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Artificial insemination

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Artificial insemination
Schematic illustration of human artificial insemination
ICD-9-CM69.92
MeSHD007315

Artificial insemination is the deliberate introduction of sperm into a female's cervix or uterine cavity for the purpose of achieving a pregnancy through in vivo fertilization by means other than sexual intercourse. It is a fertility treatment for humans, and is a common practice in animal breeding, including dairy cattle (see frozen bovine semen) and pigs.

Artificial insemination may employ assisted reproductive technology, sperm donation and animal husbandry techniques. Artificial insemination techniques available include intracervical insemination (ICI) and intrauterine insemination (IUI). Where gametes from a third party are used, the procedure may be known as 'assisted insemination'.

Humans

History

The first recorded case of artificial insemination was John Hunter in 1790, who helped impregnate a linen draper's wife.[1][2] The first reported case of artificial insemination by donor occurred in 1884: William H. Pancoast, a professor in Philadelphia, took sperm from his "best looking" student to inseminate an anesthetized woman without her knowledge.[3][4] The case was reported 25 years later in a medical journal.[5] The sperm bank was developed in Iowa starting in the 1950s in research conducted by University of Iowa medical school researchers Jerome K. Sherman and Raymond Bunge.[6]

In the United Kingdom, the British obstetrician Mary Barton founded one of the first fertility clinics to offer donor insemination in the 1930s, with her husband Bertold Wiesner fathering hundreds of offspring.[7][8]

In the 1980s, direct intraperitoneal insemination (DIPI) was occasionally used, where doctors injected sperm into the lower abdomen through a surgical hole or incision, with the intention of letting them find the oocyte at the ovary or after entering the genital tract through the ostium of the fallopian tube.[9][10]

General

The sperm used in artificial insemination may be provided by either the woman's husband or partner (partner sperm) or by a known or anonymous sperm donor (see sperm donation (donor sperm)). The beneficiaries of artificial insemination are women who desire to give birth to their own child who may be single, women who are in a lesbian relationship or women who are in a heterosexual relationship but with a male partner who is infertile or who has a physical impairment which prevents full intercourse from taking place. Artificial insemination techniques were originally used mainly to assist heterosexual couples to conceive where they were having difficulties. With the advancement of techniques in this field, notably ICSI, the use of artificial insemination for such couples has largely been rendered unnecessary. However, there are still reasons why a couple would seek to use artificial insemination using the male partner's sperm. In the case of such couples, before artificial insemination is turned to as the solution, doctors will require an examination of both the male and female involved in order to remove any and all physical hindrances that are preventing them from naturally achieving a pregnancy including any factors which prevent the couple from having satisfactory sexual intercourse. The couple is also given a fertility test to determine the motility, number, and viability of the male's sperm and the success of the female's ovulation. From these tests, the doctor may or may not recommend a form of artificial insemination. The results of investigations may, for example, show that the woman's immune system may be rejecting her partner's sperm as invading molecules.[11] Women who have issues with the cervix – such as cervical scarring, cervical blockage from endometriosis, or thick cervical mucus – may also benefit from artificial insemination, since the sperm must pass through the cervix to result in fertilization.

Nowadays artificial insemination in humans is mainly used as a substitute for sexual intercourse for women without a male partner who wish to have their own children and who do so where sperm from a sperm donor is used. Donor sperm may be used in other ways, such as IVF and ICSI and a woman having a baby by a sperm donor will usually also have these methods available to her as alternatives to artificial insemination. Intracervical insemination is the easiest and most common insemination technique and can be used in the home for self-insemination without medical practitioner assistance.[12] Compared with natural insemination (i.e., insemination by sexual intercourse), artificial insemination can be more expensive and more invasive, and may require professional assistance.

Some countries have laws which restrict and regulate who can donate sperm and who is able to receive artificial insemination, and the consequences of such insemination. Some women who live in a jurisdiction which does not permit artificial insemination in the circumstance in which she finds herself may travel to another jurisdiction which permits it.

If the procedure is successful, the woman will conceive and carry a baby to term in the normal manner. A pregnancy resulting from artificial insemination is no different from a pregnancy achieved by sexual intercourse. In all cases of artificial insemination, the recipient woman will be the biological mother of any child produced, and the male whose sperm is used will be the biological father.

There are multiple methods used to obtain the semen necessary for artificial insemination. Some methods require only men, while others require a combination of a male and female. Those that require only men to obtain semen are masturbation or the aspiration of sperm by means of a puncture of the testicle and epydidymus. Methods of collecting semen that involve a combination of a male and female include interrupted intercourse, intercourse with a 'collection condom', or the post-coital aspiration of the semen from the vagina.

Preparations

Timing is critical, as the window and opportunity for fertilization is little more than twelve hours from the release of the ovum. To increase the chance of success, the woman's menstrual cycle is closely observed, often using ovulation kits, ultrasounds or blood tests, such as basal body temperature tests over, noting the color and texture of the vaginal mucus, and the softness of the nose of her cervix. To improve the success rate of artificial insemination, drugs to create a stimulated cycle may be used, but the use of such drugs also results in an increased chance of a multiple birth.

Sperm can be provided fresh or washed.[13] Washed sperm is required in certain situations. Pre- and post-concentration of motile sperm is counted. Sperm from a sperm bank will be frozen and quarantined for a period, and the donor will be tested before and after production of the sample to ensure that he does not carry a transmissible disease. Sperm from a sperm bank will also be suspended in a semen extender which assists with freezing, storing and shipping.

If sperm is provided by a private donor, either directly or through a sperm agency, it is usually supplied fresh, not frozen, and it will not be quarantined. Donor sperm provided in this way may be given directly to the recipient woman or her partner, or it may be transported in specially insulated containers. Some donors have their own freezing apparatus to freeze and store their sperm.

Techniques

The human female reproductive system. The cervix is part of the uterus. The cervical canal connects the interiors of the uterus and vagina.

Semen used is either fresh, raw, or frozen. Where donor sperm is supplied by a sperm bank, it will always be quarantined and frozen, and will need to be thawed before use. The sperm is ideally donated after two or three days of abstinence, without lubrication as the lubricant can inhibit the sperm motility.[14] When an ovum is released, semen is introduced into the woman's vagina, uterus or cervix, depending on the method being used.

Sperm is occasionally inserted twice within a 'treatment cycle'.

