Friday, June 14, 2013

Fast Diet

Gastric Bypass II


Andre Willers
14 Jun 2013
 
Synopsis :
Diabetes II can be cured by diet that alters gut fauna .
 
Discussion :
1.Existence Theorem : See appendix A
It has been done .
 
2. Theory :
See appendix B .
Prolactins play  key role .
Too much lactose and the lactose <-> prolactin balance is disturbed. More than 300 cellular systems are affected . Bad things happen .
An example of an incomplete evolutionary system (ie utilizing lactose , a mammalian food evolved only for babies .)
 
3. The easiest way is simply to drink maas  http://www.firstchoice.co.za/products/amasi
The fermentation removes most of the lactose .
Or drink Woolworth’s Lactose free milk .
But then other prolactin-like markers will be missing .
 

4.Better yet :
The Amasi cocktail : see appendix C
20% Amasi
80% Lactose free milk .
A dash of cinnamon and turmeric.
Alcohol to taste .
Coffee ad hoc .
 
5. Interesting aside :
The Fasting diet . Eat as you like for 5 days, then fast for two .
Very old . Saturday and Sunday . No work , reduced food .
 
6.Put the diet on fast forward :
6.1 Everyday , flip a coin “Shall I decide today to fast(Y/N)”
6.2 If N , eat what you like . If Y , flip again “ Shall I fast today ? (Y/N)”
If N , eat . if Y , reduce calories . ie fast .
This means on average per week , 7*1/2*1/2 = 1.75 days of fasting .
But predictably randomly fasting .  
The body treats this as normal hunter-gatherer chance . It makes the body leaner , to be more successful in the hunt . 
 
This randomizes the fasting . Normally this would mean the body gathering reserves (ie getting fatter) .
But , the body-mind knows this is not a long-term drought . It needs more nimbleness , and less fat .
The whole leveraging thingie goes into reverse leveraging .
Drinking amasi or lactose free milk will accelerate the effect .
 
 
7.Pulsations :
Pulsing an anti-acid (kidney regenerator) like a teaspoon of sodium bicarbonate , followed by Amazi and a good pro-biotic on a fasting day will accelerate things .

The effect is cumulative as only beneficial gut-bacteria survive .
The memory of the gut .
  
Thinly yours

Andre
 

Xxxxxxxxxxxxx

Appendix C

AMASI
This proudly South African fermented milk product has a smooth, creamy, slightly sour taste. A much-loved tradition in most South African cultures, First Choice Amasi is made by adding a freeze dry culture to the milk and then fermenting it until it reaches a specific acidity level. Our Amasi comes in 1 litre and 2 litre jugs.
NUTRITIONAL INFORMATION (per 100ml)
Energy
289kJ
Protein
3.3g
Glycaemic Carbohydrate of which:
Total sugar:
Total fat: 

5g
4g
Calcium
120mg



xxxxxxxxxxxxxxxxxx
Appendix A

Gut bacteria swap is key to knifeless gastric bypass
·         18:00 27 March 2013 by Douglas Heaven NewScientist .
·         For similar stories, visit the Micro-organisms and Food and Drink Topic Guides
A bacterial cocktail could soon offer a knifeless alternative to gastric bypass surgery.
The gastric bypass limits a person's food intake by, in effect, reducing the size of the stomach – often to the size of a walnut. The procedure is an effective treatment for obesity and associated diseases such as type 2 diabetes, and typically leads to a loss in excess body weight of between 65 and 75 per cent. However, it carries a high mortality risk, especially in severely obese individuals.
Lee Kaplan at Massachusetts General Hospital in Boston and colleagues may have discovered an alternative to surgery. The team performed a gastric bypass on mice and then fed microbes from their lower intestine to other healthy mice. The mice fed the bacterial cocktail lost five per cent of their body weight in two weeks, compared with mice on the same diet who had not been fed the bacteria.
This work is a big step towards a "knifeless bypass", says Carel le Roux at University College Dublin, Ireland, who was not involved in the study. He says that although the gastric bypass cuts calorie intake, it also leads to subtle physiological effects, such as changes in gut bacteria, hormones, bile acids and nerve connections. "It changes how the gut talks to the brain," says le Roux.
It is not yet clear exactly why giving mice gut bacteria from mice that have had a bypass leads to weight loss. The researchers suggest that the gut bacteria present following surgery may reduce the ability of the intestines to absorb calories, or may alter signals regulating metabolism. The goal is to understand what these microbes are doing and duplicate the effects by other means, le Roux says.
Swapping gut bacteria isn't unprecedented as a treatment. In 2010, an 89-year-old woman with a potentially fatal infection received what is known as afaecal transplant from her son. With 24 hours, her fever had abated and the infection soon disappeared. Similar transplants have been successful inminimising symptoms of Parkinson's, multiple sclerosis, chronic fatigue syndrome and rheumatoid arthritis.
Journal reference: Science Translational Medicine, DOI: 10.1126/scitranslmed.3005687
Xxxxxxxxxxxxxxxxxxxx
 
