Alcohol and Leaky Gut Syndrome
Alcohol is viewed as one of the main causes of leaky gut syndrome. It
is already accepted that alcohol can have a toxic effect on almost
every organ in the body. It is now suggested that alcohol causes
intestinal permeability. This is believed to occur because alcohol
suppresses the production of prostaglandins. These hormonal substances
are needed because they are able to moderate inflammation. If
prostaglandins are in low supply then it allows inflammation to cause
more damage inside the gut. Another mechanism by which alcohol
exacerbates leaky gut syndrome is that it prevents some important
nutrients from being transported from the intestine into the blood.
Monday, 14 March 2016
Pathogenic Clostridia, Including Botulism and Tetanus
Pathogenic Clostridia, Including Botulism and Tetanus
Pathogenic Clostridia, including Botulism and Tetanus (page 1)
(This chapter has 4 pages)
Clostridium botulinum
Clostridia
The genus
Clostridium consists of relatively large, Gram-positive,
rod-shaped
bacteria in the Phylum Firmicutes
(Clostridia is actually a
Class in the Phylum).
All species form endospores
and have a strictly fermentative type of
metabolism.
Most clostridia will not grow under aerobic conditions and vegetative
cells
are killed by exposure to O2, but their spores are able to
survive long
periods of exposure to air.
The clostridia are ancient organisms that live in virtually all of
the
anaerobic habitats of nature where organic compounds are present,
including
soils, aquatic sediments and the intestinal tracts of animals.
Clostridia are able to ferment a wide variety of organic compounds.
They produce end products such as butyric acid, acetic acid, butanol
and
acetone, and large amounts of gas (CO2 and H2)
during fermentation of
sugars.
A variety of foul smelling compounds are formed during the fermentation
of amino acids and fatty acids. The clostridia also produce a wide
variety
of extracellular enzymes to degrade large biological molecules (e.g.
proteins, lipids, collagen, cellulose, etc.) in the
environment
into fermentable components. Hence, the clostridia play an important
role
in nature in biodegradation and the carbon cycle. In anaerobic
clostridial
infections, these enzymes play a role in invasion and pathology.
Most of the clostridia are saprophytes, but a few are pathogenic for
humans, primarily Clostridium
perfringens, C. difficile, C. tetani and C. botulinum. Those that are pathogens
have primarily a saprophytic existence
in nature and, in a sense, are opportunistic pathogens. Clostridium
tetani and Clostridium botulinum produce the most potent
biological
toxins known to affect humans. As pathogens of tetanus and food-borne
botulism,
they owe their virulence almost entirely to their toxigenicity. Other
clostridia,
however, are highly invasive under certain circumstances.
Stained pus from a mixed
anaerobic
infection. At least three different clostridia are apparent.
Clostridium perfringens
C. perfringens
Clostridium perfringens, which produces a huge array of
invasins
and exotoxins, causes wound and surgical infections that lead
to
gas
gangrene, in addition to severe uterine infections.
Clostridial
hemolysins and extracellular enzymes such as proteases, lipases,
collagenase
and hyaluronidase, contribute to the invasive process. Clostridium
perfringens
also produces an enterotoxin and is an important cause of food
poisoning.
Usually the organism is encountered in improperly sterilized (canned)
foods
in which endospores have germinated.
Food poisoning
Clostridium perfringens is classified into 5 types (A�E) on
the basis of its ability to produce one or more of the major lethal
toxins, alpha, beta, epsilon and iota (α, β, ε, and ι). Enterotoxin
(CPE)-producing (cpe+) C.
perfringens type A is reported continuously as one of the most
common food poisoning agents worldwide. An increasing number of reports
also implicate the organism in 5%�15% of antibiotic�associated
diarrhea (AAD) and sporadic diarrhea (SD) cases in humans, as well as
diarrhea cases in animals.
Most food poisoning strains studied carry cpe in their
chromosomes; isolates from AAD and SD cases bear cpe in a
plasmid. Why C. perfringens strains with cpe
located on chromosomes or plasmids cause different diseases has not
been satisfactorily explained. However, the relatively greater heat
resistance of the strains with chromosomally located cpe is a
plausible explanation for these strains' survival in cooked food, thus
causing instances of food poisonings. The presence of C.
perfringens strains with chromosomally located cpe in
1.4% of American retail food indicates that these strains have an
access to the food chain, although sources and routes of contamination
are unclear.
An explanation for the strong association between C. perfringens
strains with plasmid-located cpe and cases of AAD and SD
disease may be in vivo transfer of the cpe plasmid to C.
perfringens strains of the normal intestinal microbiota.
Thus, a small amount of ingested cpe+ C. perfringens
would act as an infectious agent and transfer the cpe plasmid
to cpe� C. perfringens strains of the normal
microbiota. Conjugative transfer of the cpe plasmid has been
demonstrated in vitro, but no data exist on horizontal gene
transfer of cpe in vivo, and whether cpe+ strains
that cause AAD and SD are resident in the gastrointestinal tract or
acquired before onset of the disease is unknown.
Case Study
Report of C. perfringens Food
Poisoning
Clostridium perfringens
is a common cause of outbreaks of foodborne illness in the United
States,
especially outbreaks in which cooked beef is the implicated source.
This
is a condensed version of an MMWR report that describes an outbreak of
C.
perfringens gastroenteritis following St. Patrick's Day meals of
corned
beef. The report typifies outbreaks of C. perfringens food
poisoning.
Report
On March 18, 1993, the
Cleveland
City Health Department received telephone calls from 15 persons who
became
ill after eating corned beef purchased from one delicatessen.
After
a local newspaper article publicized this problem, 156 persons
contacted
the health department to report onset of diarrheal illness within 48
hours
of eating food from the delicatessen on March 16 or March 17. Symptoms
included abdominal cramps (88%) and vomiting (13%); no persons were
hospitalized.
The median incubation period was 12 hours (range: 2-48 hours). Of the
156
persons reporting illness, 144 (92%) reported having eaten corned beef;
20 (13%), pickles; 12 (8%), potato salad; and 11 (7%), roast beef.
In anticipation of a large
demand
for corned beef on St. Patrick's Day (March 17), the delicatessen had
purchased
1400 pounds of raw, salt-cured product. Beginning March 12, portions of
the corned beef were boiled for 3 hours at the delicatessen, allowed to
cool at room temperature, and refrigerated. On March 16 and 17, the
portions
were removed from the refrigerator, held in a warmer at 120oF
(48.8oC), and sliced and served. Corned beef sandwiches also
were made for
catering
to several groups on March 17; these sandwiches were held at room
temperature
from 11 a.m. until they were eaten throughout the afternoon.