Intracervical

Intracervical insemination (ICI) is the method of artificial insemination which most closely mimics the natural ejaculation of semen by the penis into the vagina during sexual intercourse. It is painless and is the simplest, easiest and most common method of artificial insemination involving the introduction of unwashed or raw semen into the vagina at the entrance to the cervix, usually by means of a needleless syringe.

ICI is commonly used in the home, by self-insemination and practitioner insemination. Sperm used in ICI inseminations does not have to be 'washed' to remove seminal fluid so that raw semen from a private donor may be used. Semen supplied by a sperm bank prepared for ICI or IUI use is suitable for ICI. ICI is a popular method of insemination amongst single and lesbian women purchasing donor sperm on-line.

Although ICI is the simplest method of artificial insemination, a meta-analysis has shown no difference in live birth rates compared with IUI.[15] It may also be performed privately by the woman, or, if she has a partner, in the presence of her partner, or by her partner. ICI was previously used in many fertility centers as a method of insemination, although its popularity in this context has waned as other, more reliable methods of insemination have become available.

During ICI, air is expelled from a needleless syringe which is then filled with semen which has been allowed to liquify. A specially-designed syringe, wider and with a more rounded end, may be used for this purpose. Any further enclosed air is removed by gently pressing the plunger forward. The woman lies on her back and the syringe is inserted into the vagina. Care is optimal when inserting the syringe, so that the tip is as close to the entrance to the cervix as possible. A vaginal speculum may be used for this purpose and a catheter may be attached to the tip of the syringe to ensure delivery of the semen as close to the entrance to the cervix as possible. The plunger is then slowly pushed forward and the semen in the syringe is gently emptied deep into the vagina. It is important that the syringe is emptied slowly for safety and for the best results, bearing in mind that the purpose of the procedure is the replicate as closely as possible a natural deposit of the semen in the vagina. The syringe (and catheter if used) may be left in place for several minutes before removal. The woman can bring herself to orgasm so that the cervix 'dips down' into the pool of semen, again replicating closely vaginal intercourse, and this may improve the success rate.

Following insemination, fertile sperm will swim through the cervix into the uterus and from there to the fallopian tubes in a natural way as if the sperm had been deposited in the vagina through intercourse. The woman is therefore advised to lie still for about half-an-hour to assist conception.

One insemination during a cycle is usually sufficient. Additional inseminations during the same cycle may not improve the chances of a pregnancy.

Ordinary sexual lubricants should not be used in the process, but special fertility or 'sperm-friendly' lubricants can be used for increased ease and comfort.

When performed at home without the presence of a professional, aiming the sperm in the vagina at the neck of the cervix may be more difficult to achieve and the effect may be to 'flood' the vagina with semen, rather than to target it specifically at the entrance to the cervix. This procedure is sometimes referred to as 'intravaginal insemination' (IVI).[16] Sperm supplied by a sperm bank will be frozen and must be allowed to thaw before insemination. The sealed end of the straw itself must be cut off and the open end of the straw is usually fixed straight on to the tip of the syringe, allowing the contents to be drawn into the syringe. Sperm from more than one straw can generally be used in the same syringe. Where fresh semen is used, this must be allowed to liquefy before inserting it into the syringe, or alternatively, the syringe may be back-loaded.

A conception cap, which is a form of conception device, may be inserted into the vagina following insemination and may be left in place for several hours. Using this method, a woman may go about her usual activities while the cervical cap holds the semen in the vagina close to the entrance to the cervix. Advocates of this method claim that it increases the chances of conception. One advantage with the conception device is that fresh, non-liquefied semen may be used. The man may ejaculate straight into the cap so that his fresh semen can be inserted immediately into the vagina without waiting for it to liquefy, although a collection cup may also be used. Other methods may be used to insert semen into the vagina notably involving different uses of a conception cap. These include a specially designed conception cap with a tube attached which may be inserted empty into the vagina after which liquefied semen is poured into the tube. These methods are designed to ensure that semen is inseminated as close as possible to the cervix and that it is kept in place there to increase the chances of conception.

Intrauterine

Intrauterine insemination (IUI) involves injection of washed sperm directly into the uterus with a catheter. Insemination in this way means that the sperm do not have to swim through the cervix which is coated with a mucus layer. This layer of mucus can slow down the passage of sperm and can result in many sperm perishing before they can enter the uterus. Donor sperm is sometimes tested for mucus penetration if it is to be used for ICI inseminations but partner sperm may or may not be able to pass through the cervix. In these cases, the use of IUI can provide a more efficient delivery of the sperm. In general terms, IUI is usually regarded as more efficient than ICI or IVI. It is therefore the method of choice for single and lesbian women wishing to conceive using donor sperm since this group of recipients usually require artificial insemination because they do not have a male partner, not because they have medical problems. Owing to the high number of these recipients using donor sperm services, IUI is therefore the most popular method of insemination today at a fertility clinic. The term 'artificial insemination' has, in many cases, come to mean IUI insemination.

It is important that washed sperm is used because unwashed sperm may elicit uterine cramping, expelling the semen and causing pain, due to content of prostaglandins. (Prostaglandins are also the compounds responsible for causing the myometrium to contract and expel the menses from the uterus, during menstruation.) Resting on the table for fifteen minutes after an IUI is optimal for the woman to increase the pregnancy rate.[17]

Using this technique, as with ICI, fertilization takes place naturally in the external part of the fallopian tubes in the same way that occurs following intercourse.

For heterosexual couples, the indications to perform an intrauterine insemination are usually a moderate male factor, the incapability to ejaculate in vagina and an idiopathic infertility. A short period of ejaculatory abstinence before intrauterine insemination is associated with higher pregnancy rates.[18] For the man, a TMS of more than 5 million per ml is optimal.[19] In practice, donor sperm will satisfy these criteria and since IUI is a more efficient method of artificial insemination than ICI and, because of its generally higher success rate, IUI is usually the insemination procedure of choice for single women and lesbians using donor semen in a fertility centre. Lesbians and single women are less likely to have fertility issues of their own and enabling donor sperm to be inserted directly into the womb will often produce a better chance of conceiving. A 2019 study showed that pregnancy rates were similar between lesbian women and heterosexual women undergoing IUI. However, it was found that there is a significantly higher multiple gestation rate among lesbian women undergoing ovulation induction (OI) when compared to lesbian women undergoing natural cycles.

