Vaccine controversies

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James Gillray, The Cow-Pock—or—the Wonderful Effects of the New Inoculation! (1802)

Medical and scientific evidence surrounding vaccination demonstrates that the benefits of preventing suffering and death from infectious diseases far outweigh rare adverse effects of immunization.^[1] Despite this, vaccination controversies began almost 80 years before the terms vaccine and vaccination were introduced and continue to this day. Opponents have claimed that vaccines do not work, that they are or may be dangerous, that individuals should rely on personal hygiene instead, or that mandatory vaccinations violate individual rights or religious principles.^[2] These arguments have reduced vaccination rates in certain communities, resulting in epidemics of preventable, and sometimes fatal, childhood illnesses.^[3]

The success of immunization programs depends on public confidence in their safety. Concerns about immunization safety often follow a pattern: some investigators suggest that a medical condition is an adverse effect of vaccination; a premature announcement is made of the alleged adverse effect; the initial study is not reproduced by other groups; and finally, it takes several years to regain public confidence in the vaccine.^[1]

Public reaction to vaccine controversies has contributed to a significant increase in preventable diseases, including measles.^[4] Controversy over the safety and efficacy of vaccination affects and is affected by other medical controversies, such as the water fluoridation controversy. This means that genuine concerns about safety of vaccines may become swamped by general opposition to mainstream medicine.

History

Variolation

Early attempts to prevent smallpox involved deliberate inoculation of the disease in hopes that a mild result would confer immunity. Originally called inoculation, this technique was later called variolation to avoid confusion with cowpox inoculation (vaccination) when that was introduced by Edward Jenner. Although variolation had a long history in China and India, it was first used in North America and England in 1721. Reverend Cotton Mather introduced variolation to Boston, Massachusetts, during the 1721 smallpox epidemic.^[5] Many had religious objections, but Mather convinced Dr. Zabdiel Boylston to try it. Boylston first experimented on his 6-year-old son, his slave, and his slave's son; each subject contracted the disease and was sick for several days, until the sickness vanished and they were "no longer gravely ill".^[5] Boylston went on to variolate thousands of Massachusetts residents, and many places were named for him in gratitude as a result. Lady Mary Wortley Montagu introduced variolation to England. She had seen it used in Turkey and, in 1718, had her son successfully variolated in Constantinople under the supervision of Dr. Charles Maitland.
When she returned to England in 1721, she had her daughter variolated by Maitland. This aroused considerable interest, and Sir Hans Sloane organized the variolation of some inmates in Newgate Prison. These were successful, and after a further short trial in 1722, two daughters of Caroline of Ansbach Princess of Wales were variolated without mishap. With this royal approval, the procedure became common when smallpox epidemics threatened.^[6]

Religious arguments against inoculation were soon advanced. For example, in a 1772 sermon entitled "The Dangerous and Sinful Practice of Inoculation", the English theologian Reverend Edmund Massey argued that diseases are sent by God to punish sin and that any attempt to prevent smallpox via inoculation is a "diabolical operation".^[7] It was customary at the time for popular preachers to publish sermons, which reached a wide audience. This was the case with Massey, whose sermon reached North America, where there was early religious opposition, particularly by John Williams. A greater source of opposition there was Dr. William Douglass, a medical graduate of Edinburgh University and a Fellow of the Royal Society, who had settled in Boston.^[6]:114–22

Smallpox vaccination

After Edward Jenner introduced the smallpox vaccine in 1798, variolation declined and was banned in some countries.^[8][9]

Edward Jenner

As with variolation, there was some religious opposition to vaccination, although this was balanced to some extent by support from clergymen who not only preached in its favour but also performed vaccination themselves. These included Reverend Robert Ferryman, a friend of Jenner's, and Rowland Hill.^[6]:221 There was also opposition from some variolators who saw the loss of a lucrative monopoly. William Rowley published illustrations of deformities allegedly produced by vaccination, lampooned in James Gillray's famous caricature depicted on this page, and Benjamin Moseley likened cowpox to syphilis, starting a controversy that would last into the 20th century.^[6]:203–5

There was legitimate concern from supporters of vaccination about its safety and efficacy, but this was overshadowed by general condemnation, particularly when legislation started to introduce compulsory vaccination. The reason for this was that vaccination was introduced before laboratory methods were developed to control its production and account for its failures.^[10] Vaccine was maintained initially through arm-to-arm transfer and later through production on the skin of animals, and bacteriological sterility was impossible. Further, identification methods for potential pathogens were not available until the late 19th to early 20th century. Diseases later shown to be caused by contaminated vaccine included erysipelas, tuberculosis, tetanus, and syphilis. This last, though rare—estimated at 750 cases in 100 million vaccinations^[11]—attracted particular attention. Much later, Dr. Charles Creighton, a leading medical opponent of vaccination, claimed that the vaccine itself was a cause of syphilis and devoted a whole book to the subject.^[12] As cases of smallpox started to occur in those who had been vaccinated earlier, supporters of vaccination pointed out that these were usually very mild and occurred years after the vaccination. In turn, opponents of vaccination pointed out that this contradicted Jenner's belief that vaccination conferred complete protection.^[10]:17–21 The views of opponents of vaccination that it was both dangerous and ineffective led to the development of determined anti-vaccination movements in England when legislation was introduced to make vaccination compulsory.^[13]

Opposition to legislation in England

Because of its greater risks, variolation was banned in England by the 1840 Vaccination Act, which also introduced free voluntary vaccination for infants. Thereafter Parliament passed successive acts that imposed and enforced compulsory vaccination.^[14] The 1853 act introduced compulsory vaccination, with fines for non-compliance and imprisonment for non-payment. The 1867 act extended the age requirement to 14 years and introduced repeated fines for repeated refusal for the same child. Initially, vaccination regulations were organised by the local Poor Law Guardians, and in towns where there was strong opposition to vaccination, sympathetic Guardians were elected who did not pursue prosecutions. This was changed by the 1871 act, which required Guardians to act. This significantly changed the relationship between the government and the public, and organized protests increased.^[14] In Keighley, Yorkshire, in 1876 the Guardians were arrested and briefly imprisoned in York Castle, prompting large demonstrations in support of the "Keighley Seven".^[13]:108–9 The protest movements crossed social boundaries. The financial burden of fines fell hardest on the working class, who would provide the largest numbers at public demonstrations.^[15] Societies and publications were organized by the middle classes, and support came from celebrities such as George Bernard Shaw and Alfred Russel Wallace, doctors such as Charles Creighton and Edgar Crookshank, and parliamentarians such as Jacob Bright and James Allanson Picton.^[14] By 1885, with over 3,000 prosecutions pending in Leicester, a mass rally there was attended by over 20,000 protesters.^[16]
Under increasing pressure, the government appointed a Royal Commission on Vaccination in 1889, which issued six reports between 1892 and 1896, with a detailed summary in 1898.^[17] Its recommendations were incorporated into the 1898 Vaccination Act, which still required compulsory vaccination but allowed exemption on the grounds of conscientious objection on presentation of a certificate signed by two magistrates.^[2][14] These were not easy to obtain in towns where magistrates supported compulsory vaccination, and after continued protests, a further act in 1907 allowed exemption on a simple signed declaration.^[16] Although this solved the immediate problem, the compulsory vaccination acts remained legally enforceable, and determined opponents lobbied for their repeal. This was done as a matter of routine when the National Health Service was introduced in 1948, with "almost negligible" opposition from supporters of compulsory vaccination.^[18]

Vaccination in Wales was covered by English legislation, but the Scottish legal system was separate. Vaccination was not made compulsory there until 1863, and conscientious objection was allowed after vigorous protest only in 1907.^[10]:10–11