Cultures of two of three
samples
of leftover corned beef obtained from the delicatessen yielded greater
than or equal to 105 colonies of C. perfringens per
gram.
Following the outbreak,
public
health officials recommended to the delicatessen that meat not served
immediately
after cooking be divided into small pieces, placed in shallow pans and
chilled rapidly on ice before refrigerating, and that cooked meat be
reheated
immediately before serving to an internal temperature of greater than
or
equal to 165oF (74 C).
Analysis
C. perfringens is a
ubiquitous,
anaerobic, Gram-positive, spore-forming bacillus and a frequent
contaminant
of meat and poultry.
C. perfringens food poisoning is characterized
by onset of abdominal cramps and diarrhea 8-16 hours after eating
contaminated
meat or poultry. By sporulating, this organism can survive high
temperatures
during initial cooking; the spores germinate during cooling of the
food,
and vegetative forms of the organism multiply if the food is
subsequently
held at temperatures of 60-125oF (16-52oC). If
served without
adequate
reheating, live vegetative forms of C. perfringens may be
ingested.
The bacteria then elaborate the enterotoxin that causes the
characteristic
symptoms of diarrhea and abdominal cramping.
Laboratory confirmation of C.
perfringens foodborne outbreaks requires quantitative cultures of
implicated
food or stool from ill persons. This outbreak was confirmed by the
recovery
of greater than or equal to 105 organisms per gram of
epidemiologically
implicated food. An alternate criterion is that cultures of stool
samples
from persons affected yield greater than or equal to 106
colonies
per gram. Stool cultures were not done in this outbreak.
Serotyping
is not useful for confirming C. perfringens outbreaks and, in
general,
is not available.
Corned beef is a popular
ethnic
dish that is commonly served to celebrate St. Patrick's Day. The errors
in preparation of the corned beef in this outbreak were typical of
those
associated with previously reported foodborne outbreaks of C.
perfringens. Improper
holding temperatures are a contributing factor in most C.
perfringens
outbreaks
reported to CDC. To avoid illness caused by this
organism, food should be eaten while still hot or reheated to an
internal
temperature of greater than or equal to 165oF (74oC)
before serving.
Gas gangrene
Gas gangrene generally occurs at the site of
trauma or a recent surgical wound. The onset of gas gangrene is sudden
and dramatic. About a third of cases occur on their own. Patients who
develop this disease in this manner often have underlying blood vessel
disease (atherosclerosis or hardening of the arteries), diabetes, or
colon cancer.
Clostridium perfringens
produces many
different toxins, four of
which
(alpha, beta, epsilon, iota) can cause potentially deadly syndromes.
The toxins cause damage to tissues, blood cells, and blood vessels.
Gas gangrene is marked by a high fever, brownish pus, gas
bubbles under the skin, skin discoloration, and a foul odor. It is the
rarest form of gangrene, and only 1,000 to 3,000 cases occur in the
United States each year. It can be fatal
if not treated immediately.
Clostridium perfringens,
Gram Stain. Most clostridia are renowned for staining "Gram-variable".
Pathogenic Clostridia, including Botulism and Tetanus (page 1)
(This chapter has 4 pages)
Clostridium botulinum
Clostridia
The genus
Clostridium consists of relatively large, Gram-positive,
rod-shaped
bacteria in the Phylum Firmicutes
(Clostridia is actually a
Class in the Phylum).
All species form endospores
and have a strictly fermentative type of
metabolism.
Most clostridia will not grow under aerobic conditions and vegetative
cells
are killed by exposure to O2, but their spores are able to
survive long
periods of exposure to air.
The clostridia are ancient organisms that live in virtually all of
the
anaerobic habitats of nature where organic compounds are present,
including
soils, aquatic sediments and the intestinal tracts of animals.
Clostridia are able to ferment a wide variety of organic compounds.
They produce end products such as butyric acid, acetic acid, butanol
and
acetone, and large amounts of gas (CO2 and H2)
during fermentation of
sugars.
A variety of foul smelling compounds are formed during the fermentation
of amino acids and fatty acids. The clostridia also produce a wide
variety
of extracellular enzymes to degrade large biological molecules (e.g.
proteins, lipids, collagen, cellulose, etc.) in the
environment
into fermentable components. Hence, the clostridia play an important
role
in nature in biodegradation and the carbon cycle. In anaerobic
clostridial
infections, these enzymes play a role in invasion and pathology.
Most of the clostridia are saprophytes, but a few are pathogenic for
humans, primarily Clostridium
perfringens, C. difficile, C. tetani and C. botulinum. Those that are pathogens
have primarily a saprophytic existence
in nature and, in a sense, are opportunistic pathogens. Clostridium
tetani and Clostridium botulinum produce the most potent
biological
toxins known to affect humans. As pathogens of tetanus and food-borne
botulism,
they owe their virulence almost entirely to their toxigenicity. Other
clostridia,
however, are highly invasive under certain circumstances.
Stained pus from a mixed
anaerobic
infection. At least three different clostridia are apparent.
Clostridium perfringens
C. perfringens
Clostridium perfringens, which produces a huge array of
invasins
and exotoxins, causes wound and surgical infections that lead
to
gas
gangrene, in addition to severe uterine infections.
Clostridial
hemolysins and extracellular enzymes such as proteases, lipases,
collagenase
and hyaluronidase, contribute to the invasive process. Clostridium
perfringens
also produces an enterotoxin and is an important cause of food
poisoning.
Usually the organism is encountered in improperly sterilized (canned)
foods
in which endospores have germinated.
Food poisoning
Clostridium perfringens is classified into 5 types (A�E) on
the basis of its ability to produce one or more of the major lethal
toxins, alpha, beta, epsilon and iota (α, β, ε, and ι). Enterotoxin
(CPE)-producing (cpe+) C.
perfringens type A is reported continuously as one of the most
common food poisoning agents worldwide. An increasing number of reports
also implicate the organism in 5%�15% of antibiotic�associated
diarrhea (AAD) and sporadic diarrhea (SD) cases in humans, as well as
diarrhea cases in animals.
Most food poisoning strains studied carry cpe in their
chromosomes; isolates from AAD and SD cases bear cpe in a
plasmid. Why C. perfringens strains with cpe
located on chromosomes or plasmids cause different diseases has not
been satisfactorily explained. However, the relatively greater heat
resistance of the strains with chromosomally located cpe is a
plausible explanation for these strains' survival in cooked food, thus
causing instances of food poisonings. The presence of C.
perfringens strains with chromosomally located cpe in
1.4% of American retail food indicates that these strains have an
access to the food chain, although sources and routes of contamination
are unclear.
