Re: Aluminium up?

[Guest guest]

Don't know about the aluminum, but, wanted to comment on your eye drops topic... my own experience at two different hospitals was that the staff was so inculcated as to "procedure" that when an informed parent attempted to REFUSE the eye drops (because of no risk factors)... they accused me of child abuse -- and COULD NOT even answer the question of WHY it was important.... Despite my refusal, since I have no STDs, THEY PUT THEM IN ANYWAY!!! I am sure they probably contained thimerosal (1999 and 2000.) ... hmmmm, anyone know how to look this up?Thanks,

~D

From: EOHarm [mailto:EOHarm ] On Behalf Of HollySent: Sunday, May 07, 2006 1:58 AMEOHarm Subject: Aluminium up?

Hi Group,My friend who is a nurse said with the removal of mercury the amount of Al was increased. Anyone know if this is true? Also she said when babies are born in the hospital it is automatic procedure to put silver drops in their eyes(my guess similiar to collodial silver) just in case mom has syphillis or ghonerria. Anyone know about this as well. Holly

[Guest guest]

they no longer use silver nitrate drops. instead they use erythromycinan-an antibiotic. my first child had them and had a goopy eye for a month afterward. i heard that because the drops cloud the baby's vision, it can interfere with the bonding process. in australia they do not routinely give babies the eyedrops. that's how "important" it is.Holly <inticci@...> wrote: Hi Group, My friend who is a nurse said with the removal of mercury the amount of Al was increased. Anyone know if this is true? Also she said when babies are born in the hospital it is automatic procedure to put silver drops in their eyes(my guess similiar to collodial silver) just in case mom has syphillis or ghonerria. Anyone know about this as well. Holly

Get amazing travel prices for air and hotel in one click on FareChase

[Guest guest]

Aluminum is used as an adjuvant in vaccines. Thimerosal is a

preservative. They wouldn't increase an adjuvant to replace

thimerosal.

Critical Decisions Count

http://users.adelphia.net/~cdc/VaccineIngredients.htm#Aluminum

>

> Hi Group,

>

> My friend who is a nurse said with the removal of mercury the

amount

> of Al was increased. Anyone know if this is true? Also she said

when

> babies are born in the hospital it is automatic procedure to put

> silver drops in their eyes(my guess similiar to collodial silver)

just

> in case mom has syphillis or ghonerria. Anyone know about this as

> well. Holly

>

[Guest guest]

Hi ! Could it be that Thimerosal is somehow acting as an adjuvant after all and could it be the reason why they don't want it out?

Jo Pike

Re: Aluminium up?

Aluminum is used as an adjuvant in vaccines. Thimerosal is a preservative. They wouldn't increase an adjuvant to replace thimerosal.Critical Decisions Counthttp://users.adelphia.net/~cdc/VaccineIngredients.htm#Aluminum>> Hi Group,> > My friend who is a nurse said with the removal of mercury the amount > of Al was increased. Anyone know if this is true? Also she said when > babies are born in the hospital it is automatic procedure to put > silver drops in their eyes(my guess similiar to collodial silver) just > in case mom has syphillis or ghonerria. Anyone know about this as > well. Holly>

[Guest guest]

I think Jo may be right. I have seen documents that show precisely

this - that our vaccine regulators (international) are concerned that

the antigenicity of vaccines and therefore efficacy will be/has been

reduced by the removal of thimerosal. This is never promoted but is a

dirty little secret. Thimerosal provokes an immune response - we now

know from several studies that part of the problem with thimerosal is

that it provokes production of cytokines, B cells and other immune

responses - without telling anyone publicly the authorities know that

vaccine efficacy depends in part on thimerosal.

So, contrary to what should be the case thimerosal removal might reduce

antigenicity to the point that more adjuvant is necessary.

It is a DIRTY LITTLE SECRET.

This will be part of a presentation being made at Autism One on why the

authorities are opposing the thimerosal ban legislation in a seeming

" reversal " of the 1999 PHS and AAP recommendations. Presentation by

Lujene and Krakow.

On May 7, 2006, at 10:04 AM, Jo Pike wrote:

> Hi ! Could it be that Thimerosal is somehow acting as an adjuvant

> after all and could it be the reason why they don't want it out?

>  

> Jo Pike

>> Re: Aluminium up?

>>

>> Aluminum is used as an adjuvant in vaccines. Thimerosal is a

>> preservative. They wouldn't increase an adjuvant to replace

>> thimerosal.

>>

>>

>> Critical Decisions Count

>> http://users.adelphia.net/~cdc/VaccineIngredients.htm#Aluminum

>>

>>

>>

>> >

>> > Hi Group,

>> >

>> > My friend who is a nurse said with the removal of mercury the

>> amount

>> > of Al was increased.  Anyone know if this is true?  Also she said

>> when

>> > babies are born in the hospital it is automatic procedure to put

>> > silver drops in their eyes(my guess similiar to collodial silver)

>> just

>> > in case mom has syphillis or ghonerria.  Anyone know about this as

>> > well.  Holly

>> >

>>

>>

>>

>>

>>

>>

>>

[Guest guest]



I honestly believe the only reason thimerosal is in vaccines is due to old snake oil logic that it works wonders. Did people go crazy from VD, or the treatment?

Re: Aluminium up?Aluminum is used as an adjuvant in vaccines. Thimerosal is a preservative. They wouldn't increase an adjuvant to replace thimerosal.Critical Decisions Counthttp://users.adelphia.net/~cdc/VaccineIngredients.htm#Aluminum>> Hi Group,> > My friend who is a nurse said with the removal of mercury the amount > of Al was increased. Anyone know if this is true? Also she said when > babies are born in the hospital it is automatic procedure to put > silver drops in their eyes(my guess similiar to collodial silver) just > in case mom has syphillis or ghonerria. Anyone know about this as > well. Holly>

[Guest guest]

Hi Jo! Nice to hear from you. Hope everything is going great! Any

chemical can promote an immune response. Of course, thimerosal isn't

approved as an " adjuvant " .

I found an interesting abstract from 1977.

Arch Dermatol Res. 1977 May 27;258(3):235-9. Related Articles,

Links

The adjuvant effect of tuberculin in experimental sensitization to

merthiolate.

Magnusson B, Moller H.

When guinea pigs were sensitized to tuberculin by exposure to

complete Freund's adjuvant the size of the intradermal PPD test was

positively correlated to the body weight of the animal. Old

Tuberculin showed stimulating effect in a subsequent sensitization to

merthiolate (thimerosal). The high frequency of delayed cutaneous

allergy to merthiolate in Swedish population is probably explained by

sensitization through intradermal testing with tuberculin containing

merthiolate as a preservative.

PMID: 583641 [PubMed - indexed for MEDLINE]

> >

> > Hi Group,

> >

> > My friend who is a nurse said with the removal of mercury the

> amount

> > of Al was increased. Anyone know if this is true? Also she

said

> when

> > babies are born in the hospital it is automatic procedure to

put

> > silver drops in their eyes(my guess similiar to collodial

silver)

> just

> > in case mom has syphillis or ghonerria. Anyone know about this

as

> > well. Holly

> >

>

>

>

>

>

>

>

[Guest guest]



So..., if we don't poison ourselves, we don't get antigenicity.

This is the best that can be done??

If this is true, then the whole vaccine program is totally flawed.

+ Re: Aluminium up?Aluminum is used as an adjuvant in vaccines. Thimerosal is a preservative. They wouldn't increase an adjuvant to replace thimerosal.Critical Decisions Counthttp://users.adelphia.net/~cdc/VaccineIngredients.htm#Aluminum>> Hi Group,> > My friend who is a nurse said with the removal of mercury the amount > of Al was increased. Anyone know if this is true? Also she said when > babies are born in the hospital it is automatic procedure to put > silver drops in their eyes(my guess similiar to collodial silver) just > in case mom has syphillis or ghonerria. Anyone know about this as > well. Holly>

[Guest guest]

Yes, the program is flawed. That's their DIRTY LITTLE SECRET.

The only it way it works-with vaccines as they currently exist- is by

poisoning people. Some it poisons a little and they seem ok. Some

never recover.

On May 7, 2006, at 2:15 PM, H wrote:

> So..., if we don't poison ourselves, we don't get antigenicity.

> This is the best that can be done??

> If this is true, then the whole vaccine program is totally flawed. 

>  

>  

>  

>> + Re: Aluminium up?

>>>>

>>>> Aluminum is used as an adjuvant in vaccines. Thimerosal is a

>>>> preservative. They wouldn't increase an adjuvant to replace

>>>> thimerosal.

>>>>

>>>>

>>>> Critical Decisions Count

>>>> http://users.adelphia.net/~cdc/VaccineIngredients.htm#Aluminum

>>>>

>>>>

>>>>

>>>> >

>>>> > Hi Group,

>>>> >

>>>> > My friend who is a nurse said with the removal of mercury the

>>>> amount

>>>> > of Al was increased.  Anyone know if this is true?  Also she said

>>>> when

>>>> > babies are born in the hospital it is automatic procedure to put

>>>> > silver drops in their eyes(my guess similiar to collodial silver)

>>>> just

>>>> > in case mom has syphillis or ghonerria.  Anyone know about this as

>>>> > well.  Holly

>>>> >

>>>>

>>>>

>>>>

>>>>

>>>>

>>>>

>>>>

[Guest guest]



Yes, the program is flawed. That's their DIRTY LITTLE SECRET. Could it be that Thimerosal is somehow acting as an adjuvant after all and could it be the reason why they don't want it out?

I believe it is about the controlled release and blocking of serotonin http://tinyurl.com/gk7jc , the objective of the original program. http://tinyurl.com/e6tpx http://tinyurl.com/eguom They will never remove it. Peace; ...

http://tinyurl.com/jz48p Pre-emptive treatment in Lilly study stirs debate - May 1, 2006

The behavior modification plan of the MKULTRA Violence Control Centers included: http://tinyurl.com/lf8wu (click: Reagan Era - Violence Center) Studies of violent individuals.Experiments on prisoners from Vacaville and Atascadero, and hyperkinetic children. http://tinyurl.com/gwc4c Experiments with violence-producing and violent inhibiting drugs.Hormonal aspects of passivity and aggressiveness in boys.Studies to discover and compare norms of violence among various ethnic groups.Studies of pre-delinquent children.It would also encourage law enforcement to keep computer files on pre-delinquent children, which would make possible the treatment of children before they became delinquents.

http://tinyurl.com/2ozo3 June 19, 2004 Bush plans to screen whole US population for mental illness ...Olanzapine (trade name Zyprexa), one of the atypical antipsychotic drugs recommended as a first line drug in the Texas algorithm, grossed $4.28bn (£2.35bn; 3.56bn) worldwide in 2003 and is Eli Lilly's top selling drug. A 2003 New York Times article by Gardiner reported that 70% of olanzapine sales are paid for by government agencies, such as Medicare and Medicaid.

Eli Lilly and MKUTLRA http://zmagsite.zmag.org/May2004/levine0504.html There is one Eli Lilly piece of history so bizarre that if told to many psychiatrists, one just might get diagnosed as paranoid schizophrenic and medicated with Zyrprexa. Former State Department officer Marks in The Search for the “Manchurian Candidateâ€: The CIA and Mind Control, The Secret History of the Behavioral Sciences (1979)—along with the Washington Post (1985) and the New York Times (1988)—reported an amazing story about the CIA and psychiatry. A lead player was psychiatrist D. Ewen Cameron, president of the American Psychiatric Association in 1953. Cameron was curious to discover more powerful ways to break down patient resistance. Using electroshock, LSD, and sensory deprivation, he was able to produce severe delirium. Patients often lost their sense of identity, forgetting their own names and even how to eat. The CIA, eager to learn more about Cameron’s brainwashing techniques, funded him under a project code-named MKULTRA. According to Marks, Cameron was part of a small army of the CIA’s LSD-experimenting psychiatrists. Where did the CIA get its LSD? Marks reports that the CIA had been previously supplied by the Swiss pharmaceutical corporation Sandoz, but was uncomfortable relying on a foreign company and so, in 1953, the CIA asked Eli Lilly to make them up a batch of LSD, which Lilly subsequently donated to the CIA.

Eli Lilly and LSD http://tinyurl.com/nkha6 All around the world, the CIA tried to stay on top of the LSD supply. Back home in Indianapolis, Eli Lilly & Company was even then working on a process to synthesize LSD. Agency officials felt uncomfortable having to rely on a foreign company for their supply, and in 1953 they asked Lilly executives to make them up a batch, which the company subsequently donated to the government. http://tinyurl.com/gw2m2 Lysergic acid is a metabolite of LSD, a hallucinogenic drug. Lysergic acid and similar compounds, collectively known as serotonin antagonists, bond to the same D-receptors used by serotonin. Through this action, lysergic acid blocks serotonin and redirects neural pulses.

Eil Lilly and Thimoersal http://tinyurl.com/jrqaq Thimerosal is an organic compound that is 49.6 percent ethylmercury. Eli Lilly and Co., the Indianapolis-based drug giant, developed and registered thimerosal under its trade name Merthiolate in 1929 and began marketing it as an antibacterial, antifungal product. It became the most widely used preservative in vaccines. http://tinyurl.com/zmze4 In platelets, thimerosal causes aggregation, increase of arachidonic acid metabolism, and exocytotic release of serotonin. http://tinyurl.com/qgf8y Thimerosal induces a release reaction, seen in ultrastructural study and revealed by measurement of 14C-serotonin release. http://tinyurl.com/hw4e7 Autism and its Connection with the Neurotransmitter Serotonin.

Eli Lilly and Prozac http://www.prozac.com/index.jsp http://tinyurl.com/foglu PROZAC may help to correct this imbalance by increasing the brain's own supply of serotonin.

Eli Lilly and Strettera http://www.strattera.com/index.jsp http://tinyurl.com/kssty Strattera very selectively affects only the norepinephrine pathways. It does not influence the function of other neurotransmitters.

Eli Lilly and Zyprexa http://www.zyprexa.com/index.jsp http://tinyurl.com/hc9w4 Zyprexa, like the other atypical antipsychotics, appears to work by by blocking certain serotonin and dopamine receptors. Unlike some other medications it blocks the serotonin receptors more potently than the dopamine receptors. http://tinyurl.com/2ozo3

(P.S., For some strange reason Zyprexa reminds me of Dypraxa, in "The Constant Gardener", for some odd reason).

H.W. Bush

1976-1977 Director of the Central Intelligence Agency (CIA)

1977-1979 Eli Lilly Corporate Director, appointed by the father of the future Vice President Dan Quayle who owned controlling interest in the corporation.

1981-1989 Vice-President H.W. Bush under President Reagan

1981-1989 Director or President Reagan’s "Drug Task Force"

1989-1993 President H.W. Bush and Vice-President Danforth (Dan) Quayle??