In the late 19th century, the city of Leicester in the UK received much attention because of the way smallpox was managed there. There was particularly strong opposition to compulsory vaccination, and medical authorities had to work within this framework. They developed a system that did not use vaccination but was based on strict isolation of cases and contacts and the provision of isolation hospitals. This proved successful but required acceptance of compulsory isolation rather than vaccination. C. Killick Millard, initially a supporter of compulsory vaccination, was appointed Medical Officer of Health in 1901. He moderated his views on compulsion but encouraged contacts and his staff to accept vaccination. This approach, developed initially due to overwhelming opposition to government policy, became known as the Leicester Method.^[18][19] In time it became generally accepted as the most appropriate way to deal with smallpox outbreaks and was listed as one of the "important events in the history of smallpox control" by those most involved in the World Health Organization's successful Smallpox Eradication Campaign. The final stages of the campaign, generally referred to as "surveillance containment", owed much to the Leicester method.^[20][21]

Opposition to vaccination in the United States and Brazil

In the US, President Thomas Jefferson took a close interest in vaccination, alongside Dr. Waterhouse, chief physician at Boston. Jefferson encouraged the development of ways to transport vaccine material through the Southern states, which included measures to avoid damage by heat, a leading cause of ineffective batches. Smallpox outbreaks were contained by the latter half of the 19th century, a development widely attributed to the vaccination of a large portion of the population. Vaccination rates fell after this decline in smallpox cases, and the disease again became epidemic in the late 19th century (see Smallpox).^[22]

After an 1879 visit to New York by prominent British anti-vaccinationist William Tebb, the Anti-Vaccination Society of America was founded. The New England Anti-Compulsory Vaccination League formed in 1882, and the Anti-Vaccination League of New York City in 1885. Tactics in the US largely followed those used in England.^[23] Vaccination in the US was regulated by individual states, in which there followed the progression of compulsion, opposition, and repeal similar to that in England.^[24] Although generally organized on a state-by-state basis, the vaccination controversy reached the US Supreme Court in 1905. There, in the case of Jacobson v. Massachusetts, the court issued a landmark ruling that the public good overrode personal freedom.

John Pitcairn, the wealthy founder of the Pittsburgh Plate Glass Company (now PPG Industries), emerged as a major financier and leader of the American anti-vaccination movement. On March 5, 1907, in Harrisburg, Pennsylvania, he delivered an address to the Committee on Public Health and Sanitation of the Pennsylvania General Assembly criticizing vaccination.^[25] He later sponsored the National Anti-Vaccination Conference, which, held in Philadelphia in October 1908, led to the creation of The Anti-Vaccination League of America. When the league organized later that month, members chose Pitcairn as their first president.^[26]

On December 1, 1911, Pitcairn was appointed by Pennsylvania Governor John K. Tener to the Pennsylvania State Vaccination Commission, and subsequently authored a detailed report strongly opposing the commission's conclusions.^[26] He remained a staunch opponent of vaccination until his death in 1916.

1904 cartoon opposing the mandatory vaccination law in Brazil. "The Congress", depicted as a Roman Caesar, threatens "the People", in rags, with a sharp object and shackles.

In November 1904, in response to years of inadequate sanitation and disease, followed by a poorly explained public health campaign led by the renowned Brazilian public health official Oswaldo Cruz, citizens and military cadets in Rio de Janeiro arose in a Revolta da Vacina, or Vaccine Revolt. Riots broke out on the day a vaccination law took effect; vaccination symbolized the most feared and most tangible aspect of a public health plan that included other features, such as urban renewal, that many had opposed for years.^[27]

In the early 19th century, the anti-vaccination movement drew members from a wide range of society; more recently, it has been reduced to a predominantly middle-class phenomenon.^[28]

Later vaccines and antitoxins

Opposition to smallpox vaccination continued into the 20th century and was joined by controversy over new vaccines and the introduction of antitoxin treatment for diphtheria. Injection of horse serum into humans as used in antitoxin can cause hypersensitivity, commonly referred to as serum sickness. Moreover, the continued production of smallpox vaccine in animals and the production of antitoxins in horses prompted anti-vivisectionists to oppose vaccination.

Diphtheria antitoxin was serum from horses that had been immunized against diphtheria, and was used to treat human cases by providing passive immunity. In 1901, antitoxin from a horse named Jim was contaminated with tetanus and killed 13 children in St Louis, Missouri. This incident, together with nine deaths from tetanus from contaminated smallpox vaccine in Camden, New Jersey, led directly and quickly to the passing of the Biologics Control Act in 1902.^[29]

Robert Koch developed tuberculin in 1890. Inoculated into individuals who have had tuberculosis, it produces a hypersensitivity reaction, and is still used to detect those who have been infected. However, Koch used tuberculin as a vaccine. This caused serious reactions and deaths in individuals whose latent tuberculosis was reactivated by the tuberculin.^[30] This was a major setback for supporters of new vaccines.^[10]:30–31 Such incidents and others ensured that any untoward results concerning vaccination and related procedures received continued publicity, which grew as the number of new procedures increased.

In 1955, in a tragedy known as the Cutter incident, Cutter Laboratories produced 120,000 doses of the Salk polio vaccine that inadvertently contained some live polio virus along with inactivated virus. This vaccine caused 40,000 cases of polio, 53 cases of paralysis, and five deaths. The disease spread through the recipients' families, creating a polio epidemic that led to a further 113 cases of paralytic polio and another five deaths. It was one of the worst pharmaceutical disasters in US history.^[31]

Later 20th-century events include the 1982 broadcast of DPT: Vaccine Roulette, which sparked debate over the DPT vaccine,^[32] and the 1998 publication of a fraudulent academic article,^[33] which sparked the MMR vaccine controversy.

Arguments against vaccines in the 21st century are often similar to those of 19th-century anti-vaccinationists.^[2]

Effectiveness

Rubella fell sharply when universal immunization was introduced. CDC

Scientific evidence for the effectiveness of large-scale vaccination campaigns is well established. Vaccination campaigns helped eradicate smallpox, which once killed as many as one in seven children in Europe,^[34] and have nearly eradicated polio.^[35] As a more modest example, infections caused by Haemophilus influenzae, a major cause of bacterial meningitis and other serious diseases in children, have decreased by over 99% in the US since the introduction of a vaccine in 1988.^[36] Full vaccination, from birth to adolescence, of all US children born in a given year saves an estimated 33,000 lives and prevents an estimated 14 million infections.^[37]

Some opponents of vaccination argue that these reductions in infectious disease are a result of improved sanitation and hygiene (rather than vaccination), or that these diseases were already in decline before the introduction of specific vaccines. These claims are not supported by scientific data; the incidence of vaccine-preventable diseases tended to fluctuate over time until the introduction of specific vaccines, at which point the incidence dropped to near zero. A Centers for Disease Control website aimed at countering common misconceptions about vaccines argued, "Are we expected to believe that better sanitation caused incidence of each disease to drop, just at the time a vaccine for that disease was introduced?"^[38]

Other critics argue that the immunity granted by vaccines is only temporary and requires boosters, whereas those who survive the disease become permanently immune.^[2] As discussed below, the philosophies of some alternative medicine practitioners are incompatible with the idea that vaccines are effective.^[39]

Population health

Incomplete vaccine coverage increases the risk of disease for the entire population, including those who have been vaccinated, because it reduces herd immunity. For example, the measles vaccine targets children between the ages of 9 and 12 months, and the short window between the disappearance of maternal antibody (before which the vaccine often fails to seroconvert) and natural infection means that vaccinated children are frequently still vulnerable. Herd immunity lessens this vulnerability if all the children are vaccinated. Increasing herd immunity during an outbreak or threatened outbreak is perhaps the most widely accepted justification for mass vaccination. Mass vaccination also helps to increase coverage rapidly, thus obtaining herd immunity, when a new vaccine is introduced.^[40]

Cost-effectiveness

Commonly used vaccines are a cost-effective and preventive way of promoting health, compared to the treatment of acute or chronic disease. In the US during the year 2001, routine childhood immunizations against seven diseases were estimated to save over $40 billion per birth-year cohort in overall social costs, including $10 billion in direct health costs, and the societal benefit-cost ratio for these vaccinations was estimated to be 16.5.^[41]

Events following reductions in vaccination

In several countries, reductions in the use of some vaccines were followed by increases in the diseases' morbidity and mortality.^[42][43] According to the Centers for Disease Control and Prevention, continued high levels of vaccine coverage are necessary to prevent resurgence of diseases that have been nearly eliminated.^[44]

Stockholm, smallpox (1873–74)

An anti-vaccination campaign motivated by religious objections, concerns about effectiveness, and concerns about individual rights led to the vaccination rate in Stockholm dropping to just over 40%, compared to about 90% elsewhere in Sweden. A major smallpox epidemic then started in 1873. It led to a rise in vaccine uptake and an end of the epidemic.^[45]

In a postwar poster the Ministry of Health urged British residents to immunize children against diphtheria.