Lesbian couples may either select a friend or family member as their sperm donor or choose an anonymous donor.[20] After a donor sperm is selected, a couple can proceed with donor sperm IUI. IUI is the least expensive option for same-sex couples and can be done without the use of medication.[21] According to a study from 2021, lesbian women undergoing IUI had a clinical pregnancy rate of 13.2% per cycle and 42.2% success rate given the average number of cycles at 3.6.[22]

Although IUI is typically carried out in a medical setting, society is increasingly recognizing the important role that this plays in the lives of individuals who might otherwise not conceive through heterosexual penetrative sexual intercourse. Especially for LGBTQ couples, this is one of the more cost-effective avenues to parenting. While IUI is open to many, it typically still includes hetero-reproductive narratives. To improve the way society talks about and carries out IUI, it is important to bring inclusive language into the conversation. One way to do this is to bring LGBTQ narratives into this process, with a particular emphasis on this being a family-centered process.[23] Even in a medical setting, it is important to bring intimacy and family-centeredness into this process, as this promotes connectedness and inclusiveness in what can be seen as a hostile and discriminatory environment.[23] LGBTQ couples or individuals typically have to navigate more complexities and barriers than heterosexual couples when undergoing IUI,[23] such as stigma and carrier decisions, so allowing room for intimacy and connectedness in the process can improve the experience for individuals, reduce stress, and minimize barriers that target marginalized individuals.

Unlike ICI, intrauterine insemination normally requires a medical practitioner to perform the procedure. One of the requirements is to have at least one permeable tube, proved by hysterosalpingography. The infertility duration is also important. A female under 30 years of age has optimal chances with IUI; A promising cycle is one that offers two follicles measuring more than 16 mm, and estrogen of more than 500 pg/mL on the day of hCG administration.[19] However, GnRH agonist administration at the time of implantation does not improve pregnancy outcome in intrauterine insemination cycles according to a randomized controlled trial.[24] One of the prominent private clinic in Europe has published a data A multiple logistic regression model showed that sperm origin, maternal age, follicle count at hCG administration day, follicle rupture, and the number of uterine contractions observed after the second insemination procedure were associated with the live-birth rate[25] The steps to follow in order to perform an intrauterine insemination are:

  • Mild Controlled Ovarian Stimulation (COS): there is no control of how many oocytes are at the same time when stimulating ovulation. For that reason, it is necessary to check the amount being ovulated via ultrasound (checking the amount of follicles developing at the same time) and administering the desired amount of hormones.
  • Ovulation Induction: using substances known as ovulation inductors.
  • Semen capacitation: wash and centrifugation, swim-up, or gradient. The insemination should not be performed later than an hour after capacitation. 'Washed sperm' may be purchased directly from a sperm bank if donor semen is used, or 'unwashed semen' may be thawed and capacitated before performing IUI insemination, provided that the capacitation leaves a minimum of, usually, five million motile sperm.
  • Luteal Phase support: a lack of progesterone in the endometrium could end a pregnancy. To avoid that 200 mg/day of micronized progesterone are administered via vagina. If there is pregnancy, this hormone is kept administering until the tenth week of pregnancy.

The cost breakdown for Intrauterine Insemination (IUI) involves several components. The procedure itself typically ranges from $300 to $1,000 per cycle without insurance.[26] The cost of the sperm may vary widely, with prices per vial ranging from $500 to $1,000 or more from a sperm bank.[27] Additional expenses might include consultation fees, ovulation-inducing medication, ultrasounds, and blood tests.[26]

The extent of insurance coverage for fertility treatments, including Intrauterine Insemination (IUI), varies considerably. Some insurance plans may cover some of the costs, while others may not provide any financial support for fertility treatments. Coverage depends on various factors, such as the insurance plan, state policies and regulations, and the underlying cause of infertility. Several states have mandated insurers to provide coverage for infertility services.[28]

IUI can be used in conjunction with controlled ovarian hyperstimulation (COH). Clomiphene Citrate is the first line, Letrozole is second line, in order to stimulate ovaries before moving on to IVF.[14] Still, advanced maternal age causes decreased success rates; women aged 38–39 years appear to have reasonable success during the first two cycles of ovarian hyperstimulation and IUI. However, for women aged over 40 years, there appears to be no benefit after a single cycle of COH/IUI.[29] Medical experts therefore recommend considering in vitro fertilization after one failed COH/IUI cycle for women aged over 40 years.[29]

A double intrauterine insemination theoretically increases pregnancy rates by decreasing the risk of missing the fertile window during ovulation. However, a randomized trial of insemination after ovarian hyperstimulation found no difference in live birth rate between single and double intrauterine insemination.[30] A Cochrane found uncertain evidence about the effect of IUI compared with timed intercourse or expectant management on live birth rates but IUI with controlled ovarian hyperstimulation is probably better than expectant management.[31]

Due to the lack of reliable evidence from controlled clinical trials, it is not certain which semen preparation techniques are more effective (wash and centrifugation; swim-up; or gradient) in terms of pregnancy and live birth rates.[32]

Intrauterine tuboperitoneal

Intrauterine tuboperitoneal insemination (IUTPI) involves injection of washed sperm into both the uterus and fallopian tubes. The cervix is then clamped to prevent leakage to the vagina, best achieved with a specially designed double nut bivalve (DNB) speculum. The sperm is mixed to create a volume of 10 ml, sufficient to fill the uterine cavity, pass through the interstitial part of the tubes and the ampulla, finally reaching the peritoneal cavity and the Pouch of Douglas where it would be mixed with the peritoneal and follicular fluid. IUTPI can be useful in unexplained infertility, mild or moderate male infertility, and mild or moderate endometriosis.[33] In non-tubal sub fertility, fallopian tube sperm perfusion may be the preferred technique over intrauterine insemination.[34]

Intratubal

Intratubal insemination (ITI) involves injection of washed sperm into the fallopian tube, although this procedure is no longer generally regarded as having any beneficial effect compared with IUI.[35] ITI however, should not be confused with gamete intrafallopian transfer, where both eggs and sperm are mixed outside the woman's body and then immediately inserted into the fallopian tube where fertilization takes place.