An explanation for the strong association between C. perfringens
strains with plasmid-located cpe and cases of AAD and SD
disease may be in vivo transfer of the cpe plasmid to C.
perfringens strains of the normal intestinal microbiota.
Thus, a small amount of ingested cpe+ C. perfringens
would act as an infectious agent and transfer the cpe plasmid
to cpe� C. perfringens strains of the normal
microbiota. Conjugative transfer of the cpe plasmid has been
demonstrated in vitro, but no data exist on horizontal gene
transfer of cpe in vivo, and whether cpe+ strains
that cause AAD and SD are resident in the gastrointestinal tract or
acquired before onset of the disease is unknown.
Case Study
Report of C. perfringens Food
Poisoning
Clostridium perfringens
is a common cause of outbreaks of foodborne illness in the United
States,
especially outbreaks in which cooked beef is the implicated source.
This
is a condensed version of an MMWR report that describes an outbreak of
C.
perfringens gastroenteritis following St. Patrick's Day meals of
corned
beef. The report typifies outbreaks of C. perfringens food
poisoning.
Report
On March 18, 1993, the
Cleveland
City Health Department received telephone calls from 15 persons who
became
ill after eating corned beef purchased from one delicatessen.
After
a local newspaper article publicized this problem, 156 persons
contacted
the health department to report onset of diarrheal illness within 48
hours
of eating food from the delicatessen on March 16 or March 17. Symptoms
included abdominal cramps (88%) and vomiting (13%); no persons were
hospitalized.
The median incubation period was 12 hours (range: 2-48 hours). Of the
156
persons reporting illness, 144 (92%) reported having eaten corned beef;
20 (13%), pickles; 12 (8%), potato salad; and 11 (7%), roast beef.
In anticipation of a large
demand
for corned beef on St. Patrick's Day (March 17), the delicatessen had
purchased
1400 pounds of raw, salt-cured product. Beginning March 12, portions of
the corned beef were boiled for 3 hours at the delicatessen, allowed to
cool at room temperature, and refrigerated. On March 16 and 17, the
portions
were removed from the refrigerator, held in a warmer at 120oF
(48.8oC), and sliced and served. Corned beef sandwiches also
were made for
catering
to several groups on March 17; these sandwiches were held at room
temperature
from 11 a.m. until they were eaten throughout the afternoon.
Cultures of two of three
samples
of leftover corned beef obtained from the delicatessen yielded greater
than or equal to 105 colonies of C. perfringens per
gram.
Following the outbreak,
public
health officials recommended to the delicatessen that meat not served
immediately
after cooking be divided into small pieces, placed in shallow pans and
chilled rapidly on ice before refrigerating, and that cooked meat be
reheated
immediately before serving to an internal temperature of greater than
or
equal to 165oF (74 C).
Analysis
C. perfringens is a
ubiquitous,
anaerobic, Gram-positive, spore-forming bacillus and a frequent
contaminant
of meat and poultry.
C. perfringens food poisoning is characterized
by onset of abdominal cramps and diarrhea 8-16 hours after eating
contaminated
meat or poultry. By sporulating, this organism can survive high
temperatures
during initial cooking; the spores germinate during cooling of the
food,
and vegetative forms of the organism multiply if the food is
subsequently
held at temperatures of 60-125oF (16-52oC). If
served without
adequate
reheating, live vegetative forms of C. perfringens may be
ingested.
The bacteria then elaborate the enterotoxin that causes the
characteristic
symptoms of diarrhea and abdominal cramping.
Laboratory confirmation of C.
perfringens foodborne outbreaks requires quantitative cultures of
implicated
food or stool from ill persons. This outbreak was confirmed by the
recovery
of greater than or equal to 105 organisms per gram of
epidemiologically
implicated food. An alternate criterion is that cultures of stool
samples
from persons affected yield greater than or equal to 106
colonies
per gram. Stool cultures were not done in this outbreak.
Serotyping
is not useful for confirming C. perfringens outbreaks and, in
general,
is not available.
Corned beef is a popular
ethnic
dish that is commonly served to celebrate St. Patrick's Day. The errors
in preparation of the corned beef in this outbreak were typical of
those
associated with previously reported foodborne outbreaks of C.
perfringens. Improper
holding temperatures are a contributing factor in most C.
perfringens
outbreaks
reported to CDC. To avoid illness caused by this
organism, food should be eaten while still hot or reheated to an
internal
temperature of greater than or equal to 165oF (74oC)
before serving.
Gas gangrene
Gas gangrene generally occurs at the site of
trauma or a recent surgical wound. The onset of gas gangrene is sudden
and dramatic. About a third of cases occur on their own. Patients who
develop this disease in this manner often have underlying blood vessel
disease (atherosclerosis or hardening of the arteries), diabetes, or
colon cancer.
Clostridium perfringens
produces many
different toxins, four of
which
(alpha, beta, epsilon, iota) can cause potentially deadly syndromes.
The toxins cause damage to tissues, blood cells, and blood vessels.
Gas gangrene is marked by a high fever, brownish pus, gas
bubbles under the skin, skin discoloration, and a foul odor. It is the
rarest form of gangrene, and only 1,000 to 3,000 cases occur in the
United States each year. It can be fatal
if not treated immediately.
Clostridium perfringens,
Gram Stain. Most clostridia are renowned for staining "Gram-variable".
Sunday, 13 March 2016
Your Gut Bacteria Linked to Your Risk for Heart Disease
Your Gut Bacteria Linked to Your Risk for Heart Disease
A
new mechanism has been discovered that connects phosphatidyl choline
(also called lecithin), a common dietary fat, along with intestinal
microflora, to an increased risk of heart disease. The study shows that
the heart risk of people with a diet high in the lipid depends on how
the micro-organisms that live in their digestive tracts metabolize it.
When lecithin and choline were fed to mice, the substances were
converted to a heart disease-forming product by the intestinal microbes.
In humans, higher blood levels of choline and the heart disease forming
microorganism products are strongly associated with increased
cardiovascular disease risk.
According to Science Daily:
A
new mechanism has been discovered that connects phosphatidyl choline
(also called lecithin), a common dietary fat, along with intestinal
microflora, to an increased risk of heart disease. The study shows that
the heart risk of people with a diet high in the lipid depends on how
the micro-organisms that live in their digestive tracts metabolize it.