UK, pertussis (1970s–80s)

In a 1974 report ascribing 36 reactions to whooping cough (pertussis) vaccine, a prominent public-health academic claimed that the vaccine was only marginally effective and questioned whether its benefits outweigh its risks, and extended television and press coverage caused a scare. Vaccine uptake in the UK decreased from 81% to 31%, and pertussis epidemics followed, leading to the deaths of some children. Mainstream medical opinion continued to support the effectiveness and safety of the vaccine; public confidence was restored after the publication of a national reassessment of vaccine efficacy. Vaccine uptake then increased to levels above 90%, and disease incidence declined dramatically.^[42]

Sweden, pertussis (1979–96)

In the vaccination moratorium period that occurred when Sweden suspended vaccination against whooping cough (pertussis) from 1979 to 1996, 60% of the country's children contracted the potentially fatal disease before the age of 10; close medical monitoring kept the death rate from whooping cough at about one per year.^[43] Pertussis remains a major health problem in developing countries, where mass vaccination is not practiced; the World Health Organization estimates it caused 294,000 deaths in 2002.^[46]

Netherlands, measles (1999–2000)

An outbreak at a religious community and school in the Netherlands illustrates the effect of measles in an unvaccinated population.^[47] The population in the several provinces affected had a high level of immunization, with the exception of one of the religious denominations, which traditionally does not accept vaccination. The three measles-related deaths and 68 hospitalizations that occurred among 2,961 cases in the Netherlands demonstrate that measles can be severe and may result in death, even in industrialized countries.

UK and Ireland, measles (2000)

As a result of the MMR vaccine controversy, vaccination compliance dropped sharply in the United Kingdom after 1996.^[48] From late 1999 until the summer of 2000, there was a measles outbreak in North Dublin, Ireland. At the time, the national immunization level had fallen below 80%, and in part of North Dublin the level was around 60%. There were more than 100 hospital admissions from over 300 cases. Three children died and several more were gravely ill, some requiring mechanical ventilation to recover.^[49]

Nigeria, polio, measles, diphtheria (2001–)

In the early first decade of the 21st century, conservative religious leaders in northern Nigeria, suspicious of Western medicine, advised their followers not to have their children vaccinated with oral polio vaccine. The boycott was endorsed by the governor of Kano State, and immunization was suspended for several months. Subsequently, polio reappeared in a dozen formerly polio-free neighbors of Nigeria, and genetic tests showed the virus was the same one that originated in northern Nigeria. Nigeria had become a net exporter of the polio virus to its African neighbors. People in the northern states were also reported to be wary of other vaccinations, and Nigeria reported over 20,000 measles cases and nearly 600 deaths from measles from January through March 2005.^[50] In 2006, Nigeria accounted for over half of all new polio cases worldwide.^[51] Outbreaks continued thereafter; for example, at least 200 children died in a late-2007 measles outbreak in Borno State.^[52]

Indiana, United States, measles (2005)

A 2005 measles outbreak in the US state of Indiana was attributed to parents who had refused to have their children vaccinated.^[53] Most cases of pediatric tetanus in the US occur in children whose parents objected to their vaccination.^[54]

Multiple states, United States, measles (2013–)

In 2000, measles was declared eliminated from the United States because internal transmission had been interrupted for one year; remaining reported cases were due to importation.^[55]

Centers for Disease Control and Prevention (CDC) reported that the three biggest outbreaks of measles in 2013 were attributed to clusters of people who were unvaccinated due to their philosophical or religious beliefs. As of August 2013, three pockets of outbreak—New York City, North Carolina, and Texas—contributed to 64% of the 159 cases of measles reported in 16 states.^[56][57]

The number of cases in 2014 quadrupled to 644,^[58] including transmission by unvaccinated visitors to Disneyland in California.^[59] Some 97% of cases in the first half of the year were confirmed to be due directly or indirectly to importation (the remainder were unknown), and 49% from the Phillippines. 165 of the 288 victims (57%) during that time were confirmed to be unvaccinated by choice; 30 (10%) were confirmed to have been vaccinated.^[60]

Swansea, measles (2013)

In 2013, an outbreak of measles occurred in the Welsh city of Swansea. One death was reported.^[61] Some estimates indicate that while in 1995, MMR uptake for two-year-olds was at 94% in Wales, it fell to as low as 67.5% in Swansea in 2003, meaning the region had a "vulnerable" age group.^[62] This has been linked to the MMR vaccine controversy, which caused a significant number of parents to fear allowing their children to receive the MMR vaccine.^[61]

Safety

Few deny the vast improvements vaccination has made to public health; a more common concern is their safety.^[63] As with any medical treatment, there is a potential for vaccines to cause serious complications, such as severe allergic reactions,^[64] but unlike most other medical interventions, vaccines are given to healthy people and so a higher standard of safety is expected.^[65] While serious complications from vaccinations are possible, they are extremely rare and much less common than similar risks from the diseases they prevent.^[38] As the success of immunization programs increases and the incidence of disease decreases, public attention shifts away from the risks of disease to the risk of vaccination,^[1] and it becomes challenging for health authorities to preserve public support for vaccination programs.^[66]

Concerns about immunization safety often follow a pattern. First, some investigators suggest that a medical condition of increasing prevalence or unknown cause is an adverse effect of vaccination. The initial study and subsequent studies by the same group have inadequate methodology—typically a poorly controlled or uncontrolled case series. A premature announcement is made about the alleged adverse effect, resonating with individuals suffering the condition, and underestimating the potential harm to those whom the vaccine could protect. The initial study is not reproduced by other groups. Finally, it takes several years to regain public confidence in the vaccine.^[1] Adverse effects ascribed to vaccines typically have an unknown origin, an increasing incidence, some biological plausibility, occurrences close to the time of vaccination, and dreaded outcomes.^[67] In almost all cases, the public health effect is limited by cultural boundaries: English speakers worry about one vaccine causing autism, while French speakers worry about another vaccine causing multiple sclerosis, and Nigerians worry that a third vaccine causes infertility.^[68]

Autism controversies

Despite significant media attention linking the causes of autism to some vaccines, there is no scientific evidence to support this hypothesis.^[1][69][70]

Thiomersal

Thiomersal is a preservative that some American parents believed caused autism. In 1999, the Centers for Disease Control (CDC) and the American Academy of Pediatrics (AAP) asked vaccine makers to remove the organomercury compound thiomersal (spelled "thimerosal" in the US) from vaccines as quickly as possible, and thiomersal has been phased out of US and European vaccines, except for some preparations of influenza vaccine.^[71] The CDC and the AAP followed the precautionary principle, which assumes that there is no harm in exercising caution even if it later turns out to be unwarranted, but their 1999 action sparked confusion and controversy that has diverted attention and resources away from efforts to determine the causes of autism.^[71] Since 2000, the thiomersal in child vaccines has been alleged to contribute to autism, and thousands of parents in the United States have pursued legal compensation from a federal fund.^[72] A 2004 Institute of Medicine (IOM) committee favored rejecting any causal relationship between thiomersal-containing vaccines and autism.^[73] Autism incidence rates increased steadily even after thiomersal was removed from childhood vaccines.^[74] Currently there is no accepted scientific evidence that exposure to thiomersal is a factor in causing autism.^[75]