Pregnancy rate

Approximate pregnancy rate as a function of total sperm count (may be twice as large as total motile sperm count). Values are for intrauterine insemination. (Old data, rates are likely higher these days)[36]

The rates of successful pregnancy for artificial insemination are 10-15% per menstrual cycle using ICI,[37] and 15–20% per cycle for IUI.[38] In IUI, about 60 to 70% have achieved pregnancy after 6 cycles.[39]

However, these pregnancy rates may be very misleading, since many factors have to be included to give a meaningful answer, e.g. definition of success and calculation of the total population.[40] These rates can be influenced by age, overall reproductive health, and if the patient had an orgasm during the insemination. The literature is conflicting on immobilization after insemination has increasing the chances of pregnancy [41] Previous data suggests that it is statistically significant for the patient to remain immobile for 15 minutes after insemination, while another review article claims that it is not.[42] A point of consideration, is that it does cost the patient or healthcare system to remain immobile for 15 minutes if it does increase the chances. For couples with unexplained infertility, unstimulated IUI is no more effective than natural means of conception.[43][44]

The pregnancy rate also depends on the total sperm count, or, more specifically, the total motile sperm count (TMSC), used in a cycle. The success rate increases with increasing TMSC, but only up to a certain count, when other factors become limiting to success. The summed pregnancy rate of two cycles using a TMSC of 5 million (may be a TSC of ~10 million on graph) in each cycle is substantially higher than one single cycle using a TMSC of 10 million. However, although more cost-efficient, using a lower TMSC also increases the average time taken to achieve pregnancy. Women whose age is becoming a major factor in fertility may not want to spend that extra time.

Samples per child

The number of samples (ejaculates) required to give rise to a child varies substantially from person to person, as well as from clinic to clinic. However, the following equations generalize the main factors involved:

For intracervical insemination:

  • N is how many children a single sample can give rise to.
  • Vs is the volume of a sample (ejaculate), usually between 1.0 mL and 6.5 mL[45]
  • c is the concentration of motile sperm in a sample after freezing and thawing, approximately 5–20 million per ml but varies substantially
  • rs is the pregnancy rate per cycle, between 10% and 35% [37]
  • nr is the total motile sperm count recommended for vaginal insemination (VI) or intra-cervical insemination (ICI), approximately 20 million pr. ml.

The pregnancy rate increases with increasing number of motile sperm used, but only up to a certain degree, when other factors become limiting instead.

Derivation of the equation (click at right to view)
In the simplest form, the equation reads:
N is how many children a single sample can give rise to
ns is the number of vials produced per sample
nc is the number of vials used in a cycle
rs is the pregnancy rate per cycle

ns can be further split into:

ns is the number of vials produced per sample
Vs is the volume of a sample
Vv is the volume of the vials used

nc may be split into:

nc is the number of vials used in a cycle
nr is the number of motile sperm recommended for use in a cycle
ns is the number of motile sperm in a vial

ns may be split into:

ns is the number of motile sperm in a vial
Vv is the volume of the vials used
c is the concentration of motile sperm in a sample

Thus, the factors can be presented as follows:

N is how many children a single sample can help giving rise to
Vs is the volume of a sample
c is the concentration of motile sperm in a sample
rs is the pregnancy rate per cycle
nr is the number of motile sperm recommended for use in a cycles
Vv is the volume of the vials used (its value does not affect N and may be eliminated. In short, the smaller the vials, the more vials are used)
Approximate live birth rate (rs) among infertile couples as a function of total motile sperm count (nr). Values are for intrauterine insemination.[citation needed]

With these numbers, one sample would on average help giving rise to 0.1–0.6 children, that is, it actually takes on average 2–5 samples to make a child.

For intrauterine insemination, a centrifugation fraction (fc) may be added to the equation:

fc is the fraction of the volume that remains after centrifugation of the sample, which may be about half (0.5) to a third (0.33).

On the other hand, only 5 million motile sperm may be needed per cycle with IUI (nr=5 million)

Thus, only 1–3 samples may be needed for a child if used for IUI.

Social implications

One of the key issues arising from the rise of dependency on assisted reproductive technology (ARTs) is the pressure placed on couples to conceive, "where children are highly desired, parenthood is culturally mandatory, and childlessness socially unacceptable".[46]

The medicalization of infertility creates a framework in which individuals are encouraged to think of infertility quite negatively. In many cultures donor insemination is religiously and culturally prohibited, often meaning that less accessible "high tech" and expensive ARTs, like IVF, are the only solution.

An over-reliance on reproductive technologies in dealing with infertility prevents many – especially, for example, in the "infertility belt" of central and southern Africa – from dealing with many of the key causes of infertility treatable by artificial insemination techniques; namely preventable infections, dietary and lifestyle influences.[46]

If good records are not kept, the offspring when grown up risk accidental incest.

Risk Factors

The risk factors of artificial insemination are comparatively low to other forms of fertility treatment. The most prominent risk factor would be infection after the procedure, with other risk factors including a higher risk of having twins or triplets, and minor vaginal bleeding during the procedure.[47]

Although these risk factors are minor and generally manageable, there is a significant knowledge gap between identity groups around risk factors for fertility treatments in general. For instance, it was found that LGBTQ+ individuals had "had significant knowledge gaps of risk factors associated with reproductive outcomes when compared to heterosexual female peers."[48] Therefore, it is imperative that providers take extra care in educating their LGBTQ+ patients on potential risk factors of artificial insemination. The implications of this knowledge gap between LGTBQ+ individuals and their heterosexual counterparts are serious and worth noting. Lack of access to proper information and risk factors around procedures like these may dissuade someone from pursuing these procedures altogether. As a result, there will be less normalization of LGBTQ+ family making and reproduction, which only perpetuates this cycle of lack of information among LGBTQ+ folks.

Some countries restrict artificial insemination in a variety of ways. For example, some countries do not permit AI for single women, and other countries do not permit the use of donor sperm.

As of May 2013, the following European countries permit medically assisted AI for single women:

Law in the United States

History of Law Around Artificial Insemination

Artificial insemination used to be seen as adultery and was illegal until the 1960s when states started recognizing the child born from artificial insemination as legitimate.[50] Once the children began to be recognized as legitimate, legal questions around who the parents of the child are, how to handle surrogacy, paternity rights, and eventually artificial insemination and LGBT+ parents began to arise. Prior to the use of artificial insemination, the legal parents of a child were the two people who conceived the child or the person who birthed the child and their legal spouse,[50] but artificial insemination complicates the legal process of becoming a parent as well as who is the parent of the child. Deciding who the parents of the child are is the largest legal predicament around artificial insemination. However, questions around surrogacy and donor's rights also appear as a side question to determining the parent(s). Some major cases that deal with artificial insemination and parental rights are, K.M v E.G, Johnson v Calvert, Matter of Baby M, and In Re K.M.H.