2001-2008 H.W. Bush’s son becomes President W. Bush with Vice-President (Dick) Cheney

-----Original Message-----From: EOHarm [mailto:EOHarm ]On Behalf Of J. KrakowSent: Sunday, May 07, 2006 2:31 PMEOHarm Subject: Re: Re: Aluminium up?Yes, the program is flawed. That's their DIRTY LITTLE SECRET.The only it way it works-with vaccines as they currently exist- is by poisoning people. Some it poisons a little and they seem ok. Some never recover.On May 7, 2006, at 2:15 PM, H wrote:

So..., if we don't poison ourselves, we don't get antigenicity.This is the best that can be done??If this is true, then the whole vaccine program is totally flawed.

[Guest guest]

Take a look at the MSDS for silver nitrate. It doesn't sound like it should be used in the eyes at all! On page 4 (of 7), of the MSDS, it mentions that silver nitrate is incompatible with thimerosal. Aasa http://www.sciencelab.com/xMSDS-Silver_nitrate-9927411 barb beaudot <mnkygrl9@...> wrote: they no longer use silver nitrate drops. instead they use erythromycinan-an antibiotic. my first child had them and had a goopy eye for a month afterward. i heard that because the drops cloud the baby's vision, it can interfere with the bonding process. in australia they do not routinely give babies the eyedrops. that's how "important" it is.Holly <inticci@...>

wrote: Hi Group,My friend who is a nurse said with the removal of mercury the amount of Al was increased. Anyone know if this is true? Also she said when babies are born in the hospital it is automatic procedure to put silver drops in their eyes(my guess similiar to collodial silver) just in case mom has syphillis or ghonerria. Anyone know about this as well. Holly Get amazing travel prices for air and hotel in one click on FareChase

[Guest guest]

Had to check out what ie said....his usual BS...remember this one?

http://pediatrics.aappublications.org/cgi/content/full/112/6/1394

Right arrow Infectious Disease & Immunity

PEDIATRICS Vol. 112 No. 6 December 2003, pp. 1394-1397

SPECIAL ARTICLE

Addressing Parents' Concerns: Do Vaccines Contain Harmful

Preservatives, Adjuvants, Additives, or Residuals?

A. Offit, MD* and Rita K. Jew, PharmD{ddagger}

* Division of Infectious Diseases, Children's Hospital of

Philadelphia, University of Pennsylvania School of Medicine, and

Wistar Institute of Anatomy and Biology, Philadelphia, Pennsylvania

{ddagger} Department of Pharmacy, Children's Hospital of Philadelphia,

Philadelphia, Pennsylvania

ABSTRACT

TOP

ABSTRACT

PRESERVATIVES

ADJUVANTS

ADDITIVES

MANUFACTURING RESIDUALS

CONCLUSION

REFERENCES

Vaccines often contain preservatives, adjuvants, additives, or

manufacturing residuals in addition to pathogen-specific immunogens.

Some parents, alerted by stories in the news media or information

contained on the World Wide Web, are concerned that some of the

substances contained in vaccines might harm their children. We

reviewed data on thimerosal, aluminum, gelatin, human serum albumin,

formaldehyde, antibiotics, egg proteins, and yeast proteins. Both

gelatin and egg proteins are contained in vaccines in quantities

sufficient to induce rare instances of severe, immediate-type

hypersensitivity reactions. However, quantities of mercury, aluminum,

formaldehyde, human serum albumin, antibiotics, and yeast proteins in

vaccines have not been found to be harmful in humans or experimental

animals.

Key Words: vaccine safety • thimerosal • aluminum • formaldehyde •

gelatin • egg proteins • yeast proteins

Abbreviations: FDA, Food and Drug Administration • DTaP,

diphtheria-tetanus-acellular pertussis • Hib, Haemophilus influenzae

type B • EPA, Environmental Protection Agency • ATSDR, Agency for

Toxic Substances Disease Registry • MMR, measles-mumps-rubella • IgE,

immunoglobulin E • CJD, Creutzfeld- disease • BSE, bovine

spongiform encephalopathy • vCJD, variant Creutzfeld- disease

Vaccines contain live viruses, killed viruses, purified viral

proteins, inactivated bacterial toxins, or bacterial polysaccharides.

In addition to these immunogens, vaccines often contain other

substances. For example, vaccines may contain preservatives that

prevent bacterial or fungal contamination (eg, thimerosal); adjuvants

that enhance antigen-specific immune responses (eg, aluminum salts);

or additives that stabilize live, attenuated viruses (eg, gelatin,

human serum albumin). Furthermore, vaccines may contain residual

quantities of substances used during the manufacturing process (eg,

formaldehyde, antibiotics, egg proteins, yeast proteins).

Some parents, alerted by stories in the news media or on the World

Wide Web, are concerned that substances such as thimerosal,

formaldehyde, aluminum, antibiotics, and gelatin are harmful. We

review safety data obtained from human exposure and experimental

animal studies that address these concerns.

PRESERVATIVES

TOP

ABSTRACT

PRESERVATIVES

ADJUVANTS

ADDITIVES

MANUFACTURING RESIDUALS

CONCLUSION

REFERENCES

Preservatives are used in some vaccines to prevent bacterial or fungal

contamination. The requirement for preservatives in vaccines arose

from many incidents in the early 20th century of children who

developed severe and occasionally fatal bacterial infections after

administration of vaccines contained in multidose vials.1 For example,

in 1916, 4 children died, 26 developed local abscesses, and 68

developed severe systemic infections after receipt of a typhoid

vaccine contaminated with Staphylococcus aureus.1 As a consequence of

this and similar incidents, preservatives have been required for

vaccines contained in multidose vials (with some exceptions) since the

1930s.2

Three preservatives are used in vaccines licensed in the United

States: phenol, 2-phenoxyethanol, and thimerosal (Table 1).

Thimerosal, a mercury-containing preservative, has been the focus of

intense scrutiny by the US Congress and the news media after its

removal from most childhood vaccines in 2001. Attention by the news

media has caused some parents to fear that thimerosal contained in

vaccines might harm their children.

View this table:

[in this window]

[in a new window]

TABLE 1. Preservative Content in Vaccines Licensed in the United

States, 2003

Removal of thimerosal from vaccines was precipitated by an amendment

to the Food and Drug Administration (FDA) Modernization Act, which was

signed into law on November 21, 1997.3 The amendment gave the FDA 2

years to " compile a list of drugs and foods that contain intentionally

introduced mercury compounds and ... [to] provide a quantitative and

qualitative analysis of the mercury compounds in the list... . " The

amendment arose from a long-standing interest in lessening human

exposure to mercury, a known neurotoxin and nephrotoxin.

At the time the FDA Modernization Act was passed, it was recommended

that infants receive 3 different vaccines that contained thimerosal:

diphtheria-tetanus-acellular pertussis (DTaP), hepatitis B, and

Haemophilus influenzae type B (Hib). Infants who received all of these

vaccines could have been exposed to a cumulative dose of mercury as

high as 187.5 µg by 6 months of age.4 This value exceeded guidelines

recommended by the Environmental Protection Agency (EPA) but did not

exceed those recommended by the Agency for Toxic Substances Disease

Registry (ATSDR) or the FDA (Table 2).4 Therefore, thimerosal was

removed from most childhood vaccines by 2001 as a precautionary measure.5

View this table:

[in this window]

[in a new window]

TABLE 2. Exposure Limits for Mercury in Infants & #8804;6 Months of Age by

Percentile Body Weight Established by the EPA, the ATSDR, and the FDA

Although no published studies to date have compared the incidence of

neurodevelopmental delay in children who received thimerosal-free or

thimerosal-containing vaccines, several facts are reassuring that the

level of mercury contained in vaccines was not likely to be harmful.

Thimerosal contains 49.6% mercury by weight and is metabolized to

ethylmercury and thiosalicylate. Ethylmercury is contained in many

drugs as well as biologicals. Adults and children who are exposed

inadvertently to large quantities of ethylmercury acutely (quantities

1000- to 1 000 000-fold greater than those found in vaccines) can

sustain permanent neurologic damage and death.6–11 However, no data

exist on the capacity of low-dose, chronic exposure to ethylmercury to

harm the developing nervous system. Guidelines for chronic exposure to

ethylmercury were extrapolated from guidelines for methylmercury (the

most common form of mercury found in the environment) established by

the EPA, ATSDR, and FDA.4

Guidelines from the EPA were based in part on data from pregnant women

in rural Iraq who were exposed to large quantities of methylmercury.12

In October 1971, Iraq imported >90 000 metric tons of

methylmercury-treated seed grain. The grain, distributed free of

charge to farmers throughout the country, was used to make bread.

Consumption of this bread caused an extensive outbreak of

methylmercury poisoning, resulting in >6000 hospitalizations and 450

deaths. By examining the quantity of methylmercury contained in hair

from mothers who ingested methylmercury and comparing calculated

exposures to methylmercury with the frequency of neurologic symptoms

in their offspring (eg, psychomotor retardation, seizures, impaired

vision or hearing), a dose-response curve for fetal exposure to

methylmercury and neurologic damage was established. The EPA

determined guidelines by taking the lowest quantity of methylmercury

that might have resulted in harm to the fetus, bracketing that dose

with 95% confidence intervals and dividing the lower confidence

interval by an " uncertainty " factor of 10.4

By using data from pregnant women in Iraq who were exposed to

methylmercury in the environment to establish guidelines for chronic

exposure of infants in the United States to ethylmercury in vaccines,

2 important assumptions were made: 1) that the toxicity and

pharmacokinetics of methylmercury are the same as those of

ethylmercury and 2) that the central nervous systems of the fetus and

newborn are equally susceptible to the harmful effects of mercury.

However, the pharmacokinetics of ethylmercury and methylmercury are

not the same. Methylmercury has a biological half-life in blood of

approximately 50 days compared with that of approximately 7 days for

ethylmercury.4,13 Because ethylmercury is excreted from the body far

more quickly than methylmercury, cumulative dose guidelines would be

very different. In support of this important difference, Pichichero et

al13 found that the level of mercury detected in the blood of 40

full-term infants who were 6 months of age or younger and received

thimerosal-containing DTaP, hepatitis B, and Hib vaccines did not

exceed recommended guidelines.13 Furthermore, the developing central

nervous system of the fetus is more susceptible to environmental and

toxic insults than that of the newborn.14–17

Removal of thimerosal from most vaccines caused several unanticipated

consequences. First, before the availability of thimerosal-free DTaP,

hepatitis B, and Hib vaccines, hospitals were advised to defer the

birth dose of hepatitis B vaccine to 2 to 6 months of age in infants

of hepatitis B-seronegative mothers.18 Some hospitals misinterpreted

this guideline and suspended administration of the birth dose of

hepatitis B vaccine for all newborns.19–21 As a consequence, 1

institution reported that 3 infants of hepatitis B-seropositive

mothers did not receive the recommended birth dose of hepatitis B

vaccine.22 Another institution reported the death from acute hepatitis

B-induced liver failure of a 3-month-old infant who was born to a

hepatitis B-seropositive mother; the infant did not receive the

hepatitis B vaccine.19 Furthermore, although thimerosal-free vaccines

are now available, many hospitals continue to defer the birth dose of

hepatitis B vaccine inappropriately.19–21 Second, the removal of

thimerosal from vaccines caused some parents and physicians to believe

that vaccines that contain thimerosal were harmful, independent of

dose or age of administration. For example, although contrary to

recommendations by the Centers for Disease Control and Prevention,23

some parents and physicians were hesitant to give any

thimerosal-containing vaccines to children (eg, influenza vaccine to

children at high risk of severe influenza infection). Third, although

thimerosal was removed from vaccines in part to " maintain the public's

trust in immunization, " some physicians found that parents were less

confident in professional groups that recommended vaccines before than

after removal of thimerosal.24

ADJUVANTS

TOP

ABSTRACT

PRESERVATIVES

ADJUVANTS

ADDITIVES

MANUFACTURING RESIDUALS

CONCLUSION

REFERENCES

Aluminum salts are the only adjuvants currently licensed for use in

the United States (Table 3). Aluminum salts include aluminum

hydroxide, aluminum phosphate, and potassium aluminum sulfate (alum).

Aluminum-containing vaccines are prepared by adsorption of antigens

onto aluminum hydroxide or aluminum phosphate gels or by precipitation

of antigens in a solution of alum.25

View this table:

[in this window]

[in a new window]

TABLE 3. Aluminum Salt (Adjuvant) Content in Vaccines Licensed in

the United States, 2003

Aluminum salts were found initially to enhance immune responses after

immunization with diphtheria and tetanus toxoids in studies performed

in the 1930s, 1940s, and 1950s.26–30 Early studies suggested that

aluminum salts reduced the rate of elimination of antigens at the site

of inoculation (ie, depot effect).31 However, subsequent studies

questioned the importance of the depot effect and found that aluminum

salts enhanced antigen uptake by antigen-presenting cells (eg,

dendritic cells),32 activated antigen-presenting cells,32 or induced

production of cytokines33 and complement.34 The importance of each of

these mechanisms in enhancing antigen-specific immune responses

remains unclear.

The safety of aluminum has been established by experience during the

past 70 years, with hundreds of millions of people inoculated with

aluminum-containing vaccines. Adverse reactions including erythema,

subcutaneous nodules, contact hypersensitivity, and granulomatous

inflammation have been observed rarely.35

Aluminum-containing vaccines are not the only source of aluminum

exposure for infants. Because aluminum is 1 of the most abundant

elements in the earth's crust and is present in air, food, and water,

all infants are exposed to aluminum in the environment. For example,

breast milk contains approximately 40 µg of aluminum per liter, and

infant formulas contain an average of approximately 225 µg of aluminum

per liter.36–40 Vaccines contain quantities of aluminum similar to

those contained in infant formulas (Table 3). However, because large

quantities of aluminum can cause serious neurologic effects in

humans,41 guidelines were established by the ATSDR.

For determining the quantity of aluminum below which safety is likely,

data were generated in mice that were inoculated orally with various

quantities of aluminum lactate.42 No adverse reactions were observed

when mice were fed quantities of aluminum as high as 62 mg/kg/day. By

applying uncertainty factors of 3 (for extrapolation to humans) and 10

(for human variability), the ATSDR concluded that the minimum risk

level for exposure to aluminum was 2 mg/kg/day.43 The half-life of

elimination of aluminum from the body is approximately 24 hours.41

Therefore, the burden of aluminum to which infants are exposed in

food36–40 and vaccines (Table 3) is clearly less than the guideline

established by the ATSDR and far less than that found to be safe in

experimental animals.41,42

ADDITIVES

TOP

ABSTRACT

PRESERVATIVES

ADJUVANTS

ADDITIVES

MANUFACTURING RESIDUALS

CONCLUSION

REFERENCES

Additives are used to stabilize vaccines from adverse conditions such

as freeze-drying or heat. In addition, additives are added to vaccines

to prevent immunogens from adhering to the side of the vial. The types

of stabilizers used in vaccines include sugars (eg, sucrose, lactose),

amino acids (eg, glycine, monosodium salt of glutamic acid), and

proteins (eg, gelatin or human serum albumin).

Three issues surround the use of protein additives in vaccines: 1) the

observation that immediate-type hypersensitivity reactions are a rare

consequence of receiving gelatin-containing vaccines, 2) the

theoretical concern that human serum albumin might contain infectious

agents, and 3) the theoretical concern that bovine-derived materials

used in vaccines might contain the agent associated with bovine

spongiform encephalopathy ( " mad-cow " disease).