MMR vaccine

In the UK, the MMR vaccine was the subject of controversy after the publication in The Lancet of a 1998 paper by Andrew Wakefield and others reporting a study of 12 children mostly with autism spectrum disorders with onset soon after administration of the vaccine.^[76] At a 1998 press conference, Wakefield suggested that giving children the vaccines in three separate doses would be safer than a single vaccination. This suggestion was not supported by the paper, and several subsequent peer-reviewed studies have failed to show any association between the vaccine and autism.^[77] It later emerged that Wakefield had received funding from litigants against vaccine manufacturers and that he had not informed colleagues or medical authorities of his conflict of interest;^[78] had this been known, publication in The Lancet would not have taken place in the way that it did.^[79] Wakefield has been heavily criticized on scientific grounds and for triggering a decline in vaccination rates^[80] (vaccination rates in the UK dropped to 80% in the years following the study),^[81] as well as on ethical grounds for the way the research was conducted.^[82] In 2004, the MMR-and-autism interpretation of the paper was formally retracted by 10 of Wakefield's 12 coauthors,^[83] and in 2010 The Lancet '​s editors fully retracted the paper.^[84]
The CDC,^[85] the IOM of the National Academy of Sciences,^[73] and the UK National Health Service^[86] have all concluded that there is no evidence of a link between the MMR vaccine and autism. A systematic review by the Cochrane Library concluded that there is no credible link between the MMR vaccine and autism, that MMR has prevented diseases that still carry a heavy burden of death and complications, that the lack of confidence in MMR has damaged public health, and that the design and reporting of safety outcomes in MMR vaccine studies are largely inadequate.^[87]

In 2009, The Sunday Times reported that Wakefield had manipulated patient data and misreported results in his 1998 paper, creating the appearance of a link with autism.^[88] A 2011 article in the British Medical Journal described how the data in the study had been falsified by Wakefield so that it would arrive at a predetermined conclusion.^[89] An accompanying editorial in the same journal described Wakefield's work as an "elaborate fraud" that led to lower vaccination rates, putting hundreds of thousands of children at risk and diverting energy and money away from research into the true cause of autism.^[90]

A special court convened in the United States to review claims under the National Vaccine Injury Compensation Program ruled on 12 February 2009 that parents of autistic children are not entitled to compensation in their contention that certain vaccines caused autism in their children.^[91]

Vaccine overload

Vaccine overload is the notion that giving many vaccines at once may overwhelm or weaken a child's immature immune system and lead to adverse effects.^[92] Despite scientific evidence that strongly contradicts this idea,^[74] some parents of autistic children believe that vaccine overload causes autism.^[93] The resulting controversy has caused many parents to delay or avoid immunizing their children.^[92] Such parental misperceptions are major obstacles towards immunization of children.^[94]

The concept of vaccine overload is flawed on several levels.^[74] Despite the increase in the number of vaccines over recent decades, improvements in vaccine design have reduced the immunologic load from vaccines; the total number of immunological components in the 14 vaccines administered to US children in 2009 is less than 10% of what it was in the 7 vaccines given in 1980.^[74] A study published in 2013 found no correlation between autism and the antigen number in the vaccines the children were administered up to the age of two. Of the 1,008 children in the study, one quarter of them were diagnosed with autism were born between 1994 and 1999, when the routine vaccine schedule could contain more than 3,000 antigens (in a single shot of DTP vaccine). The vaccine schedule in 2012 contains several more vaccines, but the number of antigens the child is exposed to by the age of two is 315.^[95][96] Vaccines pose a minuscule immunologic load compared to the pathogens naturally encountered by a child in a typical year;^[74] common childhood conditions such as fevers and middle-ear infections pose a much greater challenge to the immune system than vaccines,^[97] and studies have shown that vaccinations, even multiple concurrent vaccinations, do not weaken the immune system^[74] or compromise overall immunity.^[98] The lack of evidence supporting the vaccine overload hypothesis, combined with these findings directly contradicting it, has led to the conclusion that currently recommended vaccine programs do not "overload" or weaken the immune system.^[1][99][100]

Any experiment based on withholding vaccines from children has been considered unethical,^[101] and observational studies would likely be confounded by differences in the health care–seeking behaviours of under-vaccinated children. Thus, no study directly comparing rates of autism in vaccinated and unvaccinated children has been done. However, the concept of vaccine overload is biologically implausible, vaccinated and unvaccinated children have the same immune response to non-vaccine-related infections, and autism is not an immune-mediated disease, so claims that vaccines could cause it by overloading the immune system go against current knowledge of the pathogenesis of autism. As such, the idea that vaccines cause autism has been effectively dismissed by the weight of current evidence.^[74] A 2011 journal article described the vaccine-autism connection as "the most damaging medical hoax of the last 100 years".^[102]

Prenatal infection

There is evidence that schizophrenia is associated with prenatal exposure to rubella, influenza, and toxoplasmosis infection. For example, one study found a sevenfold increased risk of schizophrenia when mothers were exposed to influenza in the first trimester of gestation. This may have public health implications, as strategies for preventing infection include vaccination, antibiotics, and simple hygiene.^[103] Based on studies in animal models, theoretical concerns have been raised about a possible link between schizophrenia and maternal immune response activated by virus antigens; a 2009 review concluded that there was insufficient evidence to recommend routine use of trivalent influenza vaccine during the first trimester of pregnancy, but that the vaccine was still recommended outside the first trimester and in special circumstances such as pandemics or in women with certain other conditions.^[104] The CDC's Advisory Committee on Immunization Practices, the American College of Obstetricians and Gynecologists, and the American Academy of Family Physicians all recommend routine flu shots for pregnant women, for several reasons:^[105]

• their risk for serious influenza-related medical complications during the last two trimesters;
• their greater rates for flu-related hospitalizations compared to non-pregnant women;
• the possible transfer of maternal anti-influenza antibodies to children, protecting the children from the flu; and
• several studies that found no harm to pregnant women or their children from the vaccinations.

Despite this recommendation, only 16% of healthy pregnant US women surveyed in 2005 had been vaccinated against the flu.^[105]

Aluminium

Aluminium compounds are used as immunologic adjuvants to increase the effectiveness of many vaccines.^[106] In some cases these compounds have been associated with redness, itching, and low-grade fever,^[106] but the use of aluminium in vaccines has not been associated with serious adverse events.^[107] In some cases, aluminum-containing vaccines are associated with macrophagic myofasciitis (MMF), localized microscopic lesions containing aluminium salts that persist for up to 8 years. However, recent case-controlled studies have found no specific clinical symptoms in individuals with biopsies showing MMF, and there is no evidence that aluminium-containing vaccines are a serious health risk or justify changes to immunization practice.^[107] Over the first six months of its life, an infant ingests more aluminium from dietary sources such as breast milk and infant formula than it does from vaccinations.^[108][109]

Other safety concerns

Other safety concerns about vaccines have been published on the Internet, in informal meetings, in books, and at symposia. These include hypotheses that vaccination can cause sudden infant death syndrome, epileptic seizures, allergies, multiple sclerosis, and autoimmune diseases such as type 1 diabetes, as well as hypotheses that vaccinations can transmit bovine spongiform encephalopathy, Hepatitis C virus, and HIV. These hypotheses have been investigated, with the conclusion that currently used vaccines meet high safety standards and that criticism of vaccine safety in the popular press is not justified.^[100]

Individual liberty

Compulsory vaccination policies have provoked opposition at various times from people who say that governments should not infringe on an individual's freedom to choose medications, even if that choice increases the risk of disease to themselves and others.^[2][110] If a vaccination program successfully reduces the disease threat, it may reduce the perceived risk of disease enough that an individual's optimal strategy is to refuse vaccination at coverage levels below those optimal for the community.^[111] Exempting some people from mandatory vaccination results in a free-rider problem, in which a few individuals gain the advantage of herd immunity without paying the cost; too many exemptions may cause loss of herd immunity, substantially increasing risks even to vaccinated individuals.^[112]