When lecithin and choline were fed to mice, the substances were
converted to a heart disease-forming product by the intestinal microbes.
In humans, higher blood levels of choline and the heart disease forming
microorganism products are strongly associated with increased
cardiovascular disease risk.
According to Science Daily:
“... [D]ifferences in gut flora metabolism of the diet from one
person to another appear to have a big effect on whether one develops
heart disease.”
Dr. Mercola's Comments: |
How Probiotics May Aid Your Weight Management
How Probiotics May Aid Your Weight Management
By Dr. Mercola
By Dr. Mercola
Your gastrointestinal tract houses some 100 trillion bacteria—about two to three pounds worth. In all, the bacteria outnumber your body's cells by about 10 to 1.
Your intestinal bacteria are part of your immune system, and researchers
are discovering that microbes of all kinds play instrumental roles in
countless areas of your health. For example, beneficial bacteria, also
known as probiotics, have been shown to:
Beneficial bacteria also control the growth of disease-causing
- Modulate your immune response and reduce inflammation
- Produce vitamins, absorb minerals, and eliminate toxins
- Control asthma and reduce risk of allergies
- Benefit your mood and mental health
- Boost weight loss
bacteria by competing for nutrition and attachment sites in your colon.
This is of immense importance, as pathogenic bacteria and other less
beneficial microbes can wreak havoc with your health if they gain the
upper hand. It can also affect your weight, as you'll see below.
For all of these reasons, and more, I always recommend a diet rich in
whole, unprocessed foods along with cultured or fermented foods. A
high-quality probiotic supplement can also be a helpful ally to restore
healthful balance to your microbiotia—especially when taking
antibiotics.
The Diet-Bacteria-Weight Connection
Bacterial imbalance in your gut can be made worse by processed foods and
foods that have been pasteurized or sterilized. Other factors affecting
your gut flora include where you live, your age, your stress level, and
any health issues you may have. Like processed foods, sugar also
promotes the growth of disease-causing yeasts and fungi.
Symptoms of a yeast (candida) overgrowth include fatigue, depression,
irritability, headaches, problems concentrating, muscle weakness,
recurrent vaginal and urinary tract infections, athlete's foot, jock
itch, persistent heartburn, indigestion, constipation, swollen joints,
nasal congestion, and sore throat.1
In case you don't have reason enough yet to re-evaluate your sugar and
fructose intake, here's another twist in the sugar-obesity connection:
researchers have discovered a difference in gut bacteria between the
overweight and those of normal weight.2
In the obese, a bacterial strain known as firmicutes is found in much greater abundance than in leaner individuals. In those of normal weight, the bacteroidetes strain is in greater supply.
The firmicutes bacteria appear to be much better than the bacteroidetes
strain at turning calories from complex sugars into fat. As those who
are overweight begin to slim down, the bacterial balance shifts from
predominantly firmicutes to predominantly bacteroidetes.
Research published last year discovered that as much as 20 percent of
the substantial weight loss achieved from gastric bypass, a popular
weight loss surgery, is actually due to shifts in the balance of
bacteria in your digestive tract.3
Bacteria Can Affect Your Food Cravings, and Weight Loss Success
According to the most recent study, a strain of friendly bacteria called Lactobacillus rhamnosus also appears to be quite helpful for weight loss in women.4 As reported in the featured article:
"The controlled clinical trial was set up so that the first 12 weeks
women were guided to eat less food and some were additionally given the
Lactobacillus rhamnosus. After 12 weeks the amount of weight loss was
greater in the group receiving the friendly flora supplement.
As it relates to weight management, one hypothesis states that your gut
Over the next 12 weeks the dietary restrictions were lifted, and the
friendly flora was continued. Those women not taking Lactobacillus
rhamnosus now gained weight, whereas the friendly flora group continued
to lose weight. The weight loss benefit was linked to measurements of
the bacterial profile of the digestive tract. This study is the
latest to show that the balance of power in the digestive tract is a
metabolic variable of high importance and nothing to ignore as part of a
long-term successful weight loss plan."
bacteria may in fact be in control of your appetite. Recent research5
suggests there's a positive-feedback loop between the foods you crave
and the composition of the microbiota in your gut that depend on those
nutrients for their survival. Microbes that thrive on sugar, for
example, can signal your brain to eat more sweets. Other studies6,7
have shown that certain bacteria found in your gut can produce insulin
resistance and weight gain by triggering chronic low-grade inflammation
in your body. Three such culprits include:
Yet another recent study revealed that a breath test of the gases
- Endotoxin-producing Enterobacter8
- Staphylococcus aureus9 (an antibiotic-resistant strain of bacteria)
- The human adenovirus-36 (a cause of respiratory infections and pinkeye)
given off by your gut bacteria might actually be able to predict your
likelihood of becoming obese. The study found that people with high
levels of hydrogen and methane in their breath are more likely to have a
higher body-mass index (BMI) and proportion of body fat.10
This, the researchers believe, may be because the related gut bacteria
influence your body's ability to extract calories from food, leading to
weight gain.
Diets, Not Borders, Dictate Gut Bacteria
It's important to understand that while your gut microbes may have a
tremendous say in you bodily processes, YOU are ultimately in control of
your intestinal microflora—through the foods you eat. Science News11
recently ran an article about how local diets dictate the bacterial
balance found in residents. For example, despite living on opposite ends
of the Earth, people in Malawi and the Guahibo of Venezuela have
similar microbial makeup, courtesy of the similarities between their
native diets.
One of the primary differences between the diets is meat consumption.
"Americans, on the other hand, have a distinctive microbiome with about 25 percent less diversity than indigenous Venezuelans," the article states.
Malawian and Guahibo diets are high in corn and cassava, with an
occasional piece of meat. Americans, on the other hand, are far more
carnivorous, and also eat far more bread, lettuce and tomatoes,
potatoes, pasta, milk and dairy products. The microbial makeup of the
three groups reveals these dietary differences. Needless to say,
altering your diet has a direct impact on the microbial community
residing in your gut—for better or worse. According to Science News:12
"A more recent study found that major diet shifts can change the mix of gut microbes noticeably in just a day.
Omnivores switching to a diet of all animal products saw the biggest
change, as some bacteria boomed and others declined. Microbes settled
back to their previous profiles a day or two after subjects returned to
their usual diets..." [Emphasis mine]
A More Complete Understanding of the Gut Could Change Modern Medicine...