Legal Parental Relations and Artificial Insemination

When children are conceived the traditional way, there is little discrepancy around who the legal parents of the child are. However, because children conceived using artificial insemination may not be genetically related to one or more of their parents, who the legal parents of the child are can come into question. Prior to the passage of the Uniform Parentage Act in 1973, children conceived via artificial insemination were deemed as “illegitimate” children.[50] The Uniform Parentage Act then recognized the children born from artificial insemination as legal and laid precedent for how the legal parents of the child were decided.[50] However, this act only applied to the children of those married couples.[50] It established that the person who birthed the child was the mother and the father would be the husband of the woman.[50] In 2002, the Uniform Parentage Act, which is adopted individually on a state by state basis,[51] was revised to address non married couples and states that an unmarried couple has the same rights to the child that a married couple would.[51] This extended who has the right to be a parent to a man who would supposedly fill in the social role as a “father.”[51] There were now numerous ways to establish parental rights for both the mother and the father depending on if the child was born using a sperm donor or a surrogate. Currently, a revised version of the Uniform Parentage Act is starting to be passed in a few states that expands how parental relations can be determined.[52] This bill includes expanding “father” to mean any person who would fill the role of a father, regardless of their gender and “mother” is expanded to anyone who gives birth to the child regardless of gender. In addition, this act would also change any language of “husband” or “wife” to “spouse.”[52]

Paternity rights

There is no federal law that applies to all fifty states when it comes to artificial insemination and paternity rights, but the Uniform Parentage Act is a model which many states have adopted.[53] Under the 1973 UPA, married heterosexual couples making use of artificial insemination through a licensed physician could list the husband as the natural father of the child, rather than the sperm donor.[53] Since then a revised version of the Act has been introduced, though to less widespread adoption[53]

Generally paternity is not an issue when artificial insemination is between a married woman and an anonymous donor.[53] Most states provide that anonymous donors' paternity claims are not recognized, and most sperm donation centers make use of contracts that require donors to sign away their paternity rights before they can participate.[53] When the mother knows the donor, however, or engages in artificial insemination while unmarried, complications may arise.[53] In cases of private sperm donation, paternity rights and responsibilities are often conferred onto sperm donors when: the donor and recipient did not comply with state laws regarding artificial insemination, the sperm donor and recipient know one another, or the donor had the intent of being a father to the child.[53] When one or a number of these things is true, courts have at times found written agreements relinquishing parental rights to be unenforceable.[53]

Opposition and criticism

Some theologically-buttressed arguments reject the moral validity of this practice, such as Pope John XXIII. However, according to a document of the USCCB, the intrauterine insemination (IUI) of “licitly obtained” (normal intercourse with a silastic sheath i.e. a perforated condom) but technologically prepared semen sample (washed, etc.) has been neither approved nor disapproved by Church authority and its moral validity remains under discussion.[54]

Other animals

A man performing artificial insemination of a cow.
A breeding mount with built-in artificial vagina used in semen collection from horses for use in artificial insemination

Artificial insemination is used for pets, livestock, endangered species, and animals in zoos or marine parks difficult to transport.

Reasons and techniques

It may be used for many reasons, including to allow a male to inseminate a much larger number of females, to allow the use of genetic material from males separated by distance or time, to overcome physical breeding difficulties, to control the paternity of offspring, to synchronize births, to avoid injury incurred during natural mating, and to avoid the need to keep a male at all (such as for small numbers of females or in species whose fertile males may be difficult to manage).

Artificial insemination is much more common than natural mating, as it allows several female animals to be impregnated from a single male. For instance, up to 30-40 female pigs can be impregnated from a single boar.[55] Workers collect the semen by masturbating the boars, then insert it into the sows via a raised catheter known as a pork stork.[56] Boars are still physically used to excite the females prior to insemination, but are prevented from actually mating.[57]

Semen is collected, extended, then cooled or frozen. It can be used on-site or shipped to the female's location. If frozen, the small plastic tube holding the semen is referred to as a straw. To allow the sperm to remain viable during the time before and after it is frozen, the semen is mixed with a solution containing glycerol or other cryoprotectants. An extender is a solution that allows the semen from a donor to impregnate more females by making insemination possible with fewer sperm. Antibiotics, such as streptomycin, are sometimes added to the sperm to control some bacterial venereal diseases. Before the actual insemination, estrus may be induced through the use of progestogen and another hormone (usually PMSG or Prostaglandin F2α).

History

Artificial insemination tools brought from the USSR by Luis Thomasset in 1935 to work at Cambridge Laboratories and South America.

The first viviparous animal to be artificially fertilized was a dog. The experiment was conducted with success by the Italian Lazzaro Spallanzani in 1780. Another pioneer was the Russian Ilya Ivanov in 1899. In 1935, diluted semen from Suffolk sheep was flown from Cambridge in Britain to Kraków, Poland, as part of an international research project.[58] The participants included Prawochenki (Poland), Milovanoff (USSR), Hammond and Walton (UK), and Thomasset (Uruguay).

Modern artificial insemination was pioneered by John O. Almquist of Pennsylvania State University. He improved breeding efficiency by the use of antibiotics (first proven with penicillin in 1946) to control bacterial growth, decreasing embryonic mortality, and increase fertility. This, and various new techniques for processing, freezing, and thawing of frozen semen significantly enhanced the practical utilization of artificial insemination in the livestock industry and earned him the 1981 Wolf Foundation Prize in Agriculture.[59] Many techniques developed by him have since been applied to other species, including humans.

Species

Artificial insemination is used in many non-human animals, including sheep, horses,[60] cattle, pigs, dogs, pedigree animals generally, zoo animals, turkeys and creatures as tiny as honeybees and as massive as orcas (killer whales).

Artificial insemination of farm animals is common in the developed world, especially for breeding dairy cattle (75% of all inseminations). Swine are also bred using this method (up to 85% of all inseminations). It is an economical means for a livestock breeder to improve their herds utilizing males having desirable traits.

Although common with cattle and swine, artificial insemination is not as widely practiced in the breeding of horses. A small number of equine associations in North America accept only horses that have been conceived by "natural cover" or "natural service" – the actual physical mating of a mare to a stallion – the Jockey Club being the most notable of these, as no artificial insemination is allowed in Thoroughbred breeding.[61] Other registries such as the AQHA and warmblood registries allow registration of foals created through artificial insemination, and the process is widely used allowing the breeding of mares to stallions not resident at the same facility – or even in the same country – through the use of transported frozen or cooled semen.