Religion

Vaccination has been opposed on religious grounds ever since it was introduced, even when vaccination is not compulsory. Some Christian opponents argued, when vaccination was first becoming widespread, that if God had decreed that someone should die of smallpox, it would be a sin to thwart God's will via vaccination.^[7] Religious opposition continues to the present day, on various grounds, raising ethical difficulties when the number of unvaccinated children threatens harm to the entire population.^[112] Many governments allow parents to opt out of their children's otherwise mandatory vaccinations for religious reasons; some parents falsely claim religious beliefs to get vaccination exemptions.^[113]
The Haredi burqa sect in Israel took a moral stand against vaccinations or medical treatments, which led to the death of at least one baby from untreated influenza.^[114]

The cell culture media of some viral vaccines, and the virus of the rubella vaccine, are derived from tissues taken from therapeutic abortions performed in the 1960s, leading to moral questions. For example, the principle of double effect, originated by Thomas Aquinas, holds that actions with both good and bad consequences are morally acceptable in specific circumstances, and the question is how this principle applies to vaccination.^[115] The Vatican Curia has expressed concern about the rubella vaccine's embryonic cell origin, saying that Catholics have "a grave responsibility to use alternative vaccines and to make a conscientious objection with regard to those which have moral problems."^[116] The Vatican concluded that until an alternative becomes available, it is acceptable for Catholics to use the existing vaccine, writing, "This is an unjust alternative choice, which must be eliminated as soon as possible."^[116]

Alternative medicine

Many forms of alternative medicine are based on philosophies that oppose vaccination and have practitioners who voice their opposition. These include some elements of the chiropractic community, some homeopaths, and naturopaths.^[39] The reasons for this negative vaccination view are complicated and rest at least in part on the early philosophies that shape the foundation of these groups.^[39]

Chiropractic

Historically, chiropractic strongly opposed vaccination based on its belief that all diseases were traceable to causes in the spine and therefore could not be affected by vaccines; Daniel D. Palmer, the founder of chiropractic, wrote, "It is the very height of absurdity to strive to 'protect' any person from smallpox or any other malady by inoculating them with a filthy animal poison."^[117] Vaccination remains controversial within the profession.^[118] Although most chiropractic writings on vaccination focus on its negative aspects,^[117] anti-vaccination sentiment is espoused by what appears to be a minority of chiropractors.^[118] The American Chiropractic Association and the International Chiropractic Association support individual exemptions to compulsory vaccination laws; a 1995 survey of US chiropractors found that about one third believed there was no scientific proof that immunization prevents disease.^[118] While the Canadian Chiropractic Association supports vaccination,^[117] a survey in Alberta in 2002 found that 25% of chiropractors advised patients for, and 27% advised against, vaccinations for patients or their children.^[119]

Although most chiropractic colleges try to teach about vaccination responsibly, several have faculty who seem to stress negative views.^[118] A survey of a 1999–2000 cross-section of students of Canadian Memorial Chiropractic College (CMCC), which does not formally teach anti-vaccination views, reported that fourth-year students opposed vaccination more strongly than did first-year students, with 29.4% of fourth-year students opposing vaccination.^[120] In a follow-up study on 2011–12 CMCC students, it was found that pro-vaccination attitudes heavily predominated. Students reported support rates ranging from 83.9% to 90%. This difference in attitude was proposed to be due to the lack of the previous influence of a "subgroup of some charismatic students who were enrolled at CMCC at the time, students who championed the Palmer postulates that advocated against the use of vaccination".^[121]

Homeopathy

Several surveys have shown that some practitioners of homeopathy, particularly homeopaths without any medical training, advise patients against vaccination.^[122] For example, a survey of registered homeopaths in Austria found that only 28% considered immunization an important preventive measure, and 83% of homeopaths surveyed in Sydney, Australia, did not recommend vaccination.^[39] Many practitioners of naturopathy also oppose vaccination.^[39]

"Homeopathic vaccines" are ineffective because they do not contain any active ingredients and thus do not stimulate the immune system. They can be dangerous if they take the place of effective treatments.^[123]

Financial motives

Critics have accused the vaccine industry of misrepresenting the safety and effectiveness of vaccines, covering up and suppressing information, and influencing health policy decisions for financial gain.^[2] Conversely, many groups profit by promoting the controversiality of vaccines, such as lawyers who receive fees often totalling millions of dollars, expert witnesses paid to provide testimony and to speak at conferences, and practitioners of alternative medicine offering ineffective and expensive medications, supplements, and procedures such as chelation therapy and hyperbaric oxygen therapy.^[124]

In the late 20th century, vaccines were a product with low profit margins,^[125] and the number of companies involved in vaccine manufacture declined. In addition to low profits and liability risks, manufacturers complained about low prices paid for vaccines by the CDC and other US government agencies.^[126] In the early 21st century, the vaccine market greatly improved with the approval of the vaccine Prevnar, along with a small number of other high-priced blockbuster vaccines, such as Gardasil and Pediarix, which each had sales revenues of over $1 billion in 2008.^[125]

The Artificial Womb Is Born: Welcome To The WORLD Of The MATRIX

Original link:  http://www.disclose.tv/news/The_Artificial_Womb_Is_Born_Welcome_To_The_WORLD_Of_The_MATRIX/114199?utm_content=buffer5f19b&utm_medium=social&utm_source=facebook.com&utm_campaign=buffer

February 14, 2015 - The artificial womb exists. In Tokyo, researchers have developed a technique called EUFI — extrauterine fetal incubation. They have taken goat fetuses, threaded catheters through the large vessels in the umbilical cord and supplied the fetuses with oxygenated blood while suspending them in incubators that contain artificial amniotic fluid heated to body temperature.

For a moment, as you contemplate those fetal goats, it may seem a short hop to the Central Hatchery of Aldous Huxley’s imagination. In fact, in recent decades, as medicine has focused on the beginning and end stages of pregnancy, the essential time inside the woman’s body has been reduced. We are, however, still a long way from connecting those two points, from creating a completely artificial gestation. But we are at a moment when the fetus, during its obligatory time in the womb, is no longer inaccessible, no longer locked away from medical interventions.

The future of human reproductive medicine lies along the speeding trajectories of several different technologies. There is neonatology, accomplishing its miracles at the too-abrupt end of gestation. There is fetal surgery, intervening dramatically during pregnancy to avert the anomalies that kill and cripple newborns. There is the technology of assisted reproduction, the in-vitro fertilization and gamete retrieval-and-transfer fireworks of the last 20 years. And then, inevitably, there is genetics. All these technologies are essentially new, and with them come ethical questions so potent that the very inventors of these miracles seem half-afraid of where we may be heading.

Between Womb and Air

Modern neonatology is a relatively short story: a few decades of phenomenal advances and doctors who resuscitate infants born 16 or 17 weeks early, babies weighing less than a pound. These very low-birthweight babies have a survival rate of about 10 percent. Experienced neonatologists are extremely hesitant about pushing the boundaries back any further; much research is aimed now at reducing the severe morbidity of these extreme preemies who do survive.

''Liquid preserves the lung structure and function,'' says Thomas Shaffer, professor of physiology and pediatrics at the School of Medicine at Temple University. He has been working on liquid ventilation for almost 30 years. Back in the late 1960's, he looked for a way to use liquid ventilation to prevent decompression sickness in deep-sea divers. His technology was featured in the book ''The Abyss,'' and for the movie of that name, Hollywood built models of the devices Shaffer had envisioned. As a postdoctoral student in physiology, he began working with premature infants. Throughout gestation, the lungs are filled with the appropriately named fetal lung fluid. Perhaps, he thought, ventilating these babies with a liquid that held a lot of oxygen would offer a gentler, safer way to take these immature lungs over the threshold toward the necessary goal of breathing air. Barotrauma, which is damage done to the lungs by the forced air banging out of the ventilator, would thus be reduced or eliminated.