Hypersensitivity to Gelatin

In 1993, Kelso et al44 reported the case of a 17-year-old girl in

California who developed profuse rhinorrhea, hives, laryngotracheal

edema, lightheadedness, and a blood pressure of 70/50 within 5 minutes

of receiving a measles-mumps-rubella (MMR) vaccine. Her symptoms

resolved after treatment with epinephrine and diphenhydramine. When

later describing the event, the girl stated that it was " kind of like

what happens when I eat Jell-O. " 44 Subsequent testing found that the

only component of the vaccine to which the patient was allergic was

gelatin.

Before 1993, immediate-type hypersensitivity reactions to the MMR

vaccine were attributed to an allergy to egg proteins.45 This

assumption was based on the fact that both the measles and mumps

components of MMR vaccine are grown in chick embryo fibroblast cells.

However, most patients with hypersensitivity to MMR vaccine were not

allergic to eggs.44 The observation by Kelso et al prompted a closer

look at the capacity of gelatin-containing vaccines to induce

hypersensitivity reactions.

Studies in Japan confirmed the findings of Kelso et al that immediate

hypersensitivity to MMR vaccine was associated with the presence of

gelatin-specific immunoglobulin E (IgE),46 not an allergy to egg

proteins. At that time, the rate of immediate hypersensitivity to MMR

in Japan was approximately 20-fold higher than that in the United

States.47,48 The increased incidence of immediate-type

hypersensitivity to gelatin in Japan was explained in 2 ways. First,

DTaP vaccines made in Japan contained gelatin, whereas DTaP vaccines

made in the United States did not.48 Second, the type of gelatin used

in Japan was not hydrolyzed.48 Hydrolysis converts high molecular

weight gelatin (>100 000 Da) to low molecular weight gelatin (between

2000 and 5000 Da). Low molecular weight gelatin is less likely to

stimulate gelatin-specific IgE than high molecular weight gelatin.49

When Japanese vaccine makers eliminated gelatin from DTaP and switched

to the use of hydrolyzed gelatin in the MMR vaccine, the incidence of

gelatin-specific immediate-type hypersensitivity reactions decreased

dramatically to levels similar to those found in the United States.50

Although the incidence of anaphylaxis to gelatin is currently very low

(approximately 1 case per 2 million doses), gelatin is the most common

identifiable cause of immediate-type hypersensitivity reactions to

gelatin-containing vaccines.51,52 A list of vaccines that contain

gelatin is provided in Table 4 (all gelatin is of porcine origin).

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TABLE 4. Gelatin Content of Vaccines Licensed in the United States,

2003

Some patients with immediate hypersensitivity reactions to gelatin

have a history of allergies to gelatin-containing foods.51 This is

explained, in part, by the extensive cross-reactivity found between

bovine gelatin contained in many foods and porcine gelatin contained

in vaccines.53 Therefore, it would be of value to ask about food

allergies before vaccination with gelatin-containing vaccines.54 If

children have either a history of food allergy to gelatin or a history

of immediate-type hypersensitivity reactions to gelatin-containing

vaccines, then gelatin-containing vaccines should not be administered

and an immunologic evaluation should be performed.54 Evaluation may

include either detection of gelatin-specific IgE by solid-phase

immunoassay or skin testing with increasing concentrations of

gelatin.54 Vaccination of people who have immunologic evidence for

gelatin hypersensitivity should be performed with the ready

availability of equipment and medications required for the treatment

of anaphylactic reactions or deferred completely.

Theoretical Risk of Infectious Agents in Human Serum Albumin

Human serum albumin (0.3 mg/dose) is contained in measles vaccine

(Attenuvax; Merck and Co, West Point, PA); mumps vaccine (Mumpsvax;

Merck and Co); rubella vaccine (Meruvax; Merck and Co); and measles,

mumps, and rubella vaccine (MMRII; Merck and Co). Because human serum

albumin is derived from human blood, there is a theoretical risk that

it might contain infectious agents. However, the FDA requires that

human serum albumin be derived from blood of screened donors and be

manufactured in a manner that would eliminate the risk of transmission

of all known viruses. The result is that no viral diseases have ever

been associated with the use of human serum albumin.

Theoretical Risk of " Mad-Cow " Disease From Bovine-Derived Reagents

Creutzfeld- disease (CJD) in humans is caused by a unique

infectious agent (proteinaceous infectious particles, or prions) that

also causes encephalopathies in other mammals such as cows (bovine

spongiform encephalopathy [bSE]) and sheep (scrapie).55 Between 1995

and 1997, a new " variant " form of CJD (vCJD) in humans was reported

from the United Kingdom after an outbreak of BSE in cows.56–60 The

timing of these events raised the possibility that people who ate

products from cows that were infected with BSE developed vCJD. Several

epidemiologic, clinical, and pathologic features of vCJD supported a

causal link between BSE and vCJD.55,61–64

Vaccines contain several reagents that are derived from cows (eg,

gelatin, glycerol, enzymes, serum, amino acids). Because of concerns

about vCJD, the FDA recently prohibited the use of bovine-derived

materials obtained from countries that are known to have cattle that

are infected with BSE.65 However, before this ban, some materials used

in vaccines might have been obtained from cows that were infected with

BSE in England. (It should be noted that US vaccine manufacturers were

not allowed to use bovine products imported from outside the United

States to protect against the possible importation of foot-and-mouth

disease). This raised the question of whether children who were

inoculated with vaccines were at risk for vCJD. Newspapers reported

this possibility in the late 1990s,66 and some parents were concerned

about bovine-derived products contained in vaccines. However, several

epidemiologic observations and features of the manufacturing process

should reassure parents that vaccines could not cause vCJD. First,

prions are detected in the brain, spinal cord, and retina of cows with

BSE and not in blood or other organs.55 Therefore, serum (present in

media that support the growth of microorganisms or cells used to make

vaccines) is not likely to contain prions. Consistent with these

observations, no cases of CJD have been transmitted by blood or blood

products, and a history of blood transfusion does not increase the

risk for CJD.67–69 Second, prions are not detected in connective

tissue of cows with BSE.55 Therefore, gelatin (made by boiling the

hooves and skin of pigs or cows) is unlikely to contain prions. Third,

epidemiologic evidence does not support vaccines as a cause of vCJD in

England.70 Human exposure to cows that were infected with BSE in

England was likely to have occurred after 1983, and vaccines that

contained bovine-derived materials were likely to have been

administered to children after 1985. If vaccines that are routinely

administered in the first 2 years of life caused vCJD, then no cases

of vCJD would have been expected to occur in people who were born

before 1985. However, all cases of vCJD occurred in people born who

were before 1985 and half before 1970.70

MANUFACTURING RESIDUALS

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ABSTRACT

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MANUFACTURING RESIDUALS

CONCLUSION

REFERENCES

Residual quantities of reagents that are used to make vaccines are

clearly defined and well regulated by the FDA. Inactivating agents

(eg, formaldehyde), antibiotics, and cellular residuals (eg, egg and

yeast proteins) may be contained in the final product.

Inactivating Agents

Inactivating agents separate a pathogen's immunogenicity from its

virulence by eliminating the harmful effects of bacterial toxins or

ablating the capacity of infectious viruses to replicate. Examples of

inactivating agents include formaldehyde, which is used to inactivate

influenza virus, poliovirus, and diphtheria and tetanus toxins;

ß-propiolactone, which is used to inactivate rabies virus; and

glutaraldehyde, which is used to inactivate toxins contained in

acellular pertussis vaccines. Formaldehyde deserves special consideration.

Concerns about the safety of formaldehyde have centered on the

observation that high concentrations of formaldehyde can damage DNA

and cause cancerous changes in cells in vitro.71,72 Although

formaldehyde is diluted during the manufacturing process, residual

quantities of formaldehyde may be found in several current vaccines

(Table 5). Fortunately, formaldehyde does not seem to be a cause of

cancer in humans,73 and animals that are exposed to large quantities

of formaldehyde (a single dose of 25 mg/kg or chronic exposure at

doses of 80–100 mg/kg/day) do not develop malignancies.74,75

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TABLE 5. Formaldehyde Content of Vaccines Licensed for Use in the

United States, 2003

The quantity of formaldehyde contained in individual vaccines does not

exceed 0.1 mg (Table 5). This quantity of formaldehyde is considered

to be safe for 2 reasons. First, formaldehyde is an essential

intermediate in human metabolism and is required for the synthesis of

thymidine, purines, and amino acids.76 Therefore, all humans have

detectable quantities of formaldehyde in their circulation

(approximately 2.5 µg of formaldehyde/mL of blood).77 Assuming an

average weight of a 2-month-old of 5 kg and an average blood volume of

85 mL/kg, the total quantity of formaldehyde found naturally in an

infant's circulation would be approximately 1.1 mg—a value at least

10-fold greater than that contained in any individual vaccine. Second,

quantities of formaldehyde at least 600-fold greater than that

contained in vaccines have been given safely to animals.74,75

Antibiotics

Antibiotics are present in some vaccines to prevent bacterial

contamination during the manufacturing process. Because antibiotics

can cause immediate-type hypersensitivity reactions in children,78,79

some parents are concerned that antibiotics that are contained in

vaccines might be harmful. However, antibiotics that are most likely

to cause immediate-type hypersensitivity reactions (eg, penicillins,

cephalosporins, sulfonamides)78,79 are not contained in vaccines.

Antibiotics that are used during vaccine manufacture include neomycin,

streptomycin, polymyxin B, chlortetracyline, and amphotericin B. Only

neomycin is contained in vaccines in detectable quantities (Table 6).

However, immediate-type hypersensitivity reactions to the small

quantities of neomycin contained in vaccines has not been clearly

documented.80,81 Although neomycin-containing products have been found

to cause delayed-type hypersensitivity reactions,82,83 these reactions

are not a contraindication to receiving vaccines.

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TABLE 6. Neomycin Content in Vaccines Licensed for Use in the

United States, 2003

Cellular Residuals

Egg Proteins

Egg allergies occur in approximately 0.5% of the population and in

approximately 5% of atopic children.84 Because influenza and yellow

fever vaccines both are propagated in the allantoic sacs of chick

embryos (eggs), egg proteins (primarily ovalbumin) are present in the

final product. Residual quantities of egg proteins found in the

influenza vaccine (approximately 0.02–1.0 µg/dose) are sufficient to

induce severe and rarely fatal hypersensitivity reactions in children

with egg allergies.85,86 Unfortunately, children with egg allergies

also have other diseases (eg, asthma) that are associated with a high

risk of severe and occasionally fatal influenza infection.87,88 For

this reason, children who have egg allergies and are at high risk of

severe influenza infection should be given influenza vaccine via a

strict protocol.86–90

In contrast to influenza vaccine, measles and mumps vaccines are

propagated in chick embryo fibroblast cells in culture. The quantity

of residual egg proteins found in measles- and mumps-containing

vaccines is approximately 40 pg—a quantity at least 500-fold less than

those found for influenza vaccines.91 The quantity of egg proteins

found in measles- and mumps-containing vaccines is not sufficient to

induce immediate-type hypersensitivity reactions, and children with

severe egg allergies can receive these vaccines safely.92

Yeast Proteins

Hepatitis B vaccines are made by transfecting cells of Saccharomyces

cerevisiae (baker's yeast) with the gene that encodes hepatitis B

surface antigen, and residual quantities of yeast proteins are

contained in the final product. Engerix-B (GlaxoKline, Research

Triangle Park, NC) contains no more than 5 mg/mL and Recombivax HB

(Merck and Co) contains no more than 1 mg/mL yeast proteins.

Immediate-type hypersensitivity reactions have been observed rarely

after receipt of hepatitis B vaccine (approximately 1 case per 600 000

doses).93 However, yeast-specific IgE has not been detected in

patients with immediate-type hypersensitivity94–96 or in nonallergic

patients97 after receipt of hepatitis B vaccine. Therefore, the risk

of anaphylaxis after receipt of hepatitis B vaccine as a result of

allergy to baker's yeast is theoretical.

CONCLUSION

TOP

ABSTRACT

PRESERVATIVES

ADJUVANTS

ADDITIVES

MANUFACTURING RESIDUALS

CONCLUSION

REFERENCES

Parents should be reassured that quantities of mercury, aluminum, and

formaldehyde contained in vaccines are likely to be harmless on the

basis of exposure studies in humans or experimental studies in

animals. Although severe anaphylactic reactions may occur rarely after

receipt of vaccines that contain sufficient quantities of egg proteins

(eg, influenza, yellow fever) or gelatin (eg, MMRII), children who are

at risk for severe infection with influenza can be desensitized to

influenza vaccine, and gelatin-specific allergies are very rare.

Immediate-type hypersensitivity reactions to neomycin or yeast

proteins have not been clearly documented and remain theoretical.

ACKNOWLEDGMENTS

Some vaccines discussed in this article are manufactured by Merck and

Co. Dr Offit is the co-holder of a patent on a bovine-human

reassortant rotavirus vaccine that is being developed by Merck. Dr

Offit's laboratory support comes from the National Institutes of

Health, and he does not receive personal support or honoraria from

Merck and does not have a financial interest in the company.

FOOTNOTES

Received for publication Feb 20, 2003; Accepted May 1, 2003.

Reprint requests to (P.A.O.) Division of Infectious Diseases,

Children's Hospital of Philadelphia, Abramson Research Building, Rm

1202C, 34th St and Civic Center Blvd, Philadelphia, PA 19104. E-mail:

offit@...

REFERENCES

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ABSTRACT

PRESERVATIVES

ADJUVANTS

ADDITIVES

MANUFACTURING RESIDUALS

CONCLUSION

REFERENCES

1. GS. The Hazards of Immunization. New York, NY: The

Althone Press; 1967:75–84

2. General Biologics Product Standards; Constituent materials.

Ingredients, preservatives, diluents, and adjuvants. 21 CFR: 610.15 (a)

3. 21 USC 397 Section 413

4. Stratton K, Gable A, McCormick MC, eds. Immunization Safety

Review: Thimerosal-Containing Vaccines and Neurodevelopmental

Disorders. Washington, DC: National Academy Press; 2001

5. Goldstein BD. The precautionary principle also applies to public

health actions. Am J Public Health.2001; 91 :1358 –1361[Abstract/Free

Full Text]

6. Hay WJ, Rickerts AG, McMenemey WH, Cumings JN. Organic mercurial

encephalopathy. Neurol Neurosurg Psychiatry.1963; 26 :199 –202

7. Axton JHM. Six cases of poisoning after a parenteral organic

mercury compound (Merthiolate). Postgrad Med J.1972; 48 :417

–421[iSI][Medline]

8. Fagan DG, Pritchard JS, son TW, Greenwood MR. Organ mercury

levels in infants with omphaloceles treated with organic mercury

antiseptic. Arch Dis Child.1977; 52 :962 –964[Abstract]

9. Cinca I, Dumitrescu I, Onaca P, et al. Accidental ethyl mercury

poisoning with nervous system, skeletal muscle, and myocardium injury.