In modern species conservation, semen collection and artificial insemination are used also in birds. In 2013 scientist of the Justus-Liebig-University of Giessen, Germany, from the working group of Michael Lierz, Clinic for birds, reptiles, amphibians, and fish, developed a novel technique for semen collection and artificial insemination in parrots producing the world's first macaw by assisted reproduction.[62]

Scientists working with captive orcas were able to pioneer the technique in the early 2000s, resulting in "the first successful conceptions, resulting in live offspring, using artificial insemination in any cetacean species".[63] John Hargrove, a SeaWorld trainer, describes Kasatka as being the first orca to receive artificial insemination.[64]

Violation of rights

Artificial insemination on animals has been criticised as a violation of animal rights, with animal rights advocates equating it with rape and arguing it constitutes institutionalized bestiality.[65][66] Artificial insemination of farm animals is condemned by animal rights campaigners such as People for the Ethical Treatment of Animals (PETA) and Joey Carbstrong, who identify the practice as a form of rape due to its sexual, involuntary and perceived painful nature.[67][68] Animal rights organizations such as PETA and Mercy for Animals frequently write against the practice in their articles.[69][70][71] Much of the meat production in the United States depends on artificial insemination, resulting in an explosive growth of the procedure over the past three decades.[72] The state of Kansas makes no exceptions for artificial insemination under its bestiality law, thus making the procedure illegal.[72]

Criteria for benefiting from artificial insemination according to the 2021 Bioethics Law

According to the 2021 Bioethics Law, the criteria that must be met to benefit from artificial insemination are as follows:

  1. Artificial insemination can be performed using sperm from the husband or frozen sperm from an anonymous donor.
  2. Both spouses or the unmarried woman must consent in advance to artificial insemination or embryo transfer.
  3. The parenting project must be validated through a series of interviews with professionals (doctors, psychologists, etc.).
  4. Individuals benefiting from artificial insemination must be of reproductive age.

The 2021 Bioethics Law has expanded the scope of Medically Assisted Procreation (MAP).[73]