Appendix B
A Cure for Diabetes
Andre Willers
31 May 2012
Synopsis :
The control-system short-circuit that causes diabetes can be interrupted in humans by a simple surgical procedure . This cures diabetes , insulin resistance and high blood pressure . We try to trace why .
Discussion :
1.Read Appendix I . This is a succinct summation of the state–of-play as at May 2012 .
2.Why should bypassing the duodenum have such drastic effects ?
Because the system outsmarted itself . Too many vital feedback loops are being controlled by the same chemicals . (A similar effect is observed in brain-stress and body-stress systems) . Inappropriate responses are triggered . The system is unstable .
2.1Peristaltic action in the duodenum is accompanied by vasoactive intestinal peptide (VIP) release, a marker for inhibitory neurotransmitter release . See Appendix III . (Note the effect on blood pressure )
But this and PHI release (see Appendix II) affect the Prolactin system ,(see http://en.wikipedia.org/wiki/Prolactin ) which is tied to at least 300 other biochemical processes , as well as the prion system (see http://andreswhy.blogspot.com “Prions and the Amygdala” May 2012) .
This whole mess is an unstable system , that can and does go wrong in a large number of ways . And the original trigger can be impossible to trace .
2.2To add insult to injury , the original trigger can cause an amygdala reaction : ie a memory remains in the system , and there few , if any , “OFF” switches . Hence nasties like insulin resistance . There are doubtlessly many more . Amygdala’s are notoriously stupid . It is the function of other systems to reprogram them .
See Appendix IV for the ratchet-effect on bloodpressure .
2.3Milk and milk-products can be identified as one of the factors that should cause the system to destabilise .Lactogen breakdown products interfere with some of the feedback loops in the energy metabolism . The result will be idiosyncratic according to individual metabolism , but insulin resistance will ratchet up . (A calf-protection system short-circuits)

