The application of ITM during the dry period did barely
modified BCS, with similar results for both groups. If dry cows are properly
fed, it is unlikely that a supplementation with injectable minerals
and/or vitamins can change subcutaneous fat deposition. On the
other hand, BCS is a subjective assessment of energy nutrition, because
adipose tissue accretion not only occur at the subcutaneous level,
but also inside of abdominal cavity and omental tissue, with genetic
differences in their distribution [15]. In other words, BCS may be similar
between two animals, but the amount of deposited abdominal fat may
considerably fluctuate. Unfortunately, visual assessment of abdominal
fat accumulation is not feasible, which would either require a blood
biomarker evaluation or an invasive surgical technique to approach
the abdominal cavity.
Regarding reproductive responses, both groups were supplemented
with minerals, and CRFS was similar between them, but calving to
conception interval was 8 days shorter (117 days) in the ITM group than the control group (125 days) (P=0.14). This slight improvement
might be explained due to the control group received only vitamin
and selenium unlike the treatment group receiving four microminerals,
also including selenium, which may boost immunity and fertility
better than a single dose of vitamin E and selenium. A study, that also
injected 2 doses of the same mineral supplement [7] during the dry period
(dry-off and prepartum), found that treated cows had significantly
less stillbirth and endometritis, but similar conception rate and calving
to conception interval than control cows. Unfortunately, based on
the nature of the data set of our trial, health events were not accurate
enough to be recorded and analyzed. Although in our study groups
were balanced for parity number and BCS at calving, occurrence of
diseases could be a major confounding. Perhaps treated group experienced
less diseases than the control group and indirectly tended to
become pregnant earlier.
TRIAL 2
The four microminerals of the supplement used in the present investigation
are involved in several cell processes that affect the normal
function of tissues, organs, and systems, improving immunity and fertility
of animals. As previously reviewed by Goff [4], briefly, selenium
form part of glutathione molecule, a powerful antioxidant system in
many cells, which has been demonstrated to reduce the incidence
of mastitis and retained fetal membranes in dairy cows. Copper is a
structural component of the superoxide dismutase, another antioxidant;
cytochrome oxidase, which is part of electron transport system
in mitochondria; lysil oxidase, involved in collagen and elastin synthesis
and bone formation; ceruloplasmin, related to hemoglobin synthesis;
and tyrosinase, involved in melanin production. Manganese is a
component of pyruvate carboxylase, a key enzyme of carbohydrate
metabolism; Mn superoxide dismutase, which is an important antioxidant
inside of mitochondria; acts in the conversion of mevalonic acid
to squalene, which is part of the pathway of cholesterol synthesis; and
essential for the synthesis of polysaccharides, glycoproteins, and sulphate
chondroitin (organic matrix of bone). Finally, Zn is necessary for
the activity of over 300 enzymes. It is component of Cu-Zn superoxide
dismutase, controlling oxidative stress; carbonic anhydrase, helping
in the acid-base homeostasis; and alkaline phosphatases, which are
a group of isoenzymes, located on the outer layer of the cell membrane,
catalyzing the hydrolysis of organic phosphate esters present
in the extracellular space. In addition, Zn forms part of calmodulin,
protein kinase C, inositol phosphate, thymosin, and participates in the synthesis of prostaglandins. Consequently, these four microminerals
are extremely important for several metabolic and cell vital processes,
also including reproductive physiology.
Strategic administration of ITM during the transition period in
dairy cows is becoming a popular management tool in dairy operations
in the USA. This practice is aimed to provide a boost with these
important elements during critical points of the production cycle
(when animals have greater demands) mainly due to the higher levels
of oxidative stress [5]. Administration of ITM supplements is not intended
to substitute the oral mineral supplementation provided within
the TMR diet on a daily basis. The major constraints of these microminerals
when they are supplemented orally as a unique source is their
low digestive absorption coefficient (< 10%) and great variability in
their bioavailability due to multiple factors such as inadequate forage
mineral levels, variability in free choice mineral intake, management
that does not allow adequate feeding, extremely antagonistic interaction
with elements in feed, water and forage, imbalances in feedstuffs,
and variability in animal mineral requirements over lactation. This
feature makes these microminerals poorly available in the digestive
tract of ruminants [4].