Today, in Shaffer's somewhat labyrinthine laboratories in Philadelphia, you can come across a ventilator with pressure settings that seem astoundingly low; this machine is set at pressures that could never force air into stiff newborn lungs. And then there is the long bubbling cylinder where a special fluorocarbon liquid can be passed through oxygen, picking up and absorbing quantities of oxygen molecules. This machine fills the lungs with fluid that flows into the tiny passageways and air sacs of a premature human lung.

Shaffer remembers, not long ago, when many people thought the whole idea was crazy, when his was the only team working on filling human lungs with liquid. Now, liquid ventilation is cited by many neonatologists as the next large step in treating premature infants. In 1989, the first human studies were done, offering liquid ventilation to infants who were not thought to have any chance of survival through conventional therapy. The results were promising, and bigger trials are now under way. A pharmaceutical company has developed a fluorocarbon liquid that has the capacity to carry a great deal of dissolved oxygen and carbon dioxide -- every 100 milliliters holds 50 milliliters of oxygen. By putting liquid into the lung, Shaffer and his colleagues argue, the lung sacs can be expanded at a much lower pressure.

''I wouldn't want to push back the gestational age limit,'' Shaffer says. ''I want to eliminate the damage.'' He says he believes that this technology may become the standard. By the year 2000, these techniques may be available in large centers. Pressed to speculate about the more distant future, he imagines a premature baby in a liquid-dwelling and a liquid-breathing intermediate stage between womb and air: Immersed in fluid that would eliminate insensible water loss you would need a sophisticated temperature-control unit, a ventilator to take care of the respiratory exchange part, better thermal control and skin care.

The Fetus as Patient

The notion that you could perform surgery on a fetus was pioneered by Michael Harrison at the University of California in San Francisco. Guided by an improved ultrasound technology, it was he who reported, in 1981, that surgical intervention to relieve a urinary tract obstruction in a fetus was possible.

''I was frustrated taking care of newborns,'' says N. Scott Adzick, who trained with Harrison and is surgeon in chief at the Children's Hospital of Philadelphia.

When children are born with malformations, damage is often done to the organ systems before birth; obstructive valves in the urinary system cause fluid to back up and destroy the kidneys, or an opening in the diaphragm allows loops of intestine to move up into the chest and crowd out the lungs. ''It's like a lot of things in medicine,'' Adzick says, ''if you'd only gotten there earlier on, you could have prevented the damage. I felt it might make sense to treat certain life-threatening malformations before birth.''


Adzick and his team see themselves as having two patients, the mother and the fetus. They are fully aware that once the fetus has attained the status of a patient, all kinds of complex dilemmas result. Their job, says Lori Howell, coordinator of Children's Hospital's Center for Fetal Diagnosis and Treatment, is to help families make choices in difficult situations. Terminate a pregnancy, sometimes very late? Continue a pregnancy, knowing the fetus will almost certainly die? Continue a pregnancy, expecting a baby who will be born needing very major surgery? Or risk fixing the problem in utero and allow time for normal growth and development?

The first fetal surgery at Children's Hospital took place seven months ago. Felicia Rodriguez, from West Palm Beach, Fla., was 22 weeks pregnant. Through ultrasound, her fetus had been diagnosed as having a congenital cystic adenomatoid malformation a mass growing in the chest, which would compress the fetal heart, backing up the circulation, killing the fetus and possibly putting the mother into congestive heart failure.

When the fetal circulation started to back up, Rodriguez flew to Philadelphia. The surgeons made a Caesarean-type incision. They performed a hysterotomy by opening the uterus quickly and bloodlessly, and then opened the amniotic sac and brought out the fetus's arm, exposing the relevant part of the chest. The mass was removed, the fetal chest was closed, the amniotic membranes sealed with absorbable staples and glue, the uterus was closed and the abdomen was sutured. And the pregnancy continued -- with special monitoring and continued use of drugs to prevent premature labor. The uterus, no longer anesthetized, is prone to contractions. Rodriguez gave birth at 35 weeks' gestation, 13 weeks after surgery, only 5 weeks before her due date. During those 13 weeks, the fetal heart pumped normally with no fluid backup, and the fetal lung tissue developed properly. Roberto Rodriguez 3d was born this May, a healthy baby born to a healthy mother.

This is a new and remarkable technology. Children's Hospital of Philadelphia and the University of California at San Francisco are the only centers that do these operations, and fewer than a hundred have been done. The research fellows, residents working in these labs and training as the next generation of fetal surgeons, convey their enthusiasm for their field and their mentors in everything they say. When you sit with them, it is impossible not to be dazzled by the idea of what they can already do and by what they will be able to do. ''When I dare to dream,'' says Theresa Quinn, a fellow at Children's Hospital, ''I think of intervening before the immune system has time to mature, allowing for advances that could be used in organ transplantation to replacement of genetic deficiencies.''

But What Do We Want?

Eighteen years ago, in-vitro fertilization was tabloid news: test-tube babies! Now IVF is a standard therapy, an insurance wrangle, another medical term instantly understood by most lay people. Enormous advertisements in daily newspapers offer IVF, egg-donation programs, even the newer technique of ICSI intracytoplasmic sperm injection as consumer alternatives. It used to be, for women at least, that genetic and gestational motherhood were one and the same. It is now possible to have your own fertilized egg carried by a surrogate or, much more commonly, to go through a pregnancy carrying an embryo formed from someone else's egg.

Given the strong desire to be pregnant, which drives many women to request donor eggs and go through biological motherhood without a genetic connection to the fetus, is it really very likely that any significant proportion of women would take advantage of an artificial womb? Could we ever reach a point where the desire to carry your own fetus in your own womb will seem a willful rejection of modern health and hygiene, an affected earth-motherism that flies in the face of common sense -- the way I feel about mothers in Cambridge who ostentatiously breast-feed their children until they are 4 years old?

I would argue that God in her wisdom created pregnancy so Moms and babies could develop a relationship before birth, says Alan Fleischman, professor of pediatrics at Albert Einstein College of Medicine in New York, who directed the neonatal program at Montefiore Medical Center for 20 years.

Mary Mahowald, a professor at the MacLean Center for Clinical Medical Ethics at the University of Chicago, and one of her medical students surveyed women about whether they would rather be related to a child gestationally or genetically, if they couldn't choose both. A slight majority opted for the gestational relationship, caring more about carrying the pregnancy, giving birth and nursing than about the genetic tie. ''Pregnancy is important to women,'' Mahowald says. ''Some women might prefer to be done with all this -- we hire our surrogates, we hire our maids, we hire our nannies -- but I think these things are going to have very limited interest.''

Susan Cooper, a psychologist who counsels people going through infertility workups, isn't so sure. Yes, she agrees, many of the patients she sees have ''an intense desire to be pregnant but it's hard to know whether that's a biological urge or a cultural urge.''

And Arthur L. Caplan, director of the Center for Bioethics at the University of Pennsylvania, takes it a step further. Thirty years from now, he speculates, we will have solved the problem of lung development; neonatology will be capable of saving 15- and 16-week-old fetuses. There will be many genetic tests available, easy to do, predicting the risks of acquiring late-onset diseases, but also predicting aptitudes, behavior traits and aspects of personality. There won't be an artificial womb available, but there will be lots of prototypes, and women who can't carry a pregnancy will sign up to use the prototypes in experimental protocols. Caplan also predicts that ''there will be a movement afoot which says all this is unnecessary and unnatural, and that the way to have babies is sex and the random lottery of nature a movement with the appeal of the environmental movement today.'' Sixty years down the line, he adds, the total artificial womb will be here. ''It's technologically inevitable. Demand is hard to predict, but I'll say significant.''

It all used to happen in the dark -- if it happened at all. It occurred well beyond our seeing or our intervening, in the wet, lightless spaces of the female body. So what changes when something as fundamental as human reproduction comes out of the closet, so to speak? Are we, in fact, different if we take hands-on control over this most basic aspect of our biology? Should we change our genetic trajectory and thus our evolutionary path? Eliminate defects or eliminate differences or are they one and the same? Save every fetus, make every baby a wanted baby, help every wanted child to be born healthy -- are these the same? What are our goals as a society, what are our goals as a medical profession, what are our goals as individual parents -- and where do these goals diverge?