J Neurol Neurosurg Psychiatry.1979; 43 :143 –149[iSI]

10. Rohyans J, Walson PD, Wood GA, Mac WA. Mercury toxicity

following merthiolate ear irrigations. J Pediatr.1984; 104 :311

–313[iSI][Medline]

11. Pfab R, Muckter H, Roider G, Zilker T. Clinical course of severe

poisoning with thiomersal. Clin Toxicol.1996; 34 :453 –460

12. Marsh DO, son TW, C, et al. Fetal methylmercury

poisoning: relationship between concentration in single strands of

maternal hair and child effects. Arch Neurol.1987; 44 :1017

–1022[Abstract]

13. Pichichero ME, Cernichiari E, Lopreiato J, Treanor J. Mercury

concentrations and metabolism in infants receiving vaccines containing

thiomersal: a descriptive study. Lancet.2002; 360 :1737

–1741[CrossRef][iSI][Medline]

14. Strömland K, Nordin V, M, et al. Autism in thalidomide

embryopathy: a population study. Dev Med Child Neurol.1994; 36 :351

–356[iSI][Medline]

15. Rodier PM. The early origins of autism. Sci Am.2000; February

:56 –63

16. Chess S, Fernandez P, Korn S. Behavioral consequences of

congenital rubella. J Pediatr.1978; 93 :699 –703[iSI][Medline]

17. Deykin EY, MacMahon B. Viral exposure and autism. Am J

Epidemiol.1979; 109 :628 –638[Abstract/Free Full Text]

18. American Academy of Pediatrics. Committee on Infectious Diseases

and Committee on Environmental Health. Thimerosal in vaccines—an

interim report to clinicians. Pediatrics.1999; 104 :570 –574[Free Full

Text]

19. Centers for Disease Control and Prevention. Impact of the 1999

AAP/USPHS joint statement on thimerosal in vaccines on infant

hepatitis B vaccination practices. MMWR Morb Mortal Wkly Rep.2001; 50

:94 –97[Medline]

20. Hurie MB, Saari TN, JP. Impact of the joint statement by

the American Academy of Pediatrics/US Public Health Service on

thimerosal in vaccines on hospital infant hepatitis B vaccination

practices. Pediatrics.2001; 107 :755 –758[Abstract/Free Full Text]

21. Brayden RM, Pearson KA, JS, et al. Effect of thimerosal

recommendations on hospitals' neonatal hepatitis B vaccination

policies. J Pediatr.2001; 138 :752 –755[CrossRef][iSI][Medline]

22. B. Comment. In: Transcript of the National Vaccine

Advisory Committee Workshop on Thimerosal in Vaccines. Bethesda, MD:

US Government Printing Office; August 12, 1999

23. Centers for Disease Control and Prevention. Recommendations

regarding the use of vaccines that contain thimerosal as a

preservative. MMWR Morb Mortal Wkly Rep.1999; 48 :996 –998[Medline]

24. Freed GL, e M. Presentation to Immunization Safety Review

Committee. History of Thimerosal Concern and Comparative Policy

Actions; Cambridge, Massachusetts; July 16, 2001

25. Shirodkar S, Hutchinson RL, DL, et al. Aluminum compounds

used as adjuvants in vaccines. Pharm Res.1990; 7 :1282

–1288[CrossRef][iSI][Medline]

26. Glenny AT, Pope CG, Waddington H, Wallace U. The antigenic value

of toxoid precipitated by potassium alum. J Pathol Bacteriol.1926; 29

:38 –39

27. Volk VK, Bunney WE. Diphtheria immunization with fluid toxoid

and alum-precipitated toxoid. Am J Public Health.1942; 32 :690 –699

28. Barr M, Glenney AT, Hignett S, et al. Antigenic efficiency of

fluid and precipitated diphtheria prophylactics in very young babies

and lambs. Lancet.1952; 2 :803 –805[iSI][Medline]

29. Barr M, Glenny AT, NR. Immunization of babies with

diphtheria-tetanus-pertussis prophylactic. Br Med J.1955; 2 :635 –639

30. Greenberg L, Benoit R. Control of potency and the dosage of

diphtheria and tetanus toxoids. JAMA.1956; 160 :108 –113[iSI]

31. Glenny AT, AH, s MF. Rate of disappearance of

diphtheria toxoid injected into rabbits and guinea pigs: toxoid

precipitated with alum. J Pathol Bacteriol.1931; 34 :267 –275[CrossRef]

32. Mannhalter JW, Neychev HO, Zlabinger GJ, et al. Modulation of

the immune response by the non-toxic and non-pyrogenic adjuvant

aluminum hydroxide: effect on antigen uptake and antigen presentation.

Clin Exp Immunol.1985; 61 :143 –151[iSI][Medline]

33. Ulanova M, Tarkowsi A, Hahn-Zoric M, Hanson LA. The common

vaccine adjuvant aluminum hydroxide upregulates accessory properties

of human monocytes via an interleukin-4-dependent mechanism. Infect

Immun.2001; 69 :1151 –1159[Abstract/Free Full Text]

34. Ramanathan VD, Badenoch- P, Turk JL. Complement activation

by aluminum and zirconium compounds. Immunology.1979; 37 :881

–888[iSI][Medline]

35. Gupta RK, Rost BE, Relyveld E, Siber GR. Adjuvant properties of

aluminum and calcium compounds. In: MF, Newman MJ, eds. Vaccine

Design: The Subunit and Adjuvant Approach. New York, NY: Plenum Press;

1995:229–248

36. Koo WWK, Kaplan LA, Krug-Wispe SK. Aluminum contamination of

infant formulas. J Parenteral Nutr.1988; 12 :170 –173[iSI]

37. Weintraub R, Hams G, Meerkin M, Rosenberg AR. High aluminum

content of infant milk formulas. Arch Dis Child.1986; 61 :914

–916[Abstract]

38. Simmer K, Fudge A, Teubner J, SL. Aluminum concentrations

in infant milk formulae. J Paediatr Child Health.1990; 26 :9

–11[iSI][Medline]

39. Hawkins NM, Coffey S, Lawson MS, Delves HT. Potential aluminum

toxicity in infants fed special infant formula. J Paediatr

Gastroenterol Nutr.1994; 19 :377 –381[iSI][Medline]

40. Mandic ML, Grgic J, Grgic Z, et al. Aluminum levels in human

milk. Sci Total Environ.1995; 170 :165 –170[CrossRef][iSI][Medline]

41. LS, DE, Chou C. Aluminum toxicokinetics regarding

infant diet and vaccination. Vaccine.2002; 20 :S13 –S17[CrossRef][Medline]

42. Golub MS, JM, Gershwin ME, Keen CL. Effects of aluminum

ingestion on spontaneous motor activity of mice. Neurotoxicol

Teratol.1989; 11 :231 –235[CrossRef][iSI][Medline]

43. Toxicological Profile for Aluminum. Atlanta, GA: US Department

of Health and Human Services, Public Health Service, Agency for Toxic

Substances and Disease Registry; 1999

44. Kelso JM, RT, Yunginger JW. Anaphylaxis to measles, mumps,

and rubella vaccine mediated by IgE to gelatin. J Allergy Clin

Immunol.1993; 91 :867 –872[CrossRef][iSI][Medline]

45. Herman JJ, Radin R, Schneiderman R. Allergic reactions to

measles (rubeola) vaccine in patients hypersensitive to egg proteins.

J Pediatr.1983; 102 :196 –199[iSI][Medline]

46. Sakaguchi M, Ogura H, Inouye S. IgE antibody to gelatin in

children with immediate-type reactions to measles and mumps vaccines.

J Allergy Clin Immunol.1995; 96 :563 –565[CrossRef][iSI][Medline]

47. Centers for Disease Control and Prevention. Update: vaccine side

effects, adverse reactions, contraindications, and precautions. MMWR

Morb Mortal Wkly Rep.1996; 45 :1 –35[Medline]

48. Sakaguchi M, Nakayama T, Fujita H, et al. Minimum estimated

incidence in Japan of anaphylaxis to live virus vaccines including

gelatin. Vaccine.2001; 19 :431 –436[CrossRef][iSI]

49. Sakai Y, Yamoto R, Onuma M, et al. Non-antigenic and low

allergic gelatin produced by specific digestion with enzyme-coupled

matrix. Biol Pharm Bull.1998; 21 :330 –334[iSI][Medline]

50. Nakayama T, Aizawa C. Change in gelatin content of vaccines

associated with reduction in reports of allergic reactions. J Allergy

Clin Immunol.2000; 106 :591 –592[CrossRef][iSI][Medline]

51. Sakaguchi M, Nakayama T, Inouye S. Food allergy to gelatin in

children with systemic immediate-type reactions, including

anaphylaxis, to vaccines. J Allergy Clin Immunol.1996; 98 :1058

–1061[CrossRef][iSI][Medline]

52. Sakaguchi M, Yamanaka T, Ikeda K, et al. IgE-mediated systemic

reactions to gelatin included in the varicella vaccine. J Allergy Clin

Immunol.1997; 99 :263 –264[CrossRef][iSI][Medline]

53. Sakaguchi M, Hori H, Ebihara T, et al. Reactivity of the

immunoglobulin E in bovine gelatin-sensitive children to gelatins from

other animals. Immunology.1999; 96 :286 –290[CrossRef][iSI][Medline]

54. Centers for Disease Control and Prevention. General

recommendations on immunization: recommendations of the Advisory

Committee on Immunization Practices (ACIP) and the American Academy of

Family Physicians (AAFP). MMWR Morb Mortal Wkly Rep.2002; 51 :17

55. Tyler KL. Prions and prion diseases of the central nervous

system (transmissible neurodegenerative diseases). In Mandell GL,

JE, Dolin R, eds. Principles and Practices of Infectious

Diseases. Philadelphia, PA: Churchill Livingstone; 2000

56. Britton TC, Al-Sarraj S, Shaw C, et al. Sporadic

Creutzfeld- disease in a 16-year-old in the UK. Lancet.1995; 346

:1155[iSI][Medline]

57. Will RG, Ironside JW, Zeidler M, et al. A new variant of

Creutzfeld- disease in the UK. Lancet.1996; 347 :921

–925[CrossRef][iSI][Medline]

58. Zeidler M, GE, Barraclough CR, et al. New variant

Creutzfeld- disease: neurologic features and diagnostic tests.

Lancet.1997; 350 :903 –907[CrossRef][iSI][Medline]

59. Schonberger L. New variant Creutzfeld- disease and bovine

spongiform encephalopathy. Infect Dis Clin North Am.1998; 12 :111

–121[CrossRef][iSI][Medline]

60. RM, Donnelly CA, Ferguson NM, et al. Transmission

dynamics and epidemiology of BSE in British cattle. Nature.1996; 382

:779[CrossRef][iSI][Medline]

61. Delys J-P, Lasmexas CI, Streichenberger N, et al. New variant

Creutzfeld- disease in France. Lancet.1997; 349 :30

–31[CrossRef][iSI][Medline]

62. Collinge J, Sidle KCL, Meads J, et al. Molecular analysis of

prion strain variation and the aetiology of `new variant' CJD.

Nature.1996; 383 :685 –690[CrossRef][iSI][Medline]

63. Parchi P, Capellari S, Chen SG, et al. Typing prion isoforms.

Nature.1997; 386 :232[CrossRef][iSI][Medline]

64. Bruce ME, Will RG, Ironside JW, et al. Transmissions to mice

indicate that `new variant' CJD is caused by BSE agent. Nature.1997;

389 :498 –501[CrossRef][iSI][Medline]

65. Marwick C. FDA calls bovine-based vaccines currently safe.

JAMA.2000; 284 :1231 –1232[Free Full Text]

66. sen M, Winter G. 5 drug makers use material with possible

mad cow link. New York Times.2001; February 8 :C1

67. Brown P. Can Creutzfeld- disease be transmitted by

transfusion? Curr Opin Hematol.1995; 2 :472 –477[Medline]

68. S, Law MG, Fletcher A, et al. Surgical treatment and

risk of sporadic Creutzfeld- disease: a case-control study.

Lancet.1999; 353 :693 –697[CrossRef][iSI][Medline]

69. Esmonde TF, Will RG, Slattery JM, et al. Creutzfeld-

disease and blood transfusion. Lancet.1993; 341 :205

–207[CrossRef][iSI][Medline]

70. Minor PD, Will RG, Salisbury D. Vaccines and variant CJD.

Vaccine.2001; 19 :409 –410[CrossRef][iSI]

71. Goldmacher VS, Thilly WG. Formaldehyde is mutagenic for cultured

human cells. Mutat Res.1983; 116 :417 –422[CrossRef][iSI][Medline]

72. Ragan DL, Boreiko CJ. Initiation of C3H/10T1/2 cell

transformation by formaldehyde. Cancer Lett.1981; 13 :325

–331[CrossRef][iSI][Medline]

73. Epidemiology of chronic occupational exposure to formaldehyde:

report of the ad hoc panel on health aspects of formaldehyde. Toxicol

Ind Health.1988; 4 :77 –90[iSI][Medline]

74. Natarajan AT, Darroudi F, Bussman CJM, van Kesteren-van Leeuwen

AC. Evaluation of the mutagenicity of formaldehyde in mammalian

cytogenetic assays in vivo and in vitro. Mutat Res.1983; 122 :355

–360[CrossRef][iSI][Medline]

75. Til HP, Woutersen RA, Feron VJ, et al. Two-year drinking-water

study of formaldehyde in rats. Food Chem Toxicol.1989; 27 :77

–87[CrossRef][iSI][Medline]

76. Huennekens FM, Osborne MJ. Folic acid coenzymes and one-carbon

metabolism. Adv Enzymol.1959; 21 :369 –446[iSI]

77. Heck H, Casanova-Schmitz M, Dodd PB, et al. Formaldehyde (CH2O)

concentrations in the blood of humans and Fischer-344 rats exposed to

CH2O under controlled conditions. Am Ind Hyg Assoc J.1985; 46 :1

–3[iSI][Medline]

78. JA, Adkinson NF. Allergic reactions to drugs and

biologic agents. JAMA.1987; 258 :2891 –2899[Abstract]

79. Yunginger JW. Anaphylaxis. Curr Probl Pediatr.1992; 22 :130

–146[CrossRef][Medline]

80. Goh CL. Anaphylaxis from topical neomycin and bacitracin. Aust J

Dermatol.1986; 27 :125 –126

81. Kwittken PL, Rosen S, Sweinberg SK. MMR vaccine and neomycin

allergy. Am J Dis Child.1993; 147 :128 –129[iSI][Medline]

82. Leyden JJ, Kligman AM. Contact dermatitis to neomycin sulfate.

JAMA.1979; 242 :1276 –1278[Abstract]

83. Mac RH, Beck M. Neomycin: a review with particular

reference to dermatological usage. Clin Exp Dermatol.1983; 8 :249

–258[iSI][Medline]

84. Ratner B, Untracht S. Egg allergy in children. Am J Dis

Child.1952; 83 :309 –316[iSI]

85. Bierman CW, Shapiro GG, Pierson WE, et al. Safety of influenza

vaccination in allergic children. J Infect Dis.1977; 136 :S652

–S655[iSI][Medline]