There are three major collaborative efforts underway that help deepen our understanding of the human microbiome:
So far, the NIH's Human Microbiome Project alone has produced 190
- The International Human Microbiome Consortium13
- The US National Institute of Health's Human Microbiome Project14
- The American Gut Project
scientific papers, along with a repository of resources that scientists
can access to explore the relationships between human gut bacteria and
disease. The American Gut Project decided to take it a step further by
allowing the American public to participate.15
All the gathered information from this project will eventually be made
public. It's an extremely ambitious project seeking to identify the
parameters for the ideal gut flora, and how your diet affects it.
What's particularly exciting about the American Gut Project is the fact
that it will allow us to really evaluate and compare the effects of a
very diverse conglomeration of lifestyles. Scientific studies almost
always focus on carefully chosen groups of people who are studied for a
specific purpose, typically to confirm or debunk a hypothesis. This
project, on the other hand, will crack the lid open on the effects on
gut flora of a myriad of lifestyle choices, by people of all ethnicities
and ages.
If we can better understand how diet and lifestyle—whether by choice or
necessity—affect your microbial makeup, doctors may eventually be able
to precisely address health problems and disease through dietary
prescriptions known to shift the microbial population in one direction
or another.
Diet and Lifestyle Dos and Don'ts
Granted, I don't see any point in waiting for such
confirmations. The fundamentals are already quite well understood, and
include a rather concise list of dos and don'ts. When it comes to diet,
you want to eat mostly whole, fresh, unadulterated foods,
taking pains to avoid sugars and processed/pasteurized and genetically
engineered foods of all kinds. Add to that a healthy amount of
traditionally fermented foods each day and you're off to a good start.
A strong case can be made for eating organic to protect your gut flora
as agricultural chemicals take a heavy toll on beneficial microbes—both
in the soil in which the food is grown, and in your body. Glyphosate
(Roundup), used in particularly hefty amounts on genetically engineered
crops, appears to be among the worst of the most widely used chemicals
in food production. As for general lifestyle advice, you'll want to
avoid well-known culprits that kill beneficial bacteria, such as:
- Antibiotics (also note that most store-bought beef typically comes from cattle raised with antibiotics. To avoid getting a low dose of antibiotics in every piece of meat you eat, make sure your meat is grass-fed and finished)
- Chlorinated water
- Antibacterial soap
- Pollution
Foods 'for Life'
In contrast to the pesticide effect of processed foods and sugar on the
state of your health, fermented foods act as natural fertilizers, if you
will—providing nutrients and promoting growth of healthy bacteria in
your digestive tract. For ages, humans have used fermented foods to
improve intestinal health. As an added boon, fermented foods are also
some of the best chelators and detox agents available, meaning they can
help rid your body of a wide variety of toxins, including heavy metals
and pesticides. Examples of healthy fermented foods include:
- Sauerkraut, pickles, and other fermented vegetables
- Fermented dairy products, such as yoghurt and kefir made from raw (unpasteurized) dairy
- Miso
- Tempeh
- Olives
To Be 'Alive,' the Food Must Be Unprocessed and Not Pasteurized...
It is important to note that traditionally fermented foods are not the
equivalent of the same foods, commercially processed and pasteurized.16 Fortunately, preparing your own fermented foods
at home is quite easy, and very cost effective. For instructions,
please see my previous interview with Caroline Barringer, a Nutritional
Therapy Practitioner (NTP), and an expert in the preparation of the
gut-nourishing foods prescribed in Dr. Natasha Campbell-McBride's Gut
and Psychology Syndrome (GAPS) Nutritional Program.
Caroline recommends eating about a quarter to half a cup (2 to 4 oz) of
fermented vegetables or other cultured food, such as raw yoghurt, with
one to three meals per day. Bear in mind that since cultured foods are
efficient detoxifiers, you may experience detox symptoms if you
introduce too many at once. So start with very small servings—as little
as a teaspoon of fermented vegetables, for example, or even just a spoon
or two of the juice—and slowly work your way up to the quarter to half
cup serving size. This way your intestinal microbiota has the chance to
adjust.
For Optimal Health, Pay Attention to Your Gut
Two things are clear:
Maintaining a good balance of gut bacteria through diet is one of the
- Sufficient amounts of friendly bacteria are fundamental to your good
health. It's impossible to be optimally healthy if your gut's bacterial
balance is out of whack.- Your lifestyle –your diet, medications, the antibacterial cleansers
you use, and other factors outside your control – are working together
to compromise the number of lifesaving friendly bacteria in your
digestive system.
most important things you can do to increase your chances of remaining
healthy and vital for a lifetime. Remember, a gut-healthy diet is one
that is rich in whole, unprocessed, unsweetened foods, along with
traditionally fermented or cultured foods. And, although I'm not a major
proponent of taking many supplements (as I believe the majority of your
nutrients need to come from food), probiotics is an exception if you
don't eat fermented foods on a regular basis.
Alcoholism linked to lack of intestinal bacteria | ScienceNordic
Alcoholism linked to lack of intestinal bacteria | ScienceNordic
A new study suggests that bacteria in the gut may play a role in alcohol addiction and the risk of relapse after rehab.
"Our
results provides strong evidence that alcohol addiction is not only in
the brain, but that it in some cases can be associated with an imbalance
in the intestinal flora,” said Professor Fredrik Bäckhed from the
University of Gothenburg during a guest lecture at Novo Nordisk
Foundation Center for Basic Metabolic Research at Copenhagen University.
The 60 alcoholics in the study had an equal use of alcohol.
After
the test participants had spent 19 days in rehab it became apparent to
the scientists that there was a big difference in how well the
participants recovered: their well-being and risk of relapse was
connected to their gut flora.
26 out of the 60 alcoholics suffered
from leaky gut syndrome and generally had a low amount of intestinal
bacteria -- specially their levels of Faecalibacterium prausnitzii,
which is known for its anti-inflammatory properties, were detected as
unusually low. The leaky gut syndrome is linked to inflammation of the
gut and diseases like Crohn disease.
After 19 days without alcohol
the 26 test subjects still scored high on tests that measuered
depression, anxiety, and alcohol cravings. There was in fact not much
difference from before they went to rehab.
In comparison, the
remaining 34 subjects with normal gut flora were recovering much better,
scoring low on depression, anxiety, and alcohol cravings. In fact,
their scores decreased to levels comparable with the control group who
didn't have a drinking problem.
On the basis of these results the
scientists concluded that intestinal flora is connected to the
likelihood of relapse after sobering up in rehab.