''The future is rosy for bioethicists,'' Caplan says.

Perri Klass's most recent book is ''Baby Doctor.'' She is a pediatrician at Boston Medical Center.

Saturated fat

From Wikipedia, the free encyclopedia

A saturated fat is a fat that consists of triglycerides containing only saturated fatty acids. Saturated fatty acids have no double bonds between the individual carbon atoms of the fatty acid chain. That is, the chain of carbon atoms is fully "saturated" with hydrogen atoms. There are many kinds of naturally occurring saturated fatty acids, which differ mainly in number of carbon atoms, from 3 carbons (propionic acid) to 36 (hexatriacontanoic acid).

Various fats contain different proportions of saturated and unsaturated fat. Examples of foods containing a high proportion of saturated fat include animal fat products such as cream, cheese, butter, ghee, suet, tallow, lard, and fatty meats.^[1] Certain vegetable products have high saturated fat content, such as coconut oil, cottonseed oil, palm kernel oil and chocolate^{[citation needed]}. Many prepared foods are high in saturated fat content, such as pizza, dairy desserts, bacon and sausage.^[2][3]

Fat profiles

While nutrition labels regularly combine them, the saturated fatty acids appear in different proportions among food groups. Lauric and myristic acids are most commonly found in "tropical" oils (e.g., palm kernel, coconut) and dairy products. The saturated fat in meat, eggs, cacao, and nuts is primarily the triglycerides of palmitic and stearic acids.

Saturated fat profile of common foods; Esterified fatty acids as percentage of total fat^[4]

Food	Lauric acid	Myristic acid	Palmitic acid	Stearic acid
Coconut oil	47%	18%	9%	3%
Palm oil	48%	1%	44%	5%
Butter	3%	11%	29%	13%
Ground beef	0%	4%	26%	15%
Salmon	0%	1%	29%	3%
Egg yolks	0%	0.3%	27%	10%
Cashews	2%	1%	10%	7%
Soybean oil	0%	0%	11%	4%

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Food	Saturated	Mono- unsaturated	Poly- unsaturated
	As weight percent (%) of total fat
Cooking oils
Canola oil	8	64	28
Corn oil	13	24	59
Olive oil	7	78	15
Sunflower oil[5]	11	20	69
Soybean oil	15	24	58
Peanut oil[6]	17	46	32
Rice bran oil	25	38	37
Coconut oil	87	13	1
Dairy products
Cheese, regular	64	29	3
Cheese, light	60	30	0
Milk, whole	62	28	4
Milk, 2%	62	30	0
Ice cream, gourmet	62	29	4
Ice cream, light	62	29	4
Meats
Beef	33	38	5
Ground sirloin	38	44	4
Pork chop	35	44	8
Ham	35	49	16
Chicken breast	29	34	21
Chicken	34	23	30
Turkey breast	30	20	30
Turkey drumstick	32	22	30
Fish, orange roughy	23	15	46
Salmon	28	33	28
Hot dog, beef	42	48	5
Hot dog, turkey	28	40	22
Burger, fast food	36	44	6
Cheeseburger, fast food	43	40	7
Breaded chicken sandwich	20	39	32
Grilled chicken sandwich	26	42	20
Sausage, Polish	37	46	11
Sausage, turkey	28	40	22
Pizza, sausage	41	32	20
Pizza, cheese	60	28	5
Nuts
Almonds dry roasted	9	65	21
Cashews dry roasted	20	59	17
Macadamia dry roasted	15	79	2
Peanut dry roasted	14	50	31
Pecans dry roasted	8	62	25
Flaxseeds, ground	8	23	65
Sesame seeds	14	38	44
Soybeans	14	22	57
Sunflower seeds	11	19	66
Walnuts dry roasted	9	23	63
Sweets and baked goods
Candy, chocolate bar	59	33	3
Candy, fruit chews	14	44	38
Cookie, oatmeal raisin	22	47	27
Cookie, chocolate chip	35	42	18
Cake, yellow	60	25	10
Pastry, Danish	50	31	14
Fats added during cooking or at the table
Butter, stick	63	29	3
Butter, whipped	62	29	4
Margarine, stick	18	39	39
Margarine, tub	16	33	49
Margarine, light tub	19	46	33
Lard	39	45	11
Shortening	25	45	26
Chicken fat	30	45	21
Beef fat	41	43	3
Dressing, blue cheese	16	54	25
Dressing, light Italian	14	24	58
Other
Egg yolk fat[7]	36	44	16
Avocado [8]	16	71	13
Unless else specified in boxes, then reference is:[9]

Examples of saturated fatty acids

Some common examples of fatty acids:

• Butyric acid with 4 carbon atoms (contained in butter)
• Lauric acid with 12 carbon atoms (contained in coconut oil, palm kernel oil, and breast milk)
• Myristic acid with 14 carbon atoms (contained in cow's milk and dairy products)
• Palmitic acid with 16 carbon atoms (contained in palm oil and meat)
• Stearic acid with 18 carbon atoms (also contained in meat and cocoa butter)

Association with diseases

Since the 1950s, it has been commonly believed that consumption of foods containing high amounts of saturated fatty acids (including meat fats, milk fat, butter, lard, coconut oil, palm oil, and palm kernel oil) is potentially less healthy than consuming fats with a lower proportion of saturated fatty acids. Sources of lower saturated fat but higher proportions of unsaturated fatty acids include olive oil, peanut oil, canola oil, avocados, safflower, corn, sunflower, soy, and cottonseed oils.^[10]

Cardiovascular disease

Leading medical, heart-health, and governmental authorities, such as the World Health Organization,^[11] the American Dietetic Association,^[12] the Dietitians of Canada,^[12] the British Dietetic Association,^[13] American Heart Association,^[14] the British Heart Foundation,^[15] the World Heart Federation,^[16] the British National Health Service,^[17] the United States Food and Drug Administration,^[18] and the European Food Safety Authority^[19] advise that saturated fat is a risk factor for cardiovascular disease (CVD).
A number of systematic reviews have examined the relationship between saturated fat and cardiovascular disease and have come to different conclusions:

A 2014 systematic review looking at observational studies of dietary intake of fatty acids, observational studies of measured fatty acid levels in the blood, and intervention studies of polyunsaturated fat supplementation concludes that the finding ″do not support cardiovascular guidelines that promote high consumption of long-chain omega-3 and omega-6 and polyunsaturated fatty acids and suggest reduced consumption of total saturated fatty acids.″^[20] Researchers acknowledged that despite their results, further research is necessary, especially in people who are initially healthy. Until the picture becomes clearer, experts recommend people stick to the current guidelines on fat consumption.^[21]

Harcombe, 2015[22]	No reduction in CHD and all-cause mortality were observed when replacing saturated fat with polyunsaturated fat, even though reductions in serum cholesterol were observed.
Schwab, 2014[23]	There was convincing evidence that partial replacement of saturated fat with polyunsaturated fat decreases the risk of cardiovascular diseases, especially in men.
Hooper, 2011[24]	Reducing saturated fat in diets did not reduce mortality, despite reducing the risk of having a cardiovascular event by 14 percent.
Micha, 2010[25]	Based on consistent evidence from human studies, replacing SFA with polyunsaturated fat modestly lowers coronary heart disease risk, with ~10% risk reduction for a 5% energy substitution; whereas replacing SFA with carbohydrate has no benefit and replacing SFA with monounsaturated fat has uncertain effects.
Mozaffarian, 2010[26]	These findings provide evidence that consuming polyunsaturated fats (PUFA) in place of SFA reduces Coronary Heart Disease (CHD) events in randomized controlled trials (RCT). Replacing saturated fats with PUFAs as percentage of calories strongly reduced CHD mortality.
Siri-Tarino, 2010[27]	5–23 years of follow-up of 347,747 subjects, 11,006 developed CHD or stroke. A meta-analysis of prospective epidemiologic studies showed that there is no significant evidence for concluding that dietary saturated fat is associated with an increased risk of CHD or CVD.
Danaei, 2009[28]	Low PUFA intake has an 1-5% Increased risk of ischemic heart disease: Low dietary PUFA (in replacement of SFA). age 30–44 Increase in RR 1.05.
Mente, 2009[29]	Single-nutrient RCTs have yet to evaluate whether reducing saturated fatty acid intake lowers the risk of CHD events. For polyunsaturated fatty acid intake, most of the RCTs have not been adequately powered and did not find a significant reduction in CHD outcomes.
Skeaff, 2009[30]	Intake of SFA was not significantly associated with CHD mortality, with a RR of 1.14. Moreover, there was no significant association with CHD death. Intake of PUFA was strongly significantly associated with CHD mortality, with a RR of 1.25. The Health Professionals Follow-up Study and the EUROASPIRE study results mirrored those of total PUFA; intake of linoleic acid was significantly associated with CHD mortality.
Jakobsen, 2009[31]	"The associations suggest that replacing saturated fatty acids with polyunsaturated fatty acids rather than monounsaturated fatty acids or carbohydrates prevents CHD over a wide range of intakes."
Van Horn, 2008[32]	25-35% fats but <7% SFA and TFA reduces risk.