86. JM, Zeiger RS, Lester MR, et al. Safe administration of

influenza vaccine to patients with egg allergy. J Pediatr.1998; 133

:624 –628[CrossRef][iSI][Medline]

87. Glezen WP. Serious morbidity and mortality associated with

influenza epidemics. Epidemiol Rev.1982; 4 :25 –44[Free Full Text]

88. Glezen WP, Greenberg SB, Atmar RL, et al. Impact of respiratory

virus infection on persons with underlying conditions. JAMA.2000; 283

:499 –505[Abstract/Free Full Text]

89. KR, Strunk RC. Safe administration of influenza vaccine

in asthmatic children hypersensitive to egg proteins. J Pediatr.1985;

106 :931 –933[CrossRef][iSI][Medline]

90. Zieger RS. Current issues with influenza vaccination in egg

allergy. J Allergy Clin Immunol.2002; 110 :834

–840[CrossRef][iSI][Medline]

91. Fasano MB, Wood RA, Cooke SK, Sampson HA. Egg hypersensitivity

and adverse reactions to measles, mumps, and rubella vaccine. J

Pediatr.1992; 120 :878 –881[iSI][Medline]

92. JM, Burks AW, Roberson PK, Sampson HA. Safe administration

of the measles vaccine to children allergic to eggs. N Engl J

Med.1995; 332 :1262 –1266[Abstract/Free Full Text]

93. Lear JT, English JS. Anaphylaxis after hepatitis B immunization.

Lancet.1995; 345 :1249

94. Hudson TJ, Newkirk M, Gervais F, Shuster J. Adverse reaction to

the recombinant hepatitis B vaccine. J Allergy Clin Immunol.1991; 88

:821 –822[CrossRef][iSI][Medline]

95. Barbaud A, Tréchot P, Reichert-Pénétrat S, et al. Allergic

mechanisms and urticaria/angioedema after hepatitis B immunization. Br

J Dermatol.1998; 139 :916 –941[CrossRef][iSI][Medline]

96. Brightman CA, Scadding GK, Dumbreck LA, et al. Yeast-derived

hepatitis B vaccine and yeast sensitivity. Lancet.1989; i :903

97. Wiederman G, Scheiner O, Ambrosch F, et al. Lack of induction of

IgE and IgG antibodies to yeast in humans immunized with recombinant

hepatitis B vaccines. Int Arch Allergy Appl Immunol.1988; 85 :130

–132[iSI][Medline]

PEDIATRICS (ISSN 1098-4275). ©2003 by the American Academy of Pediatrics

P3Rs:

Read all P3Rs

Parents' worries about thimerosal in vaccines are well founded!

Mark R. Geier, MD, Ph.D., et al.

Pediatrics Online, 12 Mar 2004 [Full text]

Re: Parents' worries about thimerosal in vaccines are well founded!

paul a offit, et al.

Pediatrics Online, 17 Mar 2004 [Full text]

Offit and Jew incorrect on 2003 Vaccination Schedules

S. Hooker

Pediatrics Online, 31 Mar 2004 [Full text]

response to brian hooker

A Offit, et al.

Pediatrics Online, 1 Apr 2004 [Full text]

> >>>> >

> >>>> > Hi Group,

> >>>> >

> >>>> > My friend who is a nurse said with the removal of mercury the

> >>>> amount

> >>>> > of Al was increased. Anyone know if this is true? Also

she said

> >>>> when

> >>>> > babies are born in the hospital it is automatic procedure to put

> >>>> > silver drops in their eyes(my guess similiar to collodial silver)

> >>>> just

> >>>> > in case mom has syphillis or ghonerria. Anyone know about

this as

> >>>> > well. Holly

> >>>> >

> >>>>

> >>>>

> >>>>

> >>>>

> >>>>

> >>>>

> >>>>

[Guest guest]

Does anyone actually listen to Offit anymore?

I don't even think the peds are bamboozled anymore.

Re: Aluminium up?

