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Causes of regular returns to estrus: the seminal dose or boar

This article covers the main semen- or boar-related factors that can cause regular returns to estrus.

Regular returns to estrus occur 18 - 24 days and 38 - 44 days post-service. A sow has a regular return (maintaining the normal duration of an estrous cycle: 18-24 days or its multiples) when fertilization of the eggs has failed or when all fertilized embryos have been lost within the first half of the estrous cycle (<10-12 days).

Under normal conditions these should make up a very small percentage of the matings, < 5%.

Causes related to the semen dose:

1. Semen dose quality: This will affect fertility and prolificacy. Different factors influence the quality of the seminal doses, but perhaps the most important are how old the doses are or those factors affecting their storage, such as the quality of the water, extender, storage conditions (temperature variations), etc.

Table 1. Influence of various aspects of semen quality on AI results

Frequency Farrowing rate (%) BA
Age of semen dose 14/51 -18 -1
Storage 8/51 -7 -0.7
Water quality 8/51 -7 -0.6
Extender quality 8/51 -17 -1.2
Sub-optimal dilution 5/51 -10 -1
Morphology 5/51 -11 -1
Subfertile boars 3/51 -51 -5.8

Flowers, B. 1996. Successful AI programs. Proc. Swine. Reprod. Symp. Am. Soc. Therio, pp 15-25.

1.1. Age of the semen dose

The age of the semen doses will affect sperm quality, reducing their viability and fertilizing capacity.

1.2. Storage

Clearly, poor storage will cause the sperm to age more quickly and thus accelerate the effects shown in the graph above. In storage, factors such as the quality of the water, the extender, or the type of plastic used have an influence.

Table 2. Fertility depending on storage, using a short-term extender (BTS).

Hours in storage Fertility (%) Total born Born alive
4-14 67.7a 11.96a 10.94a
28-38 69.8a 11.73b 10.73b
52-62 64.6b 11.61b 10.64b

a,b Distinct letters in the same column indicate a significant difference with p<0.05. Source: Hofmo, 1991

When using a long-term extender, one can begin to observe differences from the 6th day onward (see table).

Table 3. Fertility and litter size for AI using two different extenders. J. Gadea. 2003

Days A B
Fertility (%) Total born Fertility (%) Total born
2-3 170 85.9 10.3 172 86.1 10.2
3-4 164 86.6 9.2 151 84.1 10.0
4-5 188 85.1 9.0* 183 86.3 10.4*
5-6 201 78.6* 9.4 202 85.6* 9.7

*p<0.01. Source: Kuster and Althouse (1999)

Seminal dose packaging systems are automated in most commercial insemination centers, using different container systems. Plastic bags allow the diluted semen to be brought to storage temperature more quickly than the tubes. However, the type of plastic used also plays a role. It has been proven that plastics including cyclic lactone and bisphenol A diglycidyl ether (BADGE) among their components negatively affect sow fertility, but interestingly they do not affect sperm motility values.

1.3. Sub-optimal dilution

Sub-optimal dilutions are perhaps one of the most common problems. With the implementation of post-cervical insemination and the reduction in volumes used, sperm concentrations are more critical than ever. It is recommended that sperm concentrations of at least 2.5 x 109/ 80 ml be maintained for conventional doses, or 1.5 x 109/ 50-60 ml in the case of post-cervical doses. Lower concentrations will mainly affect prolificacy, but if concentration gets too low, it will also affect fertility.

1.4. Morphology

Numerous studies show that adequate spermatozoa motility and morphology checkings are related to their fertilizing capacity. Therefore, in case of reduced quality, it would be good to increase concentrations to compensate, and also reduce storage times.

Figure&nbsp;2. Total motility (Tmot): the percentage of spermatozoa that have head movement. Sungwon Park, 2013

Figure 2. Total motility (Tmot): the percentage of spermatozoa that have head movement. Sungwon Park, 2013

1.5. 5. Subfertile boars

Not all boars have the same fertilizing capacity. Genetic differences between them, their age, factors such as nutrition, temperature, vaccinations, or collection frequency are some of the factors that can affect the fertilizing quality of their semen.

Table 4. Effect of boar age on seminal dose fertility

Age of group N1 N2 Farrowing rate (%) BA (average ± SEM)
Young boars (7-10 months, n=5) 11 55 65.00 (117/180)a 11.62 ± 0.51a
Mature boars (18-33 months, n=7) 25 175 87.24 (1259/1443)b 10.53 ± 0.25a
Old boars (51-61 months, n=5) 14 70 84.74 (372/439)b 11.13 ± 0.23a
TOTAL 11-25 300 84.77 (1747/2062) 10.87 ± 0.23

The values with different letters within each column are significantly different (P<0.001; x2 = 29.99 - 61.42). The effect of the boar on the farrowing rate is significant (P < 0.005). N1 and N2 denote the number of ejaculates used per boar and per group, respectively. Tsakmakidis, I.A. et al. 2012.

2. Quality of the insemination process

The quality of the insemination process will also have an impact on the percentage of returns. Poor heat detection, which can lead to incorrect timing for insemination, or an insufficient number of doses, can have a major impact on the results.

Table 5. Influence of various aspects on AI results. Flowers, B. 1996

Frequency Farrowing rate (%) BA
Poor heat detection 15/50 -15 -0.6
Low number of services 10/50 -8 -0.3
Incorrect timing of AI 8/50 -7 -0.4
Poor AI technique 5/50 -8 -0.5

3. Post-insemination management

Stress, in all its forms, can be one of the causes for sows having a regular return to estrus. There are two particularly critical times:

  • The first 30 minutes post-insemination. Stress during this time will block the oxytocin responsible for sperm transport and may affect the proper fertilization of the ova.
  • The first 10-12 days post-service (may be heat stress). During this time stress can easily affect the proper implantation of the embryos, leading to the loss of gestation.

Table 6. Influence of post-IA management. Flowers, B. 1996

Frequency Farrowing rate (%) Born alive
Mixing sows 8//19 -7 -1.8
Moving sows 7/19 -10 -1.2

See the sow-related causes for regular returns

Use the button above or the flowchart to continue troubleshooting the returns, or to access other parts of the tool.

Types of gestation losses that can lower the farrowing rate, detailing the different types of returns to estrus based on they occur.
Types of gestation losses that can lower the farrowing rate, detailing the different types of returns to estrus based on they occur.

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