While many studies have found that including polyunsaturated fats in the diet in place of saturated fats produces more beneficial CVD outcomes, the effects of substituting monounsaturated fats or carbohydrates are unclear.^[33][34]

Dyslipidemia

The consumption of saturated fat is generally considered a risk factor for dyslipidemia, which in turn is a risk factor for some types of cardiovascular disease.^{[35][36][37][38][39]}
There are strong, consistent, and graded relationships between saturated fat intake, blood cholesterol levels, and the mass occurrence of cardiovascular disease. The relationships are accepted as causal.^[40][41] Abnormal blood lipid levels, that is high total cholesterol, high levels of triglycerides, high levels of low-density lipoprotein (LDL, "bad" cholesterol) or low levels of high-density lipoprotein (HDL, "good" cholesterol) cholesterol are all associated with increased risk of heart disease and stroke.^[16]

Meta-analyses have found a significant relationship between saturated fat and serum cholesterol levels.^[42] High total cholesterol levels, which may be caused by many factors, are associated with an increased risk of cardiovascular disease.^[43][44] However, other indicators measuring cholesterol such as high total/HDL cholesterol ratio are more predictive than total serum cholesterol.^[44] In a study of myocardial infarction in 52 countries, the ApoB/ApoA1 (related to LDL and HDL, respectively) ratio was the strongest predictor of CVD among all risk factors.^[45] There are other pathways involving obesity, triglyceride levels, insulin sensitivity, endothelial function, and thrombogenicity, among others, that play a role in CVD, although it seems, in the absence of an adverse blood lipid profile, the other known risk factors have only a weak atherogenic effect.^[46] Different saturated fatty acids have differing effects on various lipid levels.^[47]

Cancer

Breast cancer

A meta-analysis published in 2003 found a significant positive relationship in both control and cohort studies between saturated fat and breast cancer.^[48] However two subsequent reviews have found weak or insignificant associations of saturated fat intake and breast cancer risk,^[49][50] and note the prevalence of confounding factors.^[49][51]

Colorectal cancer

A systematic literature review published by the World Cancer Research Fund and the American Institute for Cancer Research in 2007 found limited but consistent evidence for a positive relationship between animal fat and colorectal cancer.^[52]

Ovarian cancer

A meta-analysis of eight observational studies published in 2001 found a statistically significant positive relationship between saturated fat and ovarian cancer.^[53] However, a 2013 study found that a pooled analysis of 12 cohort studies observed no association between total fat intake and ovarian cancer risk. Further analysis revealed that omega-3 fatty acids were protective against ovarian cancer and that trans fats were a risk factor.^[54] This study revealed that histological subtypes should be examined in determining the impact of dietary fat on ovarian cancer, rather than an oversimplified focus on total fat intake.

Prostate cancer

Some researchers have indicated that serum myristic acid^[55][56] and palmitic acid^[56] and dietary myristic^[57] and palmitic^[57] saturated fatty acids and serum palmitic combined with alpha-tocopherol supplementation^[55] are associated with increased risk of prostate cancer in a dose-dependent manner. 

 

These associations may, however, reflect differences in intake or metabolism of these fatty acids between the precancer cases and controls, rather than being an actual cause.^[56]

Bones

Mounting evidence indicates that the amount and type of fat in the diet can have important effects on bone health. Most of this evidence is derived from animal studies. The data from one study indicated that bone mineral density is negatively associated with saturated fat intake, and that men may be particularly vulnerable.^[58]

Dietary recommendations

Recommendations to reduce or limit dietary intake of saturated fats are made by Health Canada,^[59] the US Department of Health and Human Services,^[60] the UK Food Standards Agency,^[61] the Australian Department of Health and Aging,^[62] the Singapore Government Health Promotion Board,^[63] the Indian Government Citizens Health Portal,^[64] the New Zealand Ministry of Health,^[65] the Food and Drugs Board Ghana,^[66] the Republic of Guyana Ministry of Health,^[67] and Hong Kong's Centre for Food Safety.^[68]

A 2004 statement released by the Centers for Disease Control (CDC) determined that "Americans need to continue working to reduce saturated fat intake…"^[69] In addition, reviews by the American Heart Association led the Association to recommend reducing saturated fat intake to less than 7% of total calories according to its 2006 recommendations.^[70][71] This concurs with similar conclusions made by the US Department of Health and Human Services, which determined that reduction in saturated fat consumption would positively affect health and reduce the prevalence of heart disease.^[72]

In 2003, the World Health Organization (WHO) and Food and Agriculture Organization (FAO) expert consultation report concluded that "intake of saturated fatty acids is directly related to cardiovascular risk. The traditional target is to restrict the intake of saturated fatty acids to less than 10% of daily energy intake and less than 7% for high-risk groups. If populations are consuming less than 10%, they should not increase that level of intake. Within these limits, intake of foods rich in myristic and palmitic acids should be replaced by fats with a lower content of these particular fatty acids. In developing countries, however, where energy intake for some population groups may be inadequate, energy expenditure is high and body fat stores are low (BMI <18.5 kg/m²). The amount and quality of fat supply has to be considered keeping in mind the need to meet energy requirements. Specific sources of saturated fat, such as coconut and palm oil, provide low-cost energy and may be an important source of energy for the poor."^[73]

Dr. German and Dr. Dillard of University of California and Nestle Research Center in Switzerland, in their 2004 review, pointed out that "no lower safe limit of specific saturated fatty acid intakes has been identified" and recommended that the influence of varying saturated fatty acid intakes against a background of different individual lifestyles and genetic backgrounds should be the focus in future studies.^[74]

Blanket recommendations to lower saturated fat were criticized at a 2010 conference debate of the American Dietetic Association for focusing too narrowly on reducing saturated fats rather than emphasizing increased consumption of healthy fats and unrefined carbohydrates. Concern was expressed over the health risks of replacing saturated fats in the diet with refined carbohydrates, which carry a high risk of obesity and heart disease, particularly at the expense of polyunsaturated fats which may have health benefits. None of the panelists recommended heavy consumption of saturated fats, emphasizing instead the importance of overall dietary quality to cardiovascular health.^[75]

Molecular description

Two-dimensional representation of the saturated fatty acid myristic acid

A space-filling model of the saturated fatty acid myristic acid

It should be noted, as this is the defining factor of saturated fats, that the two-dimensional illustration has implicit hydrogens bonded to each of the carbon atoms in the polycarbon tail of the myristic acid molecule (there are 13 carbons in the tail, 14 carbons in the entire molecule).

Carbon atoms are also implicitly drawn, as they are portrayed as intersections between two straight lines. "Saturated," in general, refers to a maximum number of hydrogens bonded to each carbon of the polycarbon tail as allowed by the Octet Rule. This also means that only single bonds (sigma bonds) will be present between adjacent carbon atoms of the tail.