What to do ?
Surgery seems a bit drastic . All we want to do is inhibit peristalsis in the duodenum . Food can be massaged through to the jejenum . I can’t find a drug that does this selectively , but I am sure there are some .
But in the meantime we are stuck with something like Loperamide (Imodium) . It is like stopping an enormous factory to fix some small problem at the front-end of the production lines .
The following is not medical advice , and you proceed at your own peril .
Use the pulse principle .
1.Fast until the duodenum is empty , (+-6 hours) . No water .
2.Take Loperimide (Imodium) .. This stops peristalsis and release of neuro-markers .
3.Exercise (walking , jogging – this moves food without peristalsis ) . I have no idea what effect this will have on digestion . But no lying in bed allowed .
4.Then eat and drink mildly on low-carb foods . Appetite will be sharply decreased as alternate demand pathways kick in (Cf Atkins , etc) . Drink when thirsty (cf Noakes) . No milk products of any kind .Verboten
5. How often ? I noticed when writing this that this regimen is remarkably similar to religious regimens like Ramadan , Jewish , Christian , Hindu and Buddhist fasts . Two weeks to a month per year seems adequate . This should reprogram some of the systems to at least a modicum of initial states .
6.Monitor blood glucose about 2 hours after eating .
Interesting Asides :
1.Excessive alcohol intake paralyses the pylorus valve between the stomach and the duodenum . The same effect as fasting , in that food does not enter the duodenum to trigger peristalsis . Typically bloated feeling , with big “beer bellies” . Since alcohol is a product of carbohydrates , this is a fascinating adaptation to high carbohydrate intake .
To put it another way , agricultural farming only took off because periodic alcoholic binges enabled re-normalization of glycemic systems . As this dwindled , so diabetes increased .
2.Milk and Cheese : as use of these increased , systems increasingly crashed in the Prolactin areas . Energy metabolisms became unstable , and auto-immune diseases increased .And you can’t reinstate the original system simply by stopping milk products : amygdala’s have to be reprogrammed .
These are but the a sketch of the bare bones of complex mechanism . But at least some indication of where to go or where not to go .
But I refuse to countenance a system that does not allow toasted cheese sandwiches .
There must be a better way .
Andre .
xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx
Appendix I
Cristina Iaboni had the dubious distinction of being not quite obese enough. For all the pounds on her 5'5" frame, she did not meet the criteria for bariatric surgery to help control her type 2 diabetes.
Yet six years of medications and attempts at healthy living had failed to rein in her blood glucose, leaving Iaboni terrified that she was on course to have her kidneys fail "and my feet cut off" -- common consequences of uncontrolled diabetes.
Then the 45-year-old Connecticut wife, mother of two and head of human resources for a Fortune 500 company, lucked out. In 2009 she met with Dr Francisco Rubino of Weill Cornell Medical Center in New York. He had just received approval to study experimental surgery on diabetics with a relatively lean weight-to-height ratio, or body-mass index (BMI). Iaboni was among his first subjects.
Three years on, she has dropped 50 pounds to reach a healthy 145 and has normal blood pressure without medication. That isn't too surprising: Weight loss is the purpose of bariatric surgery and often reduces blood pressure. More remarkable, Iaboni no longer has diabetes.
She is not the first patient with diabetes, which can be triggered by obesity, to be cured by weight-loss surgery. But she is a rarity for having it with a BMI well below 35 and over. That's the level at which the American Diabetes Association says surgery "may be considered" and that Medicare and some private insurers cover. And Iaboni's diabetes disappeared months before she shed much weight.
Her experience has raised an intriguing possibility: that some forms of bariatric surgery treat diabetes not by making patients shed pounds. Instead, by rerouting part of the digestive system, they change what signals the gut sends to the brain and the brain sends to the liver, altering the underlying causes of diabetes.
If proven, bariatric surgery may help people with type 2 diabetes who are less obese, overweight or even of healthy weight. And it might be effective against the currently incurable type 1, or "juvenile," diabetes, too.
"Every textbook says that diabetes is chronic, irreversible, and progressive," said Rubino. "But we have thousands of patients who once had diabetes and now do not."
"INSUFFICIENT" EVIDENCE
Bariatric surgeons have long been prone to declaring victory against diabetes way too soon, before large-scale, long-term data proved their case. "The evidence for the success of bariatric surgery in patients with a BMI below 35 is not very strong," said Leonid Poretsky, director of the Friedman Diabetes Institute at Beth Israel Medical Center in New York City. "Most of the studies have been very small and not well controlled."
The American Diabetes Association rates the evidence that bariatric surgery can cure diabetes as "E," the lowest of four grades. It calls data on patients with a BMI below 35 "insufficient," and says the procedure cannot be recommended except as part of research.
The immediate risks of bariatric surgery are small -- a 0.3 per cent chance of dying within 30 days of the procedure. But a small fraction of patients develop infections, leaking from the stomach into the abdominal cavity, or gallstones, and it can cause nutritional deficiencies: There is less intestine to absorb vitamins and minerals, raising the possibility of osteoporosis and anemia.
Despite these red flags, the surgical option is attracting intense interest because the quest to cure diabetes has become almost desperate. In type-1 diabetes, the pancreas does not produce enough insulin, a hormone that moves the glucose in food into cells. In type 2 diabetes, cells become resistant to insulin. In either case, glucose remains in the blood, damaging cells and blood vessels, sometimes severely enough to cause blindness, kidney failure, or gangrene requiring foot or limb amputations.