Bäckhed hopes that the study will lead to new treatment possibilities for alcoholics where the intestinal flora is considered.
"It
appears that some alcoholics may need a different treatment than
others. The study has an interesting treatment potential,“ he said.
Schaffalitzky, head of research at the department of gastroenterology,
University of Southern Denmark, is not entirely convinced that the new
study shows a link between intestinal bacterial flora and alcohol
addiction. He was not involved in the study, but has read it.
“The study does indeed show a correlation, however, this doesn't necessarily prove anything," said Schaffalitzky.
Even
though there is some overlap it does not prove that there is a
connection between intestinal flora and increased alcohol addiction, he
says.
“There can be other explanatory factors which the study does
not account for. It may be that the test subjects have a special
drinking pattern or diet, have other illnesses, have a special gut or
something else. There are many uncertain points in the hypothesis,” said
Schaffalitzky.
certain that there is a link between the bacteria in the gut and alcohol
addiction, he also stresses that there is a need for more studies,
before we can understand the exact relation.
“It's the first time
we have shown that there is a correlation between alcohol craving and
bacterial gut composition. Previously studies with mice have produced
similar results," said Bäckhed. "However, we still don't know how the
connection between the gut and the brain works."
October 20, 2014 - 06:23
New study suggests connection between the gut flora and addiction to alcohol.
It
could be that some alcoholics have a particularly hard time quitting
the alcohol because they have fewer intestinal bacteria than other
people. (Photo: Shutterstock)
could be that some alcoholics have a particularly hard time quitting
the alcohol because they have fewer intestinal bacteria than other
people. (Photo: Shutterstock)
"Our
results provides strong evidence that alcohol addiction is not only in
the brain, but that it in some cases can be associated with an imbalance
in the intestinal flora,” said Professor Fredrik Bäckhed from the
University of Gothenburg during a guest lecture at Novo Nordisk
Foundation Center for Basic Metabolic Research at Copenhagen University.
Some alcoholics have fewer intestinal bacteria
In the study, which was recently published in the journal PNAS, Bäckhed and his colleagues from Belgium and Sweden have analysed the intestinal bacteria composition of 60 alcoholics.The 60 alcoholics in the study had an equal use of alcohol.
After
the test participants had spent 19 days in rehab it became apparent to
the scientists that there was a big difference in how well the
participants recovered: their well-being and risk of relapse was
connected to their gut flora.
26 out of the 60 alcoholics suffered
from leaky gut syndrome and generally had a low amount of intestinal
bacteria -- specially their levels of Faecalibacterium prausnitzii,
which is known for its anti-inflammatory properties, were detected as
unusually low. The leaky gut syndrome is linked to inflammation of the
gut and diseases like Crohn disease.
After 19 days without alcohol
the 26 test subjects still scored high on tests that measuered
depression, anxiety, and alcohol cravings. There was in fact not much
difference from before they went to rehab.
In comparison, the
remaining 34 subjects with normal gut flora were recovering much better,
scoring low on depression, anxiety, and alcohol cravings. In fact,
their scores decreased to levels comparable with the control group who
didn't have a drinking problem.
On the basis of these results the
scientists concluded that intestinal flora is connected to the
likelihood of relapse after sobering up in rehab.
Bäckhed hopes that the study will lead to new treatment possibilities for alcoholics where the intestinal flora is considered.
Our results strongly suggest that alcohol addiction is not only a problem which starts in the brain
appears that some alcoholics may need a different treatment than
others. The study has an interesting treatment potential,“ he said.
Professor: The study does not prove a connection
Professor OveSchaffalitzky, head of research at the department of gastroenterology,
University of Southern Denmark, is not entirely convinced that the new
study shows a link between intestinal bacterial flora and alcohol
addiction. He was not involved in the study, but has read it.
“The study does indeed show a correlation, however, this doesn't necessarily prove anything," said Schaffalitzky.
Even
though there is some overlap it does not prove that there is a
connection between intestinal flora and increased alcohol addiction, he
says.
“There can be other explanatory factors which the study does
not account for. It may be that the test subjects have a special
drinking pattern or diet, have other illnesses, have a special gut or
something else. There are many uncertain points in the hypothesis,” said
Schaffalitzky.
The brain-gut connection is still not clear
Although Bäckhed iscertain that there is a link between the bacteria in the gut and alcohol
addiction, he also stresses that there is a need for more studies,
before we can understand the exact relation.
“It's the first time
we have shown that there is a correlation between alcohol craving and
bacterial gut composition. Previously studies with mice have produced
similar results," said Bäckhed. "However, we still don't know how the
connection between the gut and the brain works."
Clostridia: This Gut Bacteria Protect Against Food Allergies
Clostridia: This Gut Bacteria Protect Against Food Allergies
By Dr. Mercola
variety of environmental factors and lifestyle choices, for better or
worse. Spending time in the hospital increases your risk of acquiring
something while there. A ten day stay means a 10 % chance of catching
something.
Some of the factors posing the gravest dangers to your microbiome include:
As noted in a recent BBC News report,13
lack of exposure to the outdoors can in and of itself cause your
microbiome to become “deficient.” After tracking the whereabouts of two
families for 24 hours, researchers found the family members spent on
average 91 percent of their time indoors. This trend may in fact be one
of the driving factors behind rising allergy statistics in the modern
world—in short; we’re underexposed to beneficial bacteria that human
beings used to get from the earth itself. According to the BBC:
“[A]rguably, the easiest thing for all of us to do to reduce our
chances of becoming allergic is to go outside. Whether it is walking the
dog or strolling to school, the evidence suggests that being outside
and taking a good deep breath of fresh air is good for you. One study
has even found that if you have more plants and flowers around your
house you are not only more likely to have a diverse array of bacteria
on your skin, you are also less likely to be allergic.
Professor Graham Rook, of University College London, calls these
bacteria our ‘old friends,’ and has no doubt of their importance to our
health. He says: ‘In a way, this realization that humans are in fact
ecosystems and that we depend so much on these microorganisms is
probably the most important advance in medicine in the last hundred
years.’"
By Dr. Mercola
Your body’s microbiome—colonies of various microbes that reside in
your gut and elsewhere in and on your body—is as unique to you as your
fingerprint.
It varies from person to person based on factors such as diet,
lifestyle, health history, geographic location, and even ancestry. Your microbiome is in fact one of the most complex ecosystems on the planet.
In terms of ratios, your bacteria outnumber your body’s cells by 10 to
1, and viruses outnumber bacteria 10 to 1! So not only is your body the
home of 100 trillion bacteria, you also house about one quadrillion
viruses (bacteriophages).