In this trial, the effect of one dose of ITM (Se, Mn, Cu, Zn) at around
35 DIM on reproductive performance was compared against a control
group without any supplementation. A strength of this trial was that
experimental cows from both groups were housed, fed and handled
homogeneously in the same lot. In addition, parity number of cows
from treated group (99 primiparous, 159 multiparous) was similar to
cows from the control group (98 primiparous, 160 multiparous). This
kind of randomized field trial design, using an injectable product, reduces
the variability of the model, making the source of variation for
reproductive responses linked mostly to the parenteral supplementation
of microminerals. Although the CRFS was similar between groups,
the speed on how cows became pregnant was 14 days earlier in treated
than control cows (P ≤ 0.05). Survival analysis is a very powerful statistical
tool to determine how quick cows become pregnant over time.
It is a reflex of pregnancy rate, where eligible cows to be bred (heat detection
rate) and cows that conceive after breeding (conception rate)
are in conjunction analyzed [16]. Conception rate in dairy cattle is affected
by several factors including the incidence of postpartum diseases
[3]. Cows with one postpartum health episode became pregnant at 160
DIM, cows with several postpartum health episodes became pregnant
beyond 200 DIM, while cows with no postpartum diseases became
pregnant at 125 DIM. Unfortunately, the nature of health records from the dairies used in this second trial did not allow for a consistent
analysis of incidence of postpartum diseases either, consequently, we
must acknowledge that the lack of accurate assessment for health conditions
might be an important confounding and sort of variation for
our results. In addition, mineral supplement was injected (35 DIM)
way beyond the high-risk period for periparturient diseases. Hence,
if the randomization process for animals assigned to both groups was
consistent, we must assume the incidence of postpartum diseases was
similar between groups, impacting fertility evenly. Although mineral
supplementation was after than the disease risk period, treated group
still had better reproductive responses than the control group. The
question arising is what would have happened if the mineral application
had been at the time of parturition? Would there have been a
positive impact on the incidence of postpartum diseases? Would there
have been a complementary improvement on herd’s fertility?
A similar study compared cows that were also treated with the
same trace mineral supplement versus a control group. Unlike our
study, the experimental group received 3 injections of the supplement:
at approximately 230 days of gestation, 260 days of gestation, and 35
DIM. Overall results found no significant differences in reproductive
performance (similar pregnancy rate between groups). Median calving
to conception interval for the control and treated group was 110
and 111 days, respectively (P = 0.61). Interestingly, the same study
reported a lower incidence of stillbirth (P=0.039), and endometritis
(P=0.028) for treated than controls cows [7]. This suggests, mineral
supplementation could boost the immune system of cows, reducing
endometritis occurrence. In addition, cows with less stillbirth are less
likely to develop uterine infections. Endometritis is extremely linked
to poor immunity, but not necessarily to poor fertility. In fact, a recent
study demonstrated that genes associated with subclinical endometritis
and neutrophil function had lower capacity of determining reproductive
responses, accordingly, the authors suggested the presence
of different genetic expression patterns that are better predictors of
reproductive efficiency [17]. Contrary to previous results, a meta-analysis
study, reported that endometritis increased significantly calving to
conception interval by 15 days, and decreased the likelihood of pregnancy
by 31% [18]. On the other hand, in the study of Machado et al [7],
calving to conception interval in treated and control group was around
110 DIM, while in our study the same interval was around 120 DIM.
A large data set [19] reported that the mean calving to conception interval
for Holstein cows was 101 days. This suggests that when days
open are shorter and show a value close to the normal average of the population, it is more difficult to improve this characteristic through
nutritional strategies (e.g. mineral supplementation), because of a normal
constraint of genetic and physiological mechanisms. This could be
an explanation why in Machado’s study [7] the mineral booster did not
improve calving to conception interval, unlike our results in which a
positive effect of the same mineral injection was observed on the same
reproductive interval.
Overall, both field trials had similar conception rates between treated
and control groups, but cows receiving an ITM exhibited a time to
pregnancy shorter than the control group. Although they showed the
same risk for conception, becoming pregnant earlier has a great impact
on herd’s fertility and profit. In fact, the cost of an extra day open
over the ideal interval in a herd has been estimated to range from 1.4
to 5.4 US$ [20, 21]. If we extrapolate our findings to a herd of 1,000 cows
reducing its calving to conception interval by 10 days, there will be a
saving between 14,000 to 54,000 US$ per year.
In trial 1 the parenteral application of 2 doses of a commercial multimineral product based on Cu, Se, Zn and Mn during the dry period did not affect BCS at calving and tended to decrease the days from calving to conception, although CRFS was similar between groups. In trial 2, the application of the same mineral product at 35 DIM did not affect the CRFS, but it reduced significantly the time to pregnancy (survival curves) by 14 days when compared with a control group.
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Fecha de recepción artículo original: 02-08-2021
Fecha de aceptación para su publicación: 19-09-2021