Had to check out what ie said....his usual BS...remember this one?http://pediatrics.aappublications.org/cgi/content/full/112/6/1394Right arrow Infectious Disease & ImmunityPEDIATRICS Vol. 112 No. 6 December 2003, pp. 1394-1397SPECIAL ARTICLEAddressing Parents' Concerns: Do Vaccines Contain HarmfulPreservatives, Adjuvants, Additives, or Residuals? A. Offit, MD* and Rita K. Jew, PharmD{ddagger}* Division of Infectious Diseases, Children's Hospital ofPhiladelphia, University of Pennsylvania School of Medicine, andWistar Institute of Anatomy and Biology, Philadelphia, Pennsylvania{ddagger} Department of Pharmacy, Children's Hospital of Philadelphia,Philadelphia, Pennsylvania ABSTRACTTOPABSTRACTPRESERVATIVESADJUVANTSADDITIVESMANUFACTURING RESIDUALSCONCLUSIONREFERENCESVaccines often contain preservatives, adjuvants, additives, ormanufacturing residuals in addition to pathogen-specific immunogens.Some parents, alerted by stories in the news media or informationcontained on the World Wide Web, are concerned that some of thesubstances contained in vaccines might harm their children. Wereviewed data on thimerosal, aluminum, gelatin, human serum albumin,formaldehyde, antibiotics, egg proteins, and yeast proteins. Bothgelatin and egg proteins are contained in vaccines in quantitiessufficient to induce rare instances of severe, immediate-typehypersensitivity reactions. However, quantities of mercury, aluminum,formaldehyde, human serum albumin, antibiotics, and yeast proteins invaccines have not been found to be harmful in humans or experimentalanimals.Key Words: vaccine safety • thimerosal • aluminum • formaldehyde •gelatin • egg proteins • yeast proteinsAbbreviations: FDA, Food and Drug Administration • DTaP,diphtheria-tetanus-acellular pertussis • Hib, Haemophilus influenzaetype B • EPA, Environmental Protection Agency • ATSDR, Agency forToxic Substances Disease Registry • MMR, measles-mumps-rubella • IgE,immunoglobulin E • CJD, Creutzfeld- disease • BSE, bovinespongiform encephalopathy • vCJD, variant Creutzfeld- diseaseVaccines contain live viruses, killed viruses, purified viralproteins, inactivated bacterial toxins, or bacterial polysaccharides.In addition to these immunogens, vaccines often contain othersubstances. For example, vaccines may contain preservatives thatprevent bacterial or fungal contamination (eg, thimerosal); adjuvantsthat enhance antigen-specific immune responses (eg, aluminum salts);or additives that stabilize live, attenuated viruses (eg, gelatin,human serum albumin). Furthermore, vaccines may contain residualquantities of substances used during the manufacturing process (eg,formaldehyde, antibiotics, egg proteins, yeast proteins).Some parents, alerted by stories in the news media or on the WorldWide Web, are concerned that substances such as thimerosal,formaldehyde, aluminum, antibiotics, and gelatin are harmful. Wereview safety data obtained from human exposure and experimentalanimal studies that address these concerns. PRESERVATIVESTOPABSTRACTPRESERVATIVESADJUVANTSADDITIVESMANUFACTURING RESIDUALSCONCLUSIONREFERENCESPreservatives are used in some vaccines to prevent bacterial or fungalcontamination. The requirement for preservatives in vaccines arosefrom many incidents in the early 20th century of children whodeveloped severe and occasionally fatal bacterial infections afteradministration of vaccines contained in multidose vials.1 For example,in 1916, 4 children died, 26 developed local abscesses, and 68developed severe systemic infections after receipt of a typhoidvaccine contaminated with Staphylococcus aureus.1 As a consequence ofthis and similar incidents, preservatives have been required forvaccines contained in multidose vials (with some exceptions) since the1930s.2Three preservatives are used in vaccines licensed in the UnitedStates: phenol, 2-phenoxyethanol, and thimerosal (Table 1).Thimerosal, a mercury-containing preservative, has been the focus ofintense scrutiny by the US Congress and the news media after itsremoval from most childhood vaccines in 2001. Attention by the newsmedia has caused some parents to fear that thimerosal contained invaccines might harm their children.View this table:[in this window][in a new window] TABLE 1. Preservative Content in Vaccines Licensed in the UnitedStates, 2003Removal of thimerosal from vaccines was precipitated by an amendmentto the Food and Drug Administration (FDA) Modernization Act, which wassigned into law on November 21, 1997.3 The amendment gave the FDA 2years to "compile a list of drugs and foods that contain intentionallyintroduced mercury compounds and ... [to] provide a quantitative andqualitative analysis of the mercury compounds in the list... . " Theamendment arose from a long-standing interest in lessening humanexposure to mercury, a known neurotoxin and nephrotoxin.At the time the FDA Modernization Act was passed, it was recommendedthat infants receive 3 different vaccines that contained thimerosal:diphtheria-tetanus-acellular pertussis (DTaP), hepatitis B, andHaemophilus influenzae type B (Hib). Infants who received all of thesevaccines could have been exposed to a cumulative dose of mercury ashigh as 187.5 µg by 6 months of age.4 This value exceeded guidelinesrecommended by the Environmental Protection Agency (EPA) but did notexceed those recommended by the Agency for Toxic Substances DiseaseRegistry (ATSDR) or the FDA (Table 2).4 Therefore, thimerosal wasremoved from most childhood vaccines by 2001 as a precautionary measure.5View this table:[in this window][in a new window] TABLE 2. Exposure Limits for Mercury in Infants & #8804;6 Months of Age byPercentile Body Weight Established by the EPA, the ATSDR, and the FDAAlthough no published studies to date have compared the incidence ofneurodevelopmental delay in children who received thimerosal-free orthimerosal-containing vaccines, several facts are reassuring that thelevel of mercury contained in vaccines was not likely to be harmful.Thimerosal contains 49.6% mercury by weight and is metabolized toethylmercury and thiosalicylate. Ethylmercury is contained in manydrugs as well as biologicals. Adults and children who are exposedinadvertently to large quantities of ethylmercury acutely (quantities1000- to 1 000 000-fold greater than those found in vaccines) cansustain permanent neurologic damage and death.6–11 However, no dataexist on the capacity of low-dose, chronic exposure to ethylmercury toharm the developing nervous system. Guidelines for chronic exposure toethylmercury were extrapolated from guidelines for methylmercury (themost common form of mercury found in the environment) established bythe EPA, ATSDR, and FDA.4Guidelines from the EPA were based in part on data from pregnant womenin rural Iraq who were exposed to large quantities of methylmercury.12In October 1971, Iraq imported >90 000 metric tons ofmethylmercury-treated seed grain. The grain, distributed free ofcharge to farmers throughout the country, was used to make bread.Consumption of this bread caused an extensive outbreak ofmethylmercury poisoning, resulting in >6000 hospitalizations and 450deaths. By examining the quantity of methylmercury contained in hairfrom mothers who ingested methylmercury and comparing calculatedexposures to methylmercury with the frequency of neurologic symptomsin their offspring (eg, psychomotor retardation, seizures, impairedvision or hearing), a dose-response curve for fetal exposure tomethylmercury and neurologic damage was established. The EPAdetermined guidelines by taking the lowest quantity of methylmercurythat might have resulted in harm to the fetus, bracketing that dosewith 95% confidence intervals and dividing the lower confidenceinterval by an "uncertainty" factor of 10.4By using data from pregnant women in Iraq who were exposed tomethylmercury in the environment to establish guidelines for chronicexposure of infants in the United States to ethylmercury in vaccines,2 important assumptions were made: 1) that the toxicity andpharmacokinetics of methylmercury are the same as those ofethylmercury and 2) that the central nervous systems of the fetus andnewborn are equally susceptible to the harmful effects of mercury.However, the pharmacokinetics of ethylmercury and methylmercury arenot the same. Methylmercury has a biological half-life in blood ofapproximately 50 days compared with that of approximately 7 days forethylmercury.4,13 Because ethylmercury is excreted from the body farmore quickly than methylmercury, cumulative dose guidelines would bevery different. In support of this important difference, Pichichero etal13 found that the level of mercury detected in the blood of 40full-term infants who were 6 months of age or younger and receivedthimerosal-containing DTaP, hepatitis B, and Hib vaccines did notexceed recommended guidelines.13 Furthermore, the developing centralnervous system of the fetus is more susceptible to environmental andtoxic insults than that of the newborn.14–17Removal of thimerosal from most vaccines caused several unanticipatedconsequences. First, before the availability of thimerosal-free DTaP,hepatitis B, and Hib vaccines, hospitals were advised to defer thebirth dose of hepatitis B vaccine to 2 to 6 months of age in infantsof hepatitis B-seronegative mothers.18 Some hospitals misinterpretedthis guideline and suspended administration of the birth dose ofhepatitis B vaccine for all newborns.19–21 As a consequence, 1institution reported that 3 infants of hepatitis B-seropositivemothers did not receive the recommended birth dose of hepatitis Bvaccine.22 Another institution reported the death from acute hepatitisB-induced liver failure of a 3-month-old infant who was born to ahepatitis B-seropositive mother; the infant did not receive thehepatitis B vaccine.19 Furthermore, although thimerosal-free vaccinesare now available, many hospitals continue to defer the birth dose ofhepatitis B vaccine inappropriately.19–21 Second, the removal ofthimerosal from vaccines caused some parents and physicians to believethat vaccines that contain thimerosal were harmful, independent ofdose or age of administration. For example, although contrary torecommendations by the Centers for Disease Control and Prevention,23some parents and physicians were hesitant to give anythimerosal-containing vaccines to children (eg, influenza vaccine tochildren at high risk of severe influenza infection). Third, althoughthimerosal was removed from vaccines in part to "maintain the public'strust in immunization," some physicians found that parents were lessconfident in professional groups that recommended vaccines before thanafter removal of thimerosal.24 ADJUVANTSTOPABSTRACTPRESERVATIVESADJUVANTSADDITIVESMANUFACTURING RESIDUALSCONCLUSIONREFERENCESAluminum salts are the only adjuvants currently licensed for use inthe United States (Table 3). Aluminum salts include aluminumhydroxide, aluminum phosphate, and potassium aluminum sulfate (alum).Aluminum-containing vaccines are prepared by adsorption of antigensonto aluminum hydroxide or aluminum phosphate gels or by precipitationof antigens in a solution of alum.25View this table:[in this window][in a new window] TABLE 3. Aluminum Salt (Adjuvant) Content in Vaccines Licensed inthe United States, 2003Aluminum salts were found initially to enhance immune responses afterimmunization with diphtheria and tetanus toxoids in studies performedin the 1930s, 1940s, and 1950s.26–30 Early studies suggested thataluminum salts reduced the rate of elimination of antigens at the siteof inoculation (ie, depot effect).31 However, subsequent studiesquestioned the importance of the depot effect and found that aluminumsalts enhanced antigen uptake by antigen-presenting cells (eg,dendritic cells),32 activated antigen-presenting cells,32 or inducedproduction of cytokines33 and complement.34 The importance of each ofthese mechanisms in enhancing antigen-specific immune responsesremains unclear.The safety of aluminum has been established by experience during thepast 70 years, with hundreds of millions of people inoculated withaluminum-containing vaccines. Adverse reactions including erythema,subcutaneous nodules, contact hypersensitivity, and granulomatousinflammation have been observed rarely.35Aluminum-containing vaccines are not the only source of aluminumexposure for infants. Because aluminum is 1 of the most abundantelements in the earth's crust and is present in air, food, and water,all infants are exposed to aluminum in the environment. For example,breast milk contains approximately 40 µg of aluminum per liter, andinfant formulas contain an average of approximately 225 µg of aluminumper liter.36–40 Vaccines contain quantities of aluminum similar tothose contained in infant formulas (Table 3). However, because largequantities of aluminum can cause serious neurologic effects inhumans,41 guidelines were established by the ATSDR.For determining the quantity of aluminum below which safety is likely,data were generated in mice that were inoculated orally with variousquantities of aluminum lactate.42 No adverse reactions were observedwhen mice were fed quantities of aluminum as high as 62 mg/kg/day. Byapplying uncertainty factors of 3 (for extrapolation to humans) and 10(for human variability), the ATSDR concluded that the minimum risklevel for exposure to aluminum was 2 mg/kg/day.43 The half-life ofelimination of aluminum from the body is approximately 24 hours.41Therefore, the burden of aluminum to which infants are exposed infood36–40 and vaccines (Table 3) is clearly less than the guidelineestablished by the ATSDR and far less than that found to be safe inexperimental animals.41,42 ADDITIVESTOPABSTRACTPRESERVATIVESADJUVANTSADDITIVESMANUFACTURING RESIDUALSCONCLUSIONREFERENCESAdditives are used to stabilize vaccines from adverse conditions suchas freeze-drying or heat. In addition, additives are added to vaccinesto prevent immunogens from adhering to the side of the vial. The typesof stabilizers used in vaccines include sugars (eg, sucrose, lactose),amino acids (eg, glycine, monosodium salt of glutamic acid), andproteins (eg, gelatin or human serum albumin).Three issues surround the use of protein additives in vaccines: 1) theobservation that immediate-type hypersensitivity reactions are a rareconsequence of receiving gelatin-containing vaccines, 2) thetheoretical concern that human serum albumin might contain infectiousagents, and 3) the theoretical concern that bovine-derived materialsused in vaccines might contain the agent associated with bovinespongiform encephalopathy ("mad-cow" disease).Hypersensitivity to GelatinIn 1993, Kelso et al44 reported the case of a 17-year-old girl inCalifornia who developed profuse rhinorrhea, hives, laryngotrachealedema, lightheadedness, and a blood pressure of 70/50 within 5 minutesof receiving a measles-mumps-rubella (MMR) vaccine. Her symptomsresolved after treatment with epinephrine and diphenhydramine. Whenlater describing the event, the girl stated that it was "kind of likewhat happens when I eat Jell-O."44 Subsequent testing found that theonly component of the vaccine to which the patient was allergic wasgelatin.Before 1993, immediate-type hypersensitivity reactions to the MMRvaccine were attributed to an allergy to egg proteins.45 Thisassumption was based on the fact that both the measles and mumpscomponents of MMR vaccine are grown in chick embryo fibroblast cells.However, most patients with hypersensitivity to MMR vaccine were notallergic to eggs.44 The observation by Kelso et al prompted a closerlook at the capacity of gelatin-containing vaccines to inducehypersensitivity reactions.Studies in Japan confirmed the findings of Kelso et al that immediatehypersensitivity to MMR vaccine was associated with the presence ofgelatin-specific immunoglobulin E (IgE),46 not an allergy to eggproteins. At that time, the rate of immediate hypersensitivity to MMRin Japan was approximately 20-fold higher than that in the UnitedStates.47,48 The increased incidence of immediate-typehypersensitivity to gelatin in Japan was explained in 2 ways. First,DTaP vaccines made in Japan contained gelatin, whereas DTaP vaccinesmade in the United States did not.48 Second, the type of gelatin usedin Japan was not hydrolyzed.48 Hydrolysis converts high molecularweight gelatin (>100 000 Da) to low molecular weight gelatin (between2000 and 5000 Da). Low molecular weight gelatin is less likely tostimulate gelatin-specific IgE than high molecular weight gelatin.49When Japanese vaccine makers eliminated gelatin from DTaP and switchedto the use of hydrolyzed gelatin in the MMR vaccine, the incidence ofgelatin-specific immediate-type hypersensitivity reactions decreaseddramatically to levels similar to those found in the United States.50Although the incidence of anaphylaxis to gelatin is currently very low(approximately 1 case per 2 million doses), gelatin is the most commonidentifiable cause of immediate-type hypersensitivity reactions togelatin-containing vaccines.51,52 A list of vaccines that containgelatin is provided in Table 4 (all gelatin is of porcine origin).View this table:[in this window][in a new window] TABLE 4. Gelatin Content of Vaccines Licensed in the United States,2003Some patients with immediate hypersensitivity reactions to gelatinhave a history of allergies to gelatin-containing foods.51 This isexplained, in part, by the extensive cross-reactivity found betweenbovine gelatin contained in many foods and porcine gelatin containedin vaccines.53 Therefore, it would be of value to ask about foodallergies before vaccination with gelatin-containing vaccines.54 Ifchildren have either a history of food allergy to gelatin or a historyof immediate-type hypersensitivity reactions to gelatin-containingvaccines, then gelatin-containing vaccines should not be administeredand an immunologic evaluation should be performed.54 Evaluation mayinclude either detection of gelatin-specific IgE by solid-phaseimmunoassay or skin testing with increasing concentrations ofgelatin.54 Vaccination of people who have immunologic evidence forgelatin hypersensitivity should be performed with the readyavailability of equipment and medications required for the treatmentof anaphylactic reactions or deferred completely.Theoretical Risk of Infectious Agents in Human Serum AlbuminHuman serum albumin (0.3 mg/dose) is contained in measles vaccine(Attenuvax; Merck and Co, West Point, PA); mumps vaccine (Mumpsvax;Merck and Co); rubella vaccine (Meruvax; Merck and Co); and measles,mumps, and rubella vaccine (MMRII; Merck and Co). Because human serumalbumin is derived from human blood, there is a theoretical risk thatit might contain infectious agents. However, the FDA requires thathuman serum albumin be derived from blood of screened donors and bemanufactured in a manner that would eliminate the risk of transmissionof all known viruses. The result is that no viral diseases have everbeen associated with the use of human serum albumin.Theoretical Risk of "Mad-Cow" Disease From Bovine-Derived ReagentsCreutzfeld- disease (CJD) in humans is caused by a uniqueinfectious agent (proteinaceous infectious particles, or prions) thatalso causes encephalopathies in other mammals such as cows (bovinespongiform encephalopathy [bSE]) and sheep (scrapie).55 Between 1995and 1997, a new "variant" form of CJD (vCJD) in humans was reportedfrom the United Kingdom after an outbreak of BSE in cows.56–60 Thetiming of these events raised the possibility that people who ateproducts from cows that were infected with BSE developed vCJD. Severalepidemiologic, clinical, and pathologic features of vCJD supported acausal link between BSE and vCJD.55,61–64Vaccines contain several reagents that are derived from cows (eg,gelatin, glycerol, enzymes, serum, amino acids). Because of concernsabout vCJD, the FDA recently prohibited the use of bovine-derivedmaterials obtained from countries that are known to have cattle thatare infected with BSE.65 However, before this ban, some materials usedin vaccines might have been obtained from cows that were infected withBSE in England. (It should be noted that US vaccine manufacturers werenot allowed to use bovine products imported from outside the UnitedStates to protect against the possible importation of foot-and-mouthdisease). This raised the question of whether children who wereinoculated with vaccines were at risk for vCJD. Newspapers reportedthis possibility in the late 1990s,66 and some parents were concernedabout bovine-derived products contained in vaccines. However, severalepidemiologic observations and features of the manufacturing processshould reassure parents that vaccines could not cause vCJD. First,prions are detected in the brain, spinal cord, and retina of cows withBSE and not in blood or other organs.55 Therefore, serum (present inmedia that support the growth of microorganisms or cells used to makevaccines) is not likely to contain prions. Consistent with theseobservations, no cases of CJD have been transmitted by blood or bloodproducts, and a history of blood transfusion does not increase therisk for CJD.67–69 Second, prions are not detected in connectivetissue of cows with BSE.55 Therefore, gelatin (made by boiling thehooves and skin of pigs or cows) is unlikely to contain prions. Third,epidemiologic evidence does not support vaccines as a cause of vCJD inEngland.70 Human exposure to cows that were infected with BSE inEngland was likely to have occurred after 1983, and vaccines thatcontained bovine-derived materials were likely to have beenadministered to children after 1985. If vaccines that are routinelyadministered in the first 2 years of life caused vCJD, then no casesof vCJD would have been expected to occur in people who were bornbefore 1985. However, all cases of vCJD occurred in people born whowere before 1985 and half before 1970.70 MANUFACTURING RESIDUALSTOPABSTRACTPRESERVATIVESADJUVANTSADDITIVESMANUFACTURING RESIDUALSCONCLUSIONREFERENCESResidual quantities of reagents that are used to make vaccines areclearly defined and well regulated by the FDA. Inactivating agents(eg, formaldehyde), antibiotics, and cellular residuals (eg, egg andyeast proteins) may be contained in the final product.Inactivating AgentsInactivating agents separate a pathogen's immunogenicity from itsvirulence by eliminating the harmful effects of bacterial toxins orablating the capacity of infectious viruses to replicate. Examples ofinactivating agents include formaldehyde, which is used to inactivateinfluenza virus, poliovirus, and diphtheria and tetanus toxins;ß-propiolactone, which is used to inactivate rabies virus; andglutaraldehyde, which is used to inactivate toxins contained inacellular pertussis