See also

References

  1. ^ "ARTIFICIAL INSEMINATION OF MARRIED WOMEN (Hansard, 26 February 1958)". api.parliament.uk. Retrieved 2020-03-02.
  2. ^ Ombelet, W.; Van Robays, J. (2015). "Artificial insemination history: hurdles and milestones". Facts, Views & Vision in ObGyn. 7 (2): 137–143. ISSN 2032-0418. PMC 4498171. PMID 26175891.
  3. ^ Yuko, Elizabeth (2016-01-08). "The First Artificial Insemination Was an Ethical Nightmare". The Atlantic. Retrieved 2019-07-17.
  4. ^ Kramer, Wendy (2016-05-10). "A Brief History of Donor Conception". HuffPost. Retrieved 2021-07-29.
  5. ^ "Letter to the Editor: Artificial Impregnation". The Medical World: 163–164. April 1909. Archived from the original on 2012-07-24. (cited in Gregoire, A.; Mayer, R. (1964). "The impregnators". Fertility and Sterility. 16: 130–4. doi:10.1016/s0015-0282(16)35476-0. PMID 14256095.)
  6. ^ Kara W. Swanson, "The Birth of the Sperm Bank," Annals of Iowa, 71 (Summer 2012), 241–76.
  7. ^ Smith, Rebecca (2016-08-10). "British man 'fathered 600 children' at own fertility clinic - Telegraph". Archived from the original on 2016-08-10. Retrieved 2020-02-05.
  8. ^ Hitchings, Henry (2019-03-26). "Mary's Babies review — Fertility clinic's dark truth". www.standard.co.uk. Retrieved 2021-07-29.
  9. ^ Cox, Lauren (3 February 2010). "Oral Sex, a Knife Fight and Then Sperm Still Impregnated Girl. Account of a Girl Impregnated After Oral Sex Shows Sperms' Incredible Survivability". abc NEWS.
  10. ^ Cimino, C.; Guastella, G.; Comparetto, G.; Gullo, D.; Perino, A.; Benigno, M.; Barba, G.; Cittadini, E. (1988). "Direct intraperitoneal insemination (DIPI) for the treatment of refractory infertility unrelated to female organic pelvic disease". Acta Europaea Fertilitatis. 19 (2): 61–68. PMID 3223194.
  11. ^ Robinson, Sarah (2010-06-24). "Professor". International Federation of Gynecology and Obstetrics. Archived from the original on 2012-11-04. Retrieved 2012-12-27.
  12. ^ Seattle Sperm Bank
  13. ^ Adams, Robert (1988). in vitro fertilization technique. Monterey CA.{{cite book}}: CS1 maint: location missing publisher (link)
  14. ^ a b Ginsburg, Elizabeth (June 4, 2018). "Procedure for intrauterine insemination (IUI) using processed sperm". Uptodate.com.
  15. ^ O'Brien, P; Vandekerckhove, P (1998-10-26), The Cochrane Collaboration (ed.), "Intra-uterine versus cervical insemination of donor sperm for subfertility", Cochrane Database of Systematic Reviews (2), Chichester, UK: John Wiley & Sons, Ltd: CD000317.pub2, doi:10.1002/14651858.cd000317, PMID 10796709, retrieved 2021-11-21
  16. ^ European Sperm Bank USA
  17. ^ Laurie Barclay. "Immobilization May Improve Pregnancy Rate After Intrauterine Insemination". Medscape Medical News. Retrieved October 31, 2009.
  18. ^ Marshburn PB, Alanis M, Matthews ML, et al. (September 2009). "A short period of ejaculatory abstinence before intrauterine insemination is associated with higher pregnancy rates". Fertil. Steril. 93 (1): 286–8. doi:10.1016/j.fertnstert.2009.07.972. PMID 19732887.
  19. ^ a b Merviel P, Heraud MH, Grenier N, Lourdel E, Sanguinet P, Copin H (November 2008). "Predictive factors for pregnancy after intrauterine insemination (IUI): An analysis of 1038 cycles and a review of the literature". Fertil. Steril. 93 (1): 79–88. doi:10.1016/j.fertnstert.2008.09.058. PMID 18996517.
  20. ^ "Lesbian Fertility Options - Donor Sperm IUI - Reciprocal IVF - LGBT". Southern California Fertility. Retrieved 2021-12-07.
  21. ^ "LGBTQ Fertility Services". Obstetrics & Gynecology. 2018-12-18. Retrieved 2021-12-07.
  22. ^ Johal, Jasmyn K.; Gardner, Rebecca M.; Vaughn, Sara J.; Jaswa, Eleni G.; Hedlin, Haley; Aghajanova, Lusine (2021-09-01). "Pregnancy success rates for lesbian women undergoing intrauterine insemination". F&S Reports. 2 (3): 275–281. doi:10.1016/j.xfre.2021.04.007. ISSN 2666-3341. PMC 8441558. PMID 34553151.
  23. ^ a b c Yao, Hong; Yang, Jieyi; Lo, Iris Po Yee (2023-06-01). "Lesbian couples' childbearing experiences using assisted reproductive technology: A netnography study". Midwifery. 121: 103656. doi:10.1016/j.midw.2023.103656. ISSN 0266-6138. PMID 37019000. S2CID 257741047.
  24. ^ Bellver J, Labarta E, Bosch E, Melo MA, Vidal C, Remohí J, Pellicer A, et al. (June 2009). "GnRH agonist administration at the time of implantation does not improve pregnancy outcome in intrauterine insemination cycles: a randomized controlled trial". Fertil. Steril. 94 (3): 1065–71. doi:10.1016/j.fertnstert.2009.04.044. PMID 19501354.
  25. ^ Blasco V, Prados N, Carranza F, González-Ravina C, Pellicer A, Fernández-Sánchez M, et al. (June 2014). "Influence of follicle rupture and uterine contractions on intrauterine insemination outcome: a new predictive model". Fertil. Steril. 102 (4): 1034–1040. doi:10.1016/j.fertnstert.2014.06.031. PMID 25044083.
  26. ^ a b "What Is Intrauterine Insemination (IUI)?". Planned Parenthood. Retrieved December 3, 2023.
  27. ^ "Donor Insemination". American Pregnancy Association. 25 April 2012. Retrieved December 3, 2023.
  28. ^ Richburg, Caroline E.; Jackson Levin, Nina; Moravek, Molly B. (March 2022). "Laboring to Conceive: Reducing Barriers to Fertility Care for Same-Sex Mothers Pursuing Parenthood". Women. 2: 44–55. doi:10.3390/women2010005. PMC 10702875.
  29. ^ a b Harris, I.; Missmer, S.; Hornstein, M. (2010). "Poor success of gonadotropin-induced controlled ovarian hyperstimulation and intrauterine insemination for older women". Fertility and Sterility. 94 (1): 144–148. doi:10.1016/j.fertnstert.2009.02.040. PMID 19394605.
  30. ^ Bagis T, Haydardedeoglu B, Kilicdag EB, Cok T, Simsek E, Parlakgumus AH (May 2010). "Single versus double intrauterine insemination in multi-follicular ovarian hyperstimulation cycles: a randomized trial". Hum Reprod. 25 (7): 1684–90. doi:10.1093/humrep/deq112. PMID 20457669.
  31. ^ Ayeleke, RO; Asseler, JD; Cohlen, BJ; Veltman-Verhulst, SM (3 March 2020). "Intra-uterine insemination for unexplained subfertility". The Cochrane Database of Systematic Reviews. 2020 (3): CD001838. doi:10.1002/14651858.CD001838.pub6. PMC 7059962. PMID 32124980.
  32. ^ Boomsma, CM; Cohlen, BJ; Farquhar, C (15 October 2019). "Semen preparation techniques for intrauterine insemination". The Cochrane Database of Systematic Reviews. 10 (11): CD004507. doi:10.1002/14651858.CD004507.pub4. PMC 6792139. PMID 31612995.
  33. ^ Leonidas Mamas, M.D. (March 2006). "Comparison of fallopian tube sperm perfusion and intrauterine tuboperitoneal insemination:a prospective randomized study". Fertility and Sterility. 85 (3): 735–740. doi:10.1016/j.fertnstert.2005.08.025. PMID 16500346.
  34. ^ G S Shekhawat, MD (2012). "Intrauterine insemination versus Fallopian tube sperm perfusion in non-tubal infertility". Internet Medical Journal. 68 (3): 226–30. doi:10.1016/j.mjafi.2012.02.013. PMC 3862360. PMID 24532873. Archived from the original on 2014-05-02. Retrieved 2012-01-24.
  35. ^ Hurd WW, Randolph JF, Ansbacher R, Menge AC, Ohl DA, Brown AN (February 1993). "Comparison of intracervical, intrauterine, and intratubal techniques for donor insemination". Fertil. Steril. 59 (2): 339–42. doi:10.1016/S0015-0282(16)55671-4. PMID 8425628.