All of these organisms perform a multitude of functions in key
biological systems, and need to be properly balanced and cared for in
order to maintain good health.
For example, your gut bacteria influence your immune responses, nervous
system functioning, and play a role in the development of any number of
diseases, including food allergies, as demonstrated by recent research.
Allergies are on the Rise Across the Western World
Food allergies affect some 15 million Americans, including one in 13
children. Disturbing statistics also point out that potentially deadly
food allergies are on the rise. For example, between 1997 and 2011
alone, food allergies in children rose by 50 percent!
Inner-city kids are at greatest risk. In one study,1
10 percent of children raised in large cities developed a food allergy
before the age of five. Twenty-nine percent developed food sensitivity.
The most common food allergy was peanuts (6 percent), followed by eggs
(4.3 percent), and pasteurized milk (2.7 percent).
City dwellers also have a heightened risk of asthma and other
environmental allergies. Similarly, in Great Britain one in three people
is allergic to something, be it pollen, dust mites, or food.2
Previous research has drawn parallels between the rise in allergies and increased antibiotic and antimicrobial use. According to British researchers,3 exposure to antibiotics early in life may increase your child’s risk of developing eczema by 40 percent.
Other scientists have clearly shown how genetically engineered foods and the use of the agricultural herbicide glyphosate destroys gut bacteria and promotes allergies. One recent study adds further credence to the disturbed microbiome hypothesis.
Certain Gut Bacteria Protect Against Food Allergies
The study,4, 5 which used mice, found that a common gut bacteria called Clostridia helps prevent sensitization to food allergens. In fact, immune responses to food allergens were reversed once Clostridia bacteria were put back into the mice.
Another common type of gut bacteria, Bacteroides, did not have this effect, suggesting Clostridia may have a unique role in this regard.
Using genetic analysis, the researchers determined that Clostridia
instructs immune cells to produce a signaling molecule called
interleukin-22 (IL-22), which is known to reduce the permeability of the
lining in your intestines.
In other words, it helps prevent leaky gut syndrome—a condition that
allows allergens to enter your bloodstream, thereby producing an immune
response. The researchers suggest this discovery may eventually lead to
probiotic therapies to treat food allergies. As reported by
HealthCanal.com:6
“By inducing immune responses that prevent food allergens from
entering the bloodstream, Clostridia minimize allergen exposure and
prevent sensitization -- a key step in the development of food
allergies...
Although the causes of food allergy... are unknown, studies have
hinted that modern hygienic or dietary practices may play a role by
disturbing the body's natural bacterial composition...
‘Environmental stimuli such as antibiotic overuse, high fat diets,
caesarean birth, removal of common pathogens and even formula feeding
have affected the microbiota with which we've co-evolved,’ said study
senior author Cathryn Nagler, PhD, Bunning Food Allergy Professor at the
University of Chicago.
‘Our results suggest this could contribute to the increasing susceptibility to food allergies.’"
Early Disruption of Gut Flora May Also Promote Metabolic Problems
In addition to an increased risk for allergies, early disruption of your
microbiome can also have long-term effects on your metabolism. One
recent study suggests that exposing infants to antibiotics may in fact
predispose them to obesity.
The study, published in the journal Cell,7, 8
points to there being a window of time when changes to the microbiome
can have a serious and long-term impact on your body’s metabolism.
This window was the first month of life in mice. Translating that to a
human time scale—provided the effect fully applies to humans—it would
correlate to a time frame of the first six months; potentially up to the
first three years. Mice given antibiotics for the first four weeks of
life grew up to be 25 percent heavier, and had 60 percent more body fat
than the controls.
The researchers identified four specific species of gut bacteria that
appeared to be of particular importance with regards to metabolism: Lactobacillus, Allobaculum, Rikenelleceae, and Candidatus arthromitus (the last one is not found in humans).
Eradicating these four species of bacteria in the mice’s guts triggered metabolic changes that led to obesity. As reported by The Guardian:9
“The findings... build on earlier work that found children who had
antibiotics before six months of age were more likely to be overweight
as seven-year-olds.
‘This is part of a growing body of evidence that antibiotics have a
biological cost,’ said Martin Blaser, a microbiologist who led the study
at New York University. ‘Our study shows that there can be permanent
consequences.’
‘If a kid is very ill, there is no question that they should get
antibiotics, but if it's marginal perhaps the doctor should be saying
'let's wait a day or two' before taking another look.
Doctors give out antibiotics thinking they won't do any harm, but
this provides evidence that they might,’ Blaser added... ‘We found that
four weeks of antibiotics was enough to perturb the microbiome, and even
though it returned to normal after a few weeks, the mice still became
fat.’”
Altering Your Microbiome Is Easy with the Appropriate Dietary Changes
The best way to optimize your gut flora is through your diet. First, you’ll want to make sure to avoid:
A gut-healthy diet is one rich in whole, unprocessed, unsweetened
- Grains and sugar,
as it promotes the growth of pathogenic yeast and other fungi. Grains
containing gluten are particularly damaging to your microflora and
overall health.10, 11- Genetically engineered foods, as they contain some of the highest amounts of glyphosate. This agricultural herbicide has been found to decimate microbes, and tend to preferentially attack beneficial bacteria
- Processed and pasteurized foods, which harm your good bacteria
- Conventionally-raised meats and other animal products; CAFO animals are routinely fed low-dose antibiotics and GE livestock feed
- Chlorinated tap water, as chlorine kills not only pathogenic bacteria in the water but also beneficial bacteria in your gut
foods, along with traditionally fermented or cultured foods. Fermented
foods are also a key component of the GAPS
protocol, a diet designed to heal and seal your gut. Your goal should
be to consume one-quarter to one-half cup of fermented veggies with each
meal, but you may need to work up to it. Consider starting with just a
teaspoon or two a few times a day, and increase as tolerated. If that is
too much (perhaps your body is severely compromised), you can even
begin by drinking a teaspoon of the brine from the fermented veggies, which is rich in the same beneficial microbes.
The video above is an extensive interview with Dr. McBride who is the
Russian neurologist that developed the GAPS diet. You may also want to
consider a high-potency probiotic supplement, but realize that there is
no substitute for the real food. A previous article in the Journal of Physiological Anthropology12
makes the case that properly controlled fermentation amplifies the
specific nutrient and phytochemical content of foods, thereby improving
health.