vaccines. Formaldehyde deserves special consideration.Concerns about the safety of formaldehyde have centered on theobservation that high concentrations of formaldehyde can damage DNAand cause cancerous changes in cells in vitro.71,72 Althoughformaldehyde is diluted during the manufacturing process, residualquantities of formaldehyde may be found in several current vaccines(Table 5). Fortunately, formaldehyde does not seem to be a cause ofcancer in humans,73 and animals that are exposed to large quantitiesof formaldehyde (a single dose of 25 mg/kg or chronic exposure atdoses of 80–100 mg/kg/day) do not develop malignancies.74,75View this table:[in this window][in a new window] TABLE 5. Formaldehyde Content of Vaccines Licensed for Use in theUnited States, 2003The quantity of formaldehyde contained in individual vaccines does notexceed 0.1 mg (Table 5). This quantity of formaldehyde is consideredto be safe for 2 reasons. First, formaldehyde is an essentialintermediate in human metabolism and is required for the synthesis ofthymidine, purines, and amino acids.76 Therefore, all humans havedetectable quantities of formaldehyde in their circulation(approximately 2.5 µg of formaldehyde/mL of blood).77 Assuming anaverage weight of a 2-month-old of 5 kg and an average blood volume of85 mL/kg, the total quantity of formaldehyde found naturally in aninfant's circulation would be approximately 1.1 mg—a value at least10-fold greater than that contained in any individual vaccine. Second,quantities of formaldehyde at least 600-fold greater than thatcontained in vaccines have been given safely to animals.74,75AntibioticsAntibiotics are present in some vaccines to prevent bacterialcontamination during the manufacturing process. Because antibioticscan cause immediate-type hypersensitivity reactions in children,78,79some parents are concerned that antibiotics that are contained invaccines might be harmful. However, antibiotics that are most likelyto cause immediate-type hypersensitivity reactions (eg, penicillins,cephalosporins, sulfonamides)78,79 are not contained in vaccines.Antibiotics that are used during vaccine manufacture include neomycin,streptomycin, polymyxin B, chlortetracyline, and amphotericin B. Onlyneomycin is contained in vaccines in detectable quantities (Table 6).However, immediate-type hypersensitivity reactions to the smallquantities of neomycin contained in vaccines has not been clearlydocumented.80,81 Although neomycin-containing products have been foundto cause delayed-type hypersensitivity reactions,82,83 these reactionsare not a contraindication to receiving vaccines.View this table:[in this window][in a new window] TABLE 6. Neomycin Content in Vaccines Licensed for Use in theUnited States, 2003Cellular ResidualsEgg ProteinsEgg allergies occur in approximately 0.5% of the population and inapproximately 5% of atopic children.84 Because influenza and yellowfever vaccines both are propagated in the allantoic sacs of chickembryos (eggs), egg proteins (primarily ovalbumin) are present in thefinal product. Residual quantities of egg proteins found in theinfluenza vaccine (approximately 0.02–1.0 µg/dose) are sufficient toinduce severe and rarely fatal hypersensitivity reactions in childrenwith egg allergies.85,86 Unfortunately, children with egg allergiesalso have other diseases (eg, asthma) that are associated with a highrisk of severe and occasionally fatal influenza infection.87,88 Forthis reason, children who have egg allergies and are at high risk ofsevere influenza infection should be given influenza vaccine via astrict protocol.86–90In contrast to influenza vaccine, measles and mumps vaccines arepropagated in chick embryo fibroblast cells in culture. The quantityof residual egg proteins found in measles- and mumps-containingvaccines is approximately 40 pg—a quantity at least 500-fold less thanthose found for influenza vaccines.91 The quantity of egg proteinsfound in measles- and mumps-containing vaccines is not sufficient toinduce immediate-type hypersensitivity reactions, and children withsevere egg allergies can receive these vaccines safely.92Yeast ProteinsHepatitis B vaccines are made by transfecting cells of Saccharomycescerevisiae (baker's yeast) with the gene that encodes hepatitis Bsurface antigen, and residual quantities of yeast proteins arecontained in the final product. Engerix-B (GlaxoKline, ResearchTriangle Park, NC) contains no more than 5 mg/mL and Recombivax HB(Merck and Co) contains no more than 1 mg/mL yeast proteins.Immediate-type hypersensitivity reactions have been observed rarelyafter receipt of hepatitis B vaccine (approximately 1 case per 600 000doses).93 However, yeast-specific IgE has not been detected inpatients with immediate-type hypersensitivity94–96 or in nonallergicpatients97 after receipt of hepatitis B vaccine. Therefore, the riskof anaphylaxis after receipt of hepatitis B vaccine as a result ofallergy to baker's yeast is theoretical. CONCLUSIONTOPABSTRACTPRESERVATIVESADJUVANTSADDITIVESMANUFACTURING RESIDUALSCONCLUSIONREFERENCESParents should be reassured that quantities of mercury, aluminum, andformaldehyde contained in vaccines are likely to be harmless on thebasis of exposure studies in humans or experimental studies inanimals. Although severe anaphylactic reactions may occur rarely afterreceipt of vaccines that contain sufficient quantities of egg proteins(eg, influenza, yellow fever) or gelatin (eg, MMRII), children who areat risk for severe infection with influenza can be desensitized toinfluenza vaccine, and gelatin-specific allergies are very rare.Immediate-type hypersensitivity reactions to neomycin or yeastproteins have not been clearly documented and remain theoretical. ACKNOWLEDGMENTSSome vaccines discussed in this article are manufactured by Merck andCo. Dr Offit is the co-holder of a patent on a bovine-humanreassortant rotavirus vaccine that is being developed by Merck. DrOffit's laboratory support comes from the National Institutes ofHealth, and he does not receive personal support or honoraria fromMerck and does not have a financial interest in the company. FOOTNOTESReceived for publication Feb 20, 2003; Accepted May 1, 2003.Reprint requests to (P.A.O.) Division of Infectious Diseases,Children's Hospital of Philadelphia, Abramson Research Building, Rm1202C, 34th St and Civic Center Blvd, Philadelphia, PA 19104. E-mail:offit@... REFERENCESTOPABSTRACTPRESERVATIVESADJUVANTSADDITIVESMANUFACTURING RESIDUALSCONCLUSIONREFERENCES 1. GS. The Hazards of Immunization. New York, NY: TheAlthone Press; 1967:75–84 2. General Biologics Product Standards; Constituent materials.Ingredients, preservatives, diluents, and adjuvants. 21 CFR: 610.15 (a) 3. 21 USC 397 Section 413 4. Stratton K, Gable A, McCormick MC, eds. Immunization SafetyReview: Thimerosal-Containing Vaccines and NeurodevelopmentalDisorders. Washington, DC: National Academy Press; 2001 5. Goldstein BD. The precautionary principle also applies to publichealth actions. Am J Public Health.2001; 91 :1358 –1361[Abstract/FreeFull Text] 6. Hay WJ, Rickerts AG, McMenemey WH, Cumings JN. Organic mercurialencephalopathy. Neurol Neurosurg Psychiatry.1963; 26 :199 –202 7. Axton JHM. Six cases of poisoning after a parenteral organicmercury compound (Merthiolate). Postgrad Med J.1972; 48 :417–421[iSI][Medline] 8. Fagan DG, Pritchard JS, son TW, Greenwood MR. Organ mercurylevels in infants with omphaloceles treated with organic mercuryantiseptic. Arch Dis Child.1977; 52 :962 –964[Abstract] 9. Cinca I, Dumitrescu I, Onaca P, et al. Accidental ethyl mercurypoisoning with nervous system, skeletal muscle, and myocardium injury.J Neurol Neurosurg Psychiatry.1979; 43 :143 –149[iSI] 10. Rohyans J, Walson PD, Wood GA, Mac WA. Mercury toxicityfollowing merthiolate ear irrigations. J Pediatr.1984; 104 :311–313[iSI][Medline] 11. Pfab R, Muckter H, Roider G, Zilker T. Clinical course of severepoisoning with thiomersal. Clin Toxicol.1996; 34 :453 –460 12. Marsh DO, son TW, C, et al. Fetal methylmercurypoisoning: relationship between concentration in single strands ofmaternal hair and child effects. Arch Neurol.1987; 44 :1017–1022[Abstract] 13. Pichichero ME, Cernichiari E, Lopreiato J, Treanor J. Mercuryconcentrations and metabolism in infants receiving vaccines containingthiomersal: a descriptive study. Lancet.2002; 360 :1737–1741[CrossRef][iSI][Medline] 14. Strömland K, Nordin V, M, et al. Autism in thalidomideembryopathy: a population study. Dev Med Child Neurol.1994; 36 :351–356[iSI][Medline] 15. Rodier PM. The early origins of autism. Sci Am.2000; February:56 –63 16. Chess S, Fernandez P, Korn S. Behavioral consequences ofcongenital rubella. J Pediatr.1978; 93 :699 –703[iSI][Medline] 17. Deykin EY, MacMahon B. Viral exposure and autism. Am JEpidemiol.1979; 109 :628 –638[Abstract/Free Full Text] 18. American Academy of Pediatrics. Committee on Infectious Diseasesand Committee on Environmental Health. Thimerosal in vaccines—aninterim report to clinicians. Pediatrics.1999; 104 :570 –574[Free FullText] 19. Centers for Disease Control and Prevention. Impact of the 1999AAP/USPHS joint statement on thimerosal in vaccines on infanthepatitis B vaccination practices. MMWR Morb Mortal Wkly Rep.2001; 50:94 –97[Medline] 20. Hurie MB, Saari TN, JP. Impact of the joint statement bythe American Academy of Pediatrics/US Public Health Service onthimerosal in vaccines on hospital infant hepatitis B vaccinationpractices. Pediatrics.2001; 107 :755 –758[Abstract/Free Full Text] 21. Brayden RM, Pearson KA, JS, et al. Effect of thimerosalrecommendations on hospitals' neonatal hepatitis B vaccinationpolicies. J Pediatr.2001; 138 :752 –755[CrossRef][iSI][Medline] 22. B. Comment. In: Transcript of the National VaccineAdvisory Committee Workshop on Thimerosal in Vaccines. Bethesda, MD:US Government Printing Office; August 12, 1999 23. Centers for Disease Control and Prevention. Recommendationsregarding the use of vaccines that contain thimerosal as apreservative. MMWR Morb Mortal Wkly Rep.1999; 48 :996 –998[Medline] 24. Freed GL, e M. Presentation to Immunization Safety ReviewCommittee. History of Thimerosal Concern and Comparative PolicyActions; Cambridge, Massachusetts; July 16, 2001 25. Shirodkar S, Hutchinson RL, DL, et al. Aluminum compoundsused as adjuvants in vaccines. Pharm Res.1990; 7 :1282–1288[CrossRef][iSI][Medline] 26. Glenny AT, Pope CG, Waddington H, Wallace U. The antigenic valueof toxoid precipitated by potassium alum. J Pathol Bacteriol.1926; 29:38 –39 27. Volk VK, Bunney WE. Diphtheria immunization with fluid toxoidand alum-precipitated toxoid. Am J Public Health.1942; 32 :690 –699 28. Barr M, Glenney AT, Hignett S, et al. Antigenic efficiency offluid and precipitated diphtheria prophylactics in very young babiesand lambs. Lancet.1952; 2 :803 –805[iSI][Medline] 29. Barr M, Glenny AT, NR. Immunization of babies withdiphtheria-tetanus-pertussis prophylactic. Br Med J.1955; 2 :635 –639 30. Greenberg L, Benoit R. Control of potency and the dosage ofdiphtheria and tetanus toxoids. JAMA.1956; 160 :108 –113[iSI] 31. Glenny AT, AH, s MF. Rate of disappearance ofdiphtheria toxoid injected into rabbits and guinea pigs: toxoidprecipitated with alum. J Pathol Bacteriol.1931; 34 :267 –275[CrossRef] 32. Mannhalter JW, Neychev HO, Zlabinger GJ, et al. Modulation ofthe immune response by the non-toxic and non-pyrogenic adjuvantaluminum hydroxide: effect on antigen uptake and antigen presentation.Clin Exp Immunol.1985; 61 :143 –151[iSI][Medline] 33. Ulanova M, Tarkowsi A, Hahn-Zoric M, Hanson LA. The commonvaccine adjuvant aluminum hydroxide upregulates accessory propertiesof human monocytes via an interleukin-4-dependent mechanism. InfectImmun.2001; 69 :1151 –1159[Abstract/Free Full Text] 34. Ramanathan VD, Badenoch- P, Turk JL. Complement activationby aluminum and zirconium compounds. Immunology.1979; 37 :881–888[iSI][Medline] 35. Gupta RK, Rost BE, Relyveld E, Siber GR. Adjuvant properties ofaluminum and calcium compounds. In: MF, Newman MJ, eds. VaccineDesign: The Subunit and Adjuvant Approach. New York, NY: Plenum Press;1995:229–248 36. Koo WWK, Kaplan LA, Krug-Wispe SK. Aluminum contamination ofinfant formulas. J Parenteral Nutr.1988; 12 :170 –173[iSI] 37. Weintraub R, Hams G, Meerkin M, Rosenberg AR. High aluminumcontent of infant milk formulas. Arch Dis Child.1986; 61 :914–916[Abstract] 38. Simmer K, Fudge A, Teubner J, SL. Aluminum concentrationsin infant milk formulae. J Paediatr Child Health.1990; 26 :9–11[iSI][Medline] 39. Hawkins NM, Coffey S, Lawson MS, Delves HT. Potential aluminumtoxicity in infants fed special infant formula. J PaediatrGastroenterol Nutr.1994; 19 :377 –381[iSI][Medline] 40. Mandic ML, Grgic J, Grgic Z, et al. Aluminum levels in humanmilk. Sci Total Environ.1995; 170 :165 –170[CrossRef][iSI][Medline] 41. LS, DE, Chou C. Aluminum toxicokinetics regardinginfant diet and vaccination. Vaccine.2002; 20 :S13 –S17[CrossRef][Medline] 42. Golub MS, JM, Gershwin ME, Keen CL. Effects of aluminumingestion on spontaneous motor activity of mice. NeurotoxicolTeratol.1989; 11 :231 –235[CrossRef][iSI][Medline] 43. Toxicological Profile for Aluminum. Atlanta, GA: US Departmentof Health and Human Services, Public Health Service, Agency for ToxicSubstances and Disease Registry; 1999 44. Kelso JM, RT, Yunginger JW. Anaphylaxis to measles, mumps,and rubella vaccine mediated by IgE to gelatin. J Allergy ClinImmunol.1993; 91 :867 –872[CrossRef][iSI][Medline] 45. Herman JJ, Radin R, Schneiderman R. Allergic reactions tomeasles (rubeola) vaccine in patients hypersensitive to egg proteins.J Pediatr.1983; 102 :196 –199[iSI][Medline] 46. Sakaguchi M, Ogura H, Inouye S. IgE antibody to gelatin inchildren with immediate-type reactions to measles and mumps vaccines.J Allergy Clin Immunol.1995; 96 :563 –565[CrossRef][iSI][Medline] 47. Centers for Disease Control and Prevention. Update: vaccine sideeffects, adverse reactions, contraindications, and precautions. MMWRMorb Mortal Wkly Rep.1996; 45 :1 –35[Medline] 48. Sakaguchi M, Nakayama T, Fujita H, et al. Minimum estimatedincidence in Japan of anaphylaxis to live virus vaccines includinggelatin. Vaccine.2001; 19 :431 –436[CrossRef][iSI] 49. Sakai Y, Yamoto R, Onuma M, et al. Non-antigenic and lowallergic gelatin produced by specific digestion with enzyme-coupledmatrix. Biol Pharm Bull.1998; 21 :330 –334[iSI][Medline] 50. Nakayama T, Aizawa C. Change in gelatin content of vaccinesassociated with reduction in reports of allergic reactions. J AllergyClin Immunol.2000; 106 :591 –592[CrossRef][iSI][Medline] 51. Sakaguchi M, Nakayama T, Inouye S. Food allergy to gelatin inchildren with systemic immediate-type reactions, includinganaphylaxis, to vaccines. J Allergy Clin Immunol.1996; 98 :1058–1061[CrossRef][iSI][Medline] 52. Sakaguchi M, Yamanaka T, Ikeda K, et al. IgE-mediated systemicreactions to gelatin included in the varicella vaccine. J Allergy ClinImmunol.1997; 99 :263 –264[CrossRef][iSI][Medline] 53. Sakaguchi M, Hori H, Ebihara T, et al. Reactivity of theimmunoglobulin E in bovine gelatin-sensitive children to gelatins fromother animals. Immunology.1999; 96 :286 –290[CrossRef][iSI][Medline] 54. Centers for Disease Control and Prevention. Generalrecommendations on immunization: recommendations of the AdvisoryCommittee on Immunization Practices (ACIP) and the American Academy ofFamily Physicians (AAFP). MMWR Morb Mortal Wkly Rep.2002; 51 :17 55. Tyler KL. Prions and prion diseases of the central nervoussystem (transmissible neurodegenerative diseases). In Mandell GL, JE, Dolin R, eds. Principles and Practices of InfectiousDiseases. Philadelphia, PA: Churchill Livingstone; 2000 56. Britton TC, Al-Sarraj S, Shaw C, et al. SporadicCreutzfeld- disease in a 16-year-old in the UK. Lancet.1995; 346:1155[iSI][Medline] 57. Will RG, Ironside JW, Zeidler M, et al. A new variant ofCreutzfeld- disease in the UK. Lancet.1996; 347 :921–925[CrossRef][iSI][Medline] 58. Zeidler M, GE, Barraclough CR, et al. New variantCreutzfeld- disease: neurologic features and diagnostic tests.Lancet.1997; 350 :903 –907[CrossRef][iSI][Medline] 59. Schonberger L. New variant Creutzfeld- disease and bovinespongiform encephalopathy. Infect Dis Clin North Am.1998; 12 :111–121[CrossRef][iSI][Medline] 60. RM, Donnelly CA, Ferguson NM, et al. Transmissiondynamics and epidemiology of BSE in British cattle. Nature.1996; 382:779[CrossRef][iSI][Medline] 61. Delys J-P, Lasmexas CI, Streichenberger N, et al. New variantCreutzfeld- disease in France. Lancet.1997; 349 :30–31[CrossRef][iSI][Medline] 62. Collinge J, Sidle KCL, Meads J, et al. Molecular analysis ofprion strain variation and the aetiology of `new variant' CJD.Nature.1996; 383 :685 –690[CrossRef][iSI][Medline] 63. Parchi P, Capellari S, Chen SG, et al. Typing prion isoforms.Nature.1997; 386 :232[CrossRef][iSI][Medline] 64. Bruce ME, Will RG, Ironside JW, et al. Transmissions to miceindicate that `new variant' CJD is caused by BSE agent. Nature.1997;389 :498 –501[CrossRef][iSI][Medline] 65. Marwick C. FDA calls bovine-based vaccines currently safe.JAMA.2000; 284 :1231 –1232[Free Full Text] 66. sen M, Winter G. 5 drug makers use material with possiblemad cow link. New York Times.2001; February 8 :C1 67. Brown P. Can Creutzfeld- disease be transmitted bytransfusion? Curr Opin Hematol.1995; 2 :472 –477[Medline] 68. S, Law MG, Fletcher A, et al. Surgical treatment andrisk of sporadic Creutzfeld- disease: a case-control study.Lancet.1999; 353 :693 –697[CrossRef][iSI][Medline] 69. Esmonde TF, Will RG, Slattery JM, et al. Creutzfeld-disease and blood transfusion. Lancet.1993; 341 :205–207[CrossRef][iSI][Medline] 70. Minor PD, Will RG, Salisbury D. Vaccines and variant CJD.Vaccine.2001; 19 :409 –410[CrossRef][iSI] 71. Goldmacher VS, Thilly WG. Formaldehyde is mutagenic for culturedhuman cells. Mutat Res.1983; 116 :417 –422[CrossRef][iSI][Medline] 72. Ragan DL, Boreiko CJ. Initiation of C3H/10T1/2 celltransformation by formaldehyde. Cancer Lett.1981; 13 :325–331[CrossRef][iSI][Medline] 73. Epidemiology of chronic occupational exposure to formaldehyde:report of the ad hoc panel on health aspects of formaldehyde. ToxicolInd Health.1988; 4 :77 –90[iSI][Medline] 74. Natarajan AT, Darroudi F, Bussman CJM, van Kesteren-van LeeuwenAC. Evaluation of the mutagenicity of formaldehyde in mammaliancytogenetic assays in vivo and in vitro. Mutat Res.1983; 122 :355–360[CrossRef][iSI][Medline] 75. Til HP, Woutersen RA, Feron VJ, et al. Two-year drinking-waterstudy of formaldehyde in rats. Food Chem Toxicol.1989; 27 :77–87[CrossRef][iSI][Medline] 76. Huennekens FM, Osborne MJ. Folic acid coenzymes and one-carbonmetabolism. Adv Enzymol.1959; 21 :369 –446[iSI] 77. Heck H, Casanova-Schmitz M, Dodd PB, et al. Formaldehyde (CH2O)concentrations in the blood of humans and Fischer-344 rats exposed toCH2O under controlled conditions. Am Ind Hyg Assoc J.1985; 46 :1–3[iSI][Medline] 78. JA, Adkinson NF. Allergic reactions to drugs andbiologic agents. JAMA.1987; 258 :2891 –2899[Abstract] 79. Yunginger JW. Anaphylaxis. Curr Probl Pediatr.1992; 22 :130–146[CrossRef][Medline] 80. Goh CL. Anaphylaxis from topical neomycin and bacitracin. Aust JDermatol.1986; 27 :125 –126 81. Kwittken PL, Rosen S, Sweinberg SK. MMR vaccine and neomycinallergy. Am J Dis Child.1993; 147 :128 –129[iSI][Medline] 82. Leyden JJ, Kligman AM. Contact dermatitis to neomycin sulfate.JAMA.1979; 242 :1276 –1278[Abstract] 83. Mac RH, Beck M. Neomycin: a review with particularreference to dermatological usage. Clin Exp Dermatol.1983; 8 :249–258[iSI][Medline] 84. Ratner B, Untracht S. Egg allergy in children. Am J DisChild.1952; 83 :309 –316[iSI] 85. Bierman CW, Shapiro GG, Pierson WE, et al. Safety of influenzavaccination in allergic children. J Infect Dis.1977; 136 :S652–S655[iSI][Medline] 86. JM, Zeiger RS, Lester MR, et al. Safe administration ofinfluenza vaccine to patients with egg allergy. J Pediatr.1998; 133:624 –628[CrossRef][iSI][Medline] 87. Glezen WP. Serious morbidity and mortality associated withinfluenza epidemics. Epidemiol Rev.1982; 4 :25 –44[Free Full Text] 88. Glezen WP, Greenberg SB, Atmar RL, et al. Impact of respiratoryvirus infection on persons with underlying conditions. JAMA.2000; 283:499 –505[Abstract/Free Full Text] 89. KR, Strunk RC. Safe administration of influenza vaccinein asthmatic children hypersensitive to egg proteins. J Pediatr.1985;106 :931 –933[CrossRef][iSI][Medline] 90. Zieger RS. Current issues with influenza vaccination in eggallergy. J Allergy Clin Immunol.2002; 110 :834–840[CrossRef][iSI][Medline] 91. Fasano MB, Wood RA, Cooke SK, Sampson HA. Egg hypersensitivityand adverse reactions to measles, mumps, and rubella vaccine. JPediatr.1992; 120 :878 –881[iSI][Medline] 92. JM, Burks AW, Roberson PK, Sampson HA. Safe administrationof the measles vaccine to children allergic to eggs. N Engl JMed.1995; 332 :1262 –1266[Abstract/Free Full Text] 93. Lear JT, English JS. Anaphylaxis after hepatitis B immunization.Lancet.1995; 345 :1249 94. Hudson TJ, Newkirk M, Gervais F, Shuster J. Adverse reaction tothe recombinant hepatitis B vaccine. J Allergy Clin Immunol.1991; 88:821 –822[CrossRef][iSI][Medline] 95. Barbaud A, Tréchot P, Reichert-Pénétrat S, et al. Allergicmechanisms and urticaria/angioedema after hepatitis B immunization. BrJ Dermatol.1998; 139 :916 –941[CrossRef][iSI][Medline] 96. Brightman CA, Scadding GK, Dumbreck LA, et al. Yeast-derivedhepatitis B vaccine and yeast sensitivity. Lancet.1989; i :903 97. Wiederman G, Scheiner O, Ambrosch F, et al. Lack of induction ofIgE and IgG antibodies to yeast in humans immunized with recombinanthepatitis B vaccines. Int Arch Allergy Appl Immunol.1988; 85 :130–132[iSI][Medline]PEDIATRICS (ISSN 1098-4275). ©2003 by the American Academy of PediatricsP3Rs:Read all P3RsParents' worries about thimerosal in vaccines are well founded! Mark R. Geier, MD, Ph.D., et al. Pediatrics Online, 12 Mar 2004 [Full text] Re: Parents' worries about thimerosal in vaccines are well founded! paul a offit, et al. Pediatrics Online, 17 Mar 2004 [Full text] Offit and Jew incorrect on 2003 Vaccination Schedules S. Hooker Pediatrics Online, 31 Mar 2004 [Full text] response to brian hooker A Offit, et al. Pediatrics Online, 1 Apr 2004 [Full text] > >>>> >> >>>> > Hi Group,> >>>> >> >>>> > My friend who is a nurse said with the removal of mercury the> >>>> amount> >>>> > of Al was increased. Anyone know if this is true? Alsoshe said> >>>> when> >>>> > babies are born in the hospital it is automatic procedure to put> >>>> > silver drops in their eyes(my guess similiar to collodial silver)> >>>> just> >>>> > in case mom has syphillis or ghonerria. Anyone know aboutthis as> >>>> > well. Holly> >>>> >> >>>>> >>>>> >>>>> >>>>> >>>>> >>>>> >>>>