  36. ^ England, Fertility Centers of New (2011-03-03). "Andrology: Sperm Volume & Concentration". Fertility Centers of New England. Retrieved 2021-01-04.
  37. ^ a b Utrecht CS News Archived 2018-10-01 at the Wayback Machine Subject: Infertility FAQ (part 4/4)
  38. ^ Allahbadia, Gautam N. (2017-12-01). "Intrauterine Insemination: Fundamentals Revisited". The Journal of Obstetrics and Gynecology of India. 67 (6): 385–392. doi:10.1007/s13224-017-1060-x. ISSN 0975-6434. PMC 5676579. PMID 29162950.
  39. ^ Intrauterine insemination. Information notes from the fertility clinic at Aarhus University Hospital, Skejby. By PhD Ulrik Kesmodel et al.
  40. ^ IVF.com
  41. ^ Cordary, D (December 2017). "Immobilization versus immediate mobilization after intrauterine insemination: A systematic review and meta-analysis". Journal of Gynecology Obstetrics and Human Reproduction. 46 (10): 747–751. doi:10.1016/j.jogoh.2017.09.005. PMID 28964965 – via Elsevier Science Direct.
  42. ^ Mol, Ben Willem J.; Veen, Fulco van der; Janssen, Catharina A. H.; Mochtar, Monique H.; Gerards, Mariette H.; Dessel, Thierry J. H. M. Van; Cox, Tessa; Maas, Pettie; Flierman, Paul A. (2009-10-30). "Immobilisation versus immediate mobilisation after intrauterine insemination: randomised controlled trial". BMJ. 339: b4080. doi:10.1136/bmj.b4080. ISSN 0959-8138. PMC 2771078. PMID 19875843.
  43. ^ "Fertility treatments 'no benefit'". BBC News. 7 August 2008.
  44. ^ Bhattacharya S, Harrild K, Mollison J, et al. (2008). "Clomifene citrate or unstimulated intrauterine insemination compared with expectant management for unexplained infertility: pragmatic randomised controlled trial". BMJ. 337: a716. doi:10.1136/bmj.a716. PMC 2505091. PMID 18687718.
  45. ^ Essig, Maria G. (2007-02-20). Van Houten, Susan; Landauer, Tracy (eds.). "Semen Analysis". Healthwise. Reviewed by Martin Gabica and Avery L. Seifert. WebMD. Retrieved 2007-08-05.
  46. ^ a b Inhorn, Marcia C. (2003). "Global infertility and the globalization of new reproductive technologies: Illustrations from Egypt". Social Science and Medicine. 56 (9): 1837–51. doi:10.1016/s0277-9536(02)00208-3. PMID 12650724. Retrieved 29 November 2022 – via ScienceDirect.
  47. ^ "Intrauterine insemination (IUI) - Mayo Clinic". www.mayoclinic.org. Retrieved 2023-11-29.
  48. ^ Thomas, S.; Chung, K.; Paulson, R.; Bendikson, K. (March 2018). "Barriers to conception: LGBT individuals have worse fertility health literacy than their heterosexual female peers". Fertility and Sterility. 109 (3): e53–e54. doi:10.1016/j.fertnstert.2018.02.102. ISSN 0015-0282.
  49. ^ a b c d e f g h i j k l m n o p q r s t u v w Rainbow Europe Country Index[permanent dead link]
  50. ^ a b c d e f Luetkemeyer, Lisa (June 1, 2015). "Paternity Law: Sperm Donors, Surrogate Mothers and Child Custody". Missouri Medicine. 112 (3): 162–165. PMC 6170122. PMID 26168582.
  51. ^ a b c Pedersen, Jamie D. "The New Uniform Parentage Act of 2017". www.americanbar.org. Retrieved March 23, 2023.
  52. ^ a b "Parentage Act - Uniform Law Commission". www.uniformlaws.org. Retrieved 2023-03-24.
  53. ^ a b c d e f g h Gill, Lauren (April 2013). "Who's Your Daddy? Defifining Paternity Rights in the Context of Free, Private Sperm Donation". William and Mary Law Review. 54 (5): 1736.
  54. ^ U.S. Conference of Catholic Bishops (USCCB) (2020). «Reproductive Technology (Evaluation & Treatment of Infertility): Guidelines for Catholic Couples». www.usccb.org.
  55. ^ "Pigs | The Vegetarian Society". Vegetarian Society. Retrieved 2019-06-03.
  56. ^ "Inseminating sows". Qld Government Department of Agriculture and Fisheries.[permanent dead link]
  57. ^ "Collecting semen from boars". Qld Government Department of Agriculture and Fisheries.[permanent dead link]
  58. ^ "Experiment in Sheep Breeding". Daily Telegraph. London. 16 May 1936. p. 3. Retrieved 2 June 2023.
  59. ^ Chet, Ilan (2009). "John O. Almquist". Wolf Prize in Agriculture. World Scientific. pp. 121–134. ISBN 978-981-283-585-7.
  60. ^ "Equine Artificial Insemination". www.equine-reproduction.com. Retrieved 2018-03-01.
  61. ^ The Jockey Club has never allowed artificial insemination. Archived September 20, 2008, at the Wayback Machine
  62. ^ Lierz M, Reinschmidt M, Müller H, Wink M, Neumann D (2013). "A novel method for semen collection and artificial insemination in large parrots (Psittaciformes)". Sci Rep. 3: 2066. Bibcode:2013NatSR...3E2066L. doi:10.1038/srep02066. PMC 3691562. PMID 23797622.
  63. ^ Robeck, T.R.; Steinman, K.J.; Gearhart, S.; Reidarson, T.R.; McBain, J.F.; Monfort, S.L. (1 August 2004). "Reproductive Physiology and Development of Artificial Insemination Technology in Killer Whales (Orcinus orca)1". Biology of Reproduction. 71 (2): 650–660. doi:10.1095/biolreprod.104.027961. PMID 15115725.
  64. ^ Hargrove, John (22 March 2016). "I trained killer whales at SeaWorld for 12 years. Here's why I quit". Vox. Retrieved 25 February 2019.
  65. ^ Rosenberg, Gabriel (1 October 2017). "How Meat Changed Sex: The Law of Interspecies Intimacy after Industrial Reproduction". GLQ: A Journal of Lesbian and Gay Studies. 23 (4). Durham, NC: Duke University Press: 473–507. doi:10.1215/10642684-4157487. ISSN 1527-9375. S2CID 148931942. Retrieved 15 January 2021.
  66. ^ Fischer, Bob (2019). The Routledge handbook of animal ethics. Routledge handbooks in applied ethics. New York, NY: Routledge. ISBN 978-1-13-809506-9. OCLC 1111771459.
  67. ^ "Is Your Food a Product of Rape?". PETA. September 2016.
  68. ^ "Why Vegans Are Going On TV to Call Farmers 'Rapists'". VICE. 6 February 2018.
  69. ^ "Is your food a product of rape?". PETA.org. PETA. September 2016. Retrieved 15 January 2021. Cows and other factory-farmed female animals endure being raped repeatedly, and their babies are torn away from them before they're all killed.
  70. ^ "Sex and Violence in the Meat Industry". MercyforAnimals.org. Mercy for Animals. 3 November 2010. Archived from the original on 31 July 2021. Retrieved 15 January 2021. In an eye-opening article in The Huffington Post, Bruce Friedrich gives readers one more reason to boycott meat, dairy and eggs: institutionalized bestiality. Aside from horrifying personal accounts from factory farmers and slaughterhouse workers bragging about sexually abusing animals and undercover video footage exposing animals being raped and sexually assaulted, Friedrich explains how routine – and legal – acts of bestiality are perpetrated every day on modern farms.
  71. ^ Jarvenpaa, Mikko (23 December 2019). "Mercy For Animals: Interview with President Leah Garcés". Sentientmedia.org. Sentient Media. Retrieved 15 January 2021. Mercy For Animals pursues change for the better by reducing the suffering of the 80 billion farmed animals raped and killed every year, Garcés says.
  72. ^ a b Rosenberg, Gabriel N.; Dutkiewicz, Jan (11 December 2020). "The Meat Industry's Bestiality Problem". The New Republic. TNR. Retrieved 15 January 2021.
  73. ^ "La loi de bioéthique qui encadre l'AMP (ou PMA) - Assistance médicale à la procréation (AMP)". Assistance médicale à la procréation (in French). Retrieved 2023-11-12.

Further reading

  • Hammond, John, et al., The Artificial Insemination of Cattle (Cambridge, Heffer, 1947, 61pp)