Other Environmental Factors That Affect Your Microbiome
Besides an inappropriate diet, your microbiome is also affected by avariety of environmental factors and lifestyle choices, for better or
worse. Spending time in the hospital increases your risk of acquiring
something while there. A ten day stay means a 10 % chance of catching
something.
Some of the factors posing the gravest dangers to your microbiome include:
Antibiotics (use only if absolutely necessary, and make sure to reseed your gut with fermented foods and/or a good probiotic supplement) | NSAIDs (Nonsteroidal anti-inflammatory drugs) damage cell membranes and disrupt energy production by mitochondria) | Proton pump inhibitors (drugs that block the production of acid in your stomach, typically prescribed for GERD, such as Prilosec, Prevacid, and Nexium) |
| Antibacterial soap | Stress | Pollution |
lack of exposure to the outdoors can in and of itself cause your
microbiome to become “deficient.” After tracking the whereabouts of two
families for 24 hours, researchers found the family members spent on
average 91 percent of their time indoors. This trend may in fact be one
of the driving factors behind rising allergy statistics in the modern
world—in short; we’re underexposed to beneficial bacteria that human
beings used to get from the earth itself. According to the BBC:
“[A]rguably, the easiest thing for all of us to do to reduce our
chances of becoming allergic is to go outside. Whether it is walking the
dog or strolling to school, the evidence suggests that being outside
and taking a good deep breath of fresh air is good for you. One study
has even found that if you have more plants and flowers around your
house you are not only more likely to have a diverse array of bacteria
on your skin, you are also less likely to be allergic.
Professor Graham Rook, of University College London, calls these
bacteria our ‘old friends,’ and has no doubt of their importance to our
health. He says: ‘In a way, this realization that humans are in fact
ecosystems and that we depend so much on these microorganisms is
probably the most important advance in medicine in the last hundred
years.’"
Deadly gut bacteria could eradicate food allergies, researchers reveal | Daily Mail Online
Deadly gut bacteria could eradicate food allergies, researchers reveal | Daily Mail Online
Bacteria from a family that includes potentially deadly infectious bugs may protect against food allergies, research has shown.
Clostridia encompasses around 100 bacterial species, some of which live harmlessly in the gut.
Others are responsible for gangrene, tetanus, botulism food poisoning and hospital infections caused by Clostridium difficile.
Gut bacteria hold the key to beating food allergies, researchers say
The
new study suggests that 'friendly' Clostridia have a unique ability to
block the harmful immune response behind food allergies.
new study suggests that 'friendly' Clostridia have a unique ability to
block the harmful immune response behind food allergies.
Tests
on 'sterile' mice sensitised to peanuts showed that introducing a
Clostridia cocktail into their bacteria-free guts reversed their
allergy.
on 'sterile' mice sensitised to peanuts showed that introducing a
Clostridia cocktail into their bacteria-free guts reversed their
allergy.
Re-introduction of another major group of gut bacteria, Bacteroides, did not have the same effect.
Tests
indicated that Clostridia caused immune cells to produce high levels of
a signalling molecule known to decrease permeability of the intestinal
lining.
indicated that Clostridia caused immune cells to produce high levels of
a signalling molecule known to decrease permeability of the intestinal
lining.
This in turn reduced the chances of allergens - molecules that trigger an allergic reaction - leaking into the bloodstream.
US
lead scientist Professor Cathryn Nagler, from the University of
Chicago, said: 'We've identified a bacterial population that protects
against food allergen sensitisation.
lead scientist Professor Cathryn Nagler, from the University of
Chicago, said: 'We've identified a bacterial population that protects
against food allergen sensitisation.
'The
first step in getting sensitised to a food allergen is for it to get
into your blood and be presented to your immune system. T
first step in getting sensitised to a food allergen is for it to get
into your blood and be presented to your immune system. T
'he presence of these bacteria regulates that process.'
Environmental
effects on gut flora - including over-use of antibiotics, high fat
diets, excessive hygiene and even infant formula feeding - may be
contributing to food allergies by suppressing Clostridia, the
researchers believe.
effects on gut flora - including over-use of antibiotics, high fat
diets, excessive hygiene and even infant formula feeding - may be
contributing to food allergies by suppressing Clostridia, the
researchers believe.
Share this article
Their findings appear in the journal Proceedings of the National Academy of Sciences.
Mice
used in the study were either raised from birth in sterile conditions
or treated with antibiotics as newborns to wipe out most of their gut
bacteria.
used in the study were either raised from birth in sterile conditions
or treated with antibiotics as newborns to wipe out most of their gut
bacteria.
Both
groups were sensitised by exposing them to peanut allergens, triggering
a strong immune response. They produced significantly higher levels of
peanut-targeting antibodies than mice with normal populations of gut
bacteria.
groups were sensitised by exposing them to peanut allergens, triggering
a strong immune response. They produced significantly higher levels of
peanut-targeting antibodies than mice with normal populations of gut
bacteria.
When
Clostridia was present, immune cells generated high levels of the
protective signalling molecule, interleukin 22 (IL-22). But when IL-22
was neutralised, levels of allergen in the animals' bloodstreams
significantly increased.
Clostridia was present, immune cells generated high levels of the
protective signalling molecule, interleukin 22 (IL-22). But when IL-22
was neutralised, levels of allergen in the animals' bloodstreams
significantly increased.
The team has already been able to reverse peanut allergies in mice
The team is now working on turning the discovery into a probiotic food allergy treatment, and has filed a provisional patent.
'It's
exciting because we know what the bacteria are; we have a way to
intervene,' said Prof Nagler. 'There are of course no guarantees, but
this is absolutely testable as a therapeutic against a disease for which
there's nothing.
exciting because we know what the bacteria are; we have a way to
intervene,' said Prof Nagler. 'There are of course no guarantees, but
this is absolutely testable as a therapeutic against a disease for which
there's nothing.
'As a mom, I can imagine how frightening it must be to worry every time your child takes a bite of food.'
Between 6% and 8% of children in the UK are believed to have a diagnosed food allergy.
Since 1990, the number of annual UK hospital admissions due to food allergy reactions has soared by 500%.
Severe
food allergy can cause anaphylaxis, an extreme immune reaction that may
prove fatal. Common triggers for anaphylaxis include peanuts, tree nuts
such as almonds, walnuts and cashews, sesame, fish, shellfish, dairy
products and eggs.
food allergy can cause anaphylaxis, an extreme immune reaction that may
prove fatal. Common triggers for anaphylaxis include peanuts, tree nuts
such as almonds, walnuts and cashews, sesame, fish, shellfish, dairy
products and eggs.
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