[Guest guest]

Henry..I hope you're right!

> > >>>> >

> > >>>> > Hi Group,

> > >>>> >

> > >>>> > My friend who is a nurse said with the removal of mercury the

> > >>>> amount

> > >>>> > of Al was increased. Anyone know if this is true? Also

> she said

> > >>>> when

> > >>>> > babies are born in the hospital it is automatic procedure

to put

> > >>>> > silver drops in their eyes(my guess similiar to collodial

silver)

> > >>>> just

> > >>>> > in case mom has syphillis or ghonerria. Anyone know about

> this as

> > >>>> > well. Holly

> > >>>> >

> > >>>>

> > >>>>

> > >>>>

> > >>>>

> > >>>>

> > >>>>

> > >>>>

[Guest guest]

Do we want to go there? If thimerosal turns out to be an active

ingredient in vaccines, then it'll be covered by the immunity law that

protects vaccine makers --Lilly et al. are off the hook.

Lenny

> >>>> >

> >>>> > Hi Group,

> >>>> >

> >>>> > My friend who is a nurse said with the removal of mercury the

> >>>> amount

> >>>> > of Al was increased. Anyone know if this is true? Also

she said

> >>>> when

> >>>> > babies are born in the hospital it is automatic procedure to put

> >>>> > silver drops in their eyes(my guess similiar to collodial silver)

> >>>> just

> >>>> > in case mom has syphillis or ghonerria. Anyone know about

this as

> >>>> > well. Holly

> >>>> >

> >>>>

> >>>>

> >>>>

> >>>>

> >>>>

> >>>>

> >>>>

[Guest guest]

And if I am not mistaken-if it's an active ingredient then the lawsuits in the vaccine court should have been allowed to move ahead years ago. Ha!schaferatsprynet <schafer@...> wrote: Do we want to go there? If thimerosal turns out to be an activeingredient in vaccines, then it'll be covered by the immunity law thatprotects vaccine makers --Lilly et al. are off the hook.Lenny> >>>> >> >>>> > Hi Group,> >>>> >> >>>> > My friend who is a nurse said with the removal of mercury the> >>>> amount> >>>> > of Al was increased. Anyone know if this is true? Alsoshe said> >>>> when> >>>> > babies are born in the hospital it is automatic procedure to put> >>>> > silver drops in their eyes(my guess similiar to collodial silver)> >>>> just> >>>> > in case mom has syphillis or ghonerria. Anyone know aboutthis as>

>>>> > well. Holly> >>>> >> >>>>> >>>>> >>>>> >>>>> >>>>> >>>>> >>>>

[Guest guest]

Dr. Boyd Haley made a few comments to us in interview that thimerosal isn't an

adjuvant.

Just an immune suppressant. But I've heard it both ways.

Either way, they should definitely use other adjuvants.

> >> + Re: Aluminium up?

> >>>>

> >>>> Aluminum is used as an adjuvant in vaccines. Thimerosal is a

> >>>> preservative. They wouldn't increase an adjuvant to replace

> >>>> thimerosal.

> >>>>

> >>>>

> >>>> Critical Decisions Count

> >>>> http://users.adelphia.net/~cdc/VaccineIngredients.htm#Aluminum

> >>>>

> >>>>

> >>>>

> >>>> >

> >>>> > Hi Group,

> >>>> >

> >>>> > My friend who is a nurse said with the removal of mercury the

> >>>> amount

> >>>> > of Al was increased.  Anyone know if this is true?  Also she said

> >>>> when

> >>>> > babies are born in the hospital it is automatic procedure to put

> >>>> > silver drops in their eyes(my guess similiar to collodial silver)

> >>>> just

> >>>> > in case mom has syphillis or ghonerria.  Anyone know about this as

> >>>> > well.  Holly

> >>>> >

> >>>>

> >>>>

> >>>>

> >>>>

> >>>>

> >>>>

> >>>>

[Guest guest]

My point is not that thimerosal is properly usable as an adjuvant - I

do not know. But some vaccine regulators think it might have an

adjuvant effect and removing it might affect efficacy. Not an

either/or proposition - my point is that it does have an affect on the

immune system - not a good one - but does provoke the production of

cytokines and B cells etc. This may make vaccines have a greater

antigenic effect and make it appear that vaccines are more effective,

but at the cost of some disruption of the immune system.

The point is that some vaccine authorities are concerned that removing

thimerosal might affect the efficacy of the vaccine. That is usually

not made public as thimerosal is supposed to be in there only as a

preservative. Note the current line that most vaccines do not have

thimerosal " as a preservative. " That statement may have more

significance than the implication that it was was used as a sterilizer

in manufacturing.

When you see some of the documents at Autism One you will see what I

mean.

On May 8, 2006, at 7:35 AM, Nanstiel wrote:

> Dr. Boyd Haley made a few comments to us in interview that thimerosal

> isn't an adjuvant.

> Just an immune suppressant. But I've heard it both ways.

>

> Either way, they should definitely use other adjuvants.

>

>

> > >> + Re: Aluminium up?

> > >>>>

> > >>>> Aluminum is used as an adjuvant in vaccines. Thimerosal is a

> > >>>> preservative. They wouldn't increase an adjuvant to replace

> > >>>> thimerosal.

> > >>>>

> > >>>>

> > >>>> Critical Decisions Count

> > >>>> http://users.adelphia.net/~cdc/VaccineIngredients.htm#Aluminum

> > >>>>

> > >>>>

> > >>>>

> > >>>> >

> > >>>> > Hi Group,

> > >>>> >

> > >>>> > My friend who is a nurse said with the removal of mercury the

> > >>>> amount

> > >>>> > of Al was increased.  Anyone know if this is true?  Also

> she said

> > >>>> when

> > >>>> > babies are born in the hospital it is automatic procedure to

> put

> > >>>> > silver drops in their eyes(my guess similiar to collodial

> silver)

> > >>>> just

> > >>>> > in case mom has syphillis or ghonerria.  Anyone know about

> this as

> > >>>> > well.  Holly

> > >>>> >

> > >>>>

> > >>>>

> > >>>>

> > >>>>

> > >>>>

> > >>>>

> > >>>>

[Guest guest]

No, this would not have changed the decisions driving cases from state

and federal courts into vaccine court. This was covered by the Leroy

decision in the vaccine court and multiple state and federal decisions.

Thimerosal is already convered as a constituent in vaccines. This is

what all the litigation was about when cases alleging thimerosal injury

were brought in state and federal courts either individually or in

class actions. Plaintiffs argued it was a contaminant and not covered.

The Defendants argued that it was a constituent. With the exception of

1 or 2 courts it was deemed to be a constituents and covered by the

vaccine act, and plaintiffs had to file in vaccine court first. The

exception was thimerosal manufacturers like Eli Lilly or Sigma-they can

be sued as thimerosal manufacturers, not vaccine manufacturers under a

federal Appeals Court decision - whether or not thimerosal is an

" active " ingredient. Being an " active ingredient " , by that I presume

you mean active as an adjuvant rather than active as a preservative,

would not affect this. The question is whether thimerosal is considered

to be a " constituent " of vaccines or a " contaminant. " The courts have

already decided it is a " constituent " that is covered by the vaccine

act. Discussing thimerosal's effect as an adjuvant would have no

bearing on this.

So, yes I want to go there as it will not change the law, and the issue

should be pressed. In addition, if it is an adjuvant but not one that

is recognized as such in licensing applications etc. - its function as

an adjuvant was hidden - so there may be violations of law or

regulation.

I do not see the problem in stating that it may have been used as an

adjuvant. Will not let Lilly off the hook - just the opposite

possibility - if some parties knew it was being used as an adjuvant..

On May 8, 2006, at 6:40 AM, Maurine Meleck wrote:

> And if I am not mistaken-if it's an active ingredient then the

> lawsuits in the vaccine court should have been allowed to move ahead

> years ago.  Ha!

>

> schaferatsprynet <schafer@...> wrote:

>> Do we want to go there?  If thimerosal turns out to be an active

>> ingredient in vaccines, then it'll be covered by the immunity law that

>> protects vaccine makers --Lilly et al. are off the hook.

>>

>> Lenny

>>

>>

>>

>> > >>>> >

>> > >>>> > Hi Group,

>> > >>>> >

>> > >>>> > My friend who is a nurse said with the removal of mercury the

>> > >>>> amount

>> > >>>> > of Al was increased.  Anyone know if this is true?  Also

>> she said

>> > >>>> when

>> > >>>> > babies are born in the hospital it is automatic procedure to

>> put

>> > >>>> > silver drops in their eyes(my guess similiar to collodial

>> silver)

>> > >>>> just

>> > >>>> > in case mom has syphillis or ghonerria.  Anyone know about

>> this as

>> > >>>> > well.  Holly

>> > >>>> >

>> > >>>>

>> > >>>>

>> > >>>>

>> > >>>>

>> > >>>>

>> > >>>>

>> > >>>>

[Guest guest]

Unfortunately, he still seems to be in high regard by too much of the

mainstream media and policy makers, probably because he says what they

want to hear. And through them, he reaches far too many parents who

buy into what he's saying because he's an " expert, " and after all he

says he really cares about our children.

Wade

> >

> > Does anyone actually listen to Offit anymore?

> > I don't even think the peds are bamboozled anymore.

> >

> >

[Guest guest]

I did hear talk of doing this to get a "better" immune response.. nice eh?

Hi Group,My friend who is a nurse said with the removal of mercury the amount of Al was increased. Anyone know if this is true? Also she said when babies are born in the hospital it is automatic procedure to put silver drops in their eyes(my guess similiar to collodial silver) just in case mom has syphillis or ghonerria. Anyone know about this as well. Holly