In 2010, 8.3 per cent of adults worldwide had type 2 diabetes (11.3 per cent did in the United States), resulting in direct medical costs of $376 billion ($116 billion in the United States). By 2030, the global incidence is projected to rise to 9.9 per cent, partly because of the rising obesity rate, with costs reaching $490 billion.
The possibility that bariatric surgery could cure diabetes emerged about a decade ago. A long-term study of thousands of patients in Sweden reported in 2004 that both gastric bypass and banding improved diabetes in many subjects. A 2008 study of 55 obese patients found that 73 per cent of those who underwent gastric banding saw their diabetes disappear after two years, compared to 13 per cent undergoing standard medical treatment such as medication, diet and exercise.
In 2009, surgeons at the University of Minnesota analyzed 621 mostly small studies of bariatric surgery in obese, diabetic patients. Their conclusion, reported in the American Journal of Medicine: 78 per cent no longer needed medication to control their blood sugar. They'd been cured. Lap banding had the worst results, worsening diabetes in some patients.
But most patients in these studies were obese, many morbidly so. (The average BMI was 48.) The improvement in glucose control could therefore be credited to the patients' weight loss, which averaged 85 pounds.
CLUES FROM THE PAST
Rubino had a hunch that something else was at work. As a research fellow in diabetes at Mount Sinai Hospital in New York in 1999, he was reviewing the medical literature one day for guidance on how to best perform bariatric surgery on a man with a BMI of 80. He found papers from the 1950s and earlier reporting that surgery for peptic ulcers had cured diabetes.
Ulcer surgery removes a portion of the stomach and reconstructs a connection to the intestine, much as gastric bypass does. Few diabetes experts had noticed the old papers; they were published in surgery journals, which endocrinologists seldom read.
His serendipitous find led Rubino to other papers describing operations on the digestive tract that cured diabetes, something that, according to medical textbooks, was unthinkable.
"Within two weeks of surgery and sometimes sooner, these patients were off their insulin, off their diabetes drugs, and with normal blood glucose levels," said Rubino. "That was too fast to explain by weight loss."
Yet that's how experts explained bariatric surgery's effect on diabetes, especially as the procedure took hold in the 1990s. Few surgeons focused on how quickly the condition disappeared, said Rubino, "or they speculated that patients weren't eating much after the surgery, and that's what cured their diabetes."
He began pursuing the idea that surgery might improve diabetes directly, rather than through weight loss. "I was ignorant of diabetes, so I wasn't burdened by too much knowledge," Rubino said. "Something that might have seemed heretical didn't seem impossible to me."
Rubino modified the popular gastric bypass surgery, called Roux-en-Y, to test his idea on diabetic lab rodents. In the classic operation, the stomach is pinched off so it can hold less food. Surgical cuts keep the rest of the stomach and the top of the small intestine, called the duodenum, from receiving any food. Instead, the stomach empties directly into the bottom of the small intestine, the jejunum. In Rubino's variation, called duodenal-jejunal bypass (DJB), the stomach is untouched, but the rest of the procedure is the same.
The rats that Rubino operated on beginning in 2000 were cured of diabetes much more quickly than their weight fell. It was the first rigorous evidence, from a well-controlled study, that gut surgery has an anti-diabetes effect.
In 2006, Rubino was ready to move from rats to people. Two patients, with BMIs of 29 and 30, underwent his procedure. Their blood sugar levels returned to normal within days, though they lost no weight. In his most recent trial, reported in March in the New England Journal of Medicine, Rubino and colleagues at Catholic University in Rome performed standard gastric bypass surgery or a procedure similar to DJB on people with type 2 diabetes. After two years, 15 of 20 bypass patients and 19 of 20 DJB patients no longer had diabetes.
Curiously, although patients shed pounds, there was no correlation between weight loss and blood glucose, the key marker of diabetes. "Bariatric surgery is more effective on diabetes than obesity," said Rubino. "Patients don't become lean, but they do not have diabetes anymore."
FROM GUT TO BRAIN
Research from the University of Toronto, reported online this month in Nature Medicine, may finally explain why. It examined the effects of bypass surgery on rats with type-1 diabetes, which is considered even harder to treat than type 2. Normally the jejunum receives only digested mush, as nutrients have already been absorbed in the duodenum, explained lead researcher Tony Lam.
Bypassing the duodenum allows the jejunum to receive an influx of nutrients for the first time, said Lam. Sensing them, the jejunum sends a "got glucose!" signal to the brain. The brain interprets that as a sign of glucose overabundance and orders the liver to decrease glucose production. Result: The rats no longer have diabetes.
"I believe that similar mechanisms are taking place in surgery for type 2 diabetes," said Lam. "It strengthens the case for the surgery treating diabetes independent of weight loss."
His rat study shows why lap banding and stomach stapling are less effective against diabetes than gastric bypass. Banding causes diabetes to go into remission in about 50 per cent of patients, probably due to weight loss, said endocrinologist Dr Allison Goldfine of the Joslin Diabetes Center in Boston.
In contrast, the diabetes-remission rate after Roux-en-Y is 80 to 85 per cent. "The improvements in blood glucose with Roux-en-Y appear to occur very early, by day three after surgery, so patients are being discharged with no medication," she said. Something other than weight loss "must be going on."
Goldfine has launched a study of diabetics with BMIs of 30 to 42 to compare outcomes after lap band surgery, Roux-en-Y, and intense medical management.
A year ago, Rubino began the first large study for type 2 diabetes patients with a BMI as low as 26, where "overweight" begins. The cost of the bypass surgery is covered by a grant from Covidien Plc, which makes laparoscopic instruments and surgical staplers. He aims to enroll at least 50 patients, following them for five years; he has operated on 20 so far.
© Copyright (c) Reuters

xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx
Appendix II
Peptide PHI (or peptide histidine isoleucine) is a peptide which functions as a hormone.
It plays a role in the regulation of prolactin in humans.[1]

1.  peptide phi
A 27-amino 
acid peptide with histidine at the N-terminal and isoleucine amide at the C-terminal. The exactamino acid composition of the peptide is species dependent. The peptide is secreted in the intestine, but is foundin the nervous system, many organs, and in the majority of peripheral tissues. It has a wide range of biological actions, affecting the cardiovascular, gastrointestinal, respiratory, and central nervous systems.
Xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx
Appendix III
Neurotransmitters Mediating the Intestinal Peristaltic Reflex in the Mouse
  1. John R. Grider
+Author Affiliations
  1. Departments of Physiology and Medicine, Medical College of Virginia Campus, Virginia Commonwealth University, Richmond, Virginia
  1. Address correspondence to:
    Dr. J. R. Grider, Department of Physiology, P.O. Box 980551, Medical College of Virginia Campus, Virginia Commonwealth University, Richmond, VA 23298. E-mail: 
    jgrider@hsc.vcu.edu
Abstract
The motor, modulatory, and sensory neurotransmitters that mediate the peristaltic reflex in the mouse colon were identified by direct measurement, and their involvement in various pathways was determined by selective receptor antagonists. Mucosal stimulation in the central compartment of a three-compartment flat sheet preparation of mouse colon elicited ascending contraction and descending relaxation in the orad and caudad compartments, respectively. Ascending contraction was accompanied by substance P release, a marker for excitatory neurotransmitter release, into the orad compartment and was partly inhibited by atropine and spantide, and abolished by a combination of the two antagonists.
Descending relaxation was accompanied by vasoactive intestinal peptide (VIP) release, a marker for inhibitory neurotransmitter release, into the caudad compartment,
and was partly inhibited by VIP10-28 and NG-nitro-L-arginine, and abolished by a combination of the two agents. Somatostatin release increased during descending relaxation: immunoneutralization of somatostatin or blockade of its effect with a selective somatostatin type 2 receptor antagonist inhibited descending relaxation. The δ-opioid receptor antagonist naltrindole augmented descending relaxation and ascending contraction. Calcitonin gene-related peptide (CGRP) release increased in the central compartment and was mediated by concurrent release of 5-hydroxytryptamine (5-HT) because its release was blocked by a 5-HT4 receptor antagonist. Both the latter and the CGRP antagonist CGRP8-37, inhibited ascending contraction and descending relaxation. Thus, the reflex in mouse like that in rat and human intestine is initiated by mucosal release of 5-HT and activation of 5-HT4 receptors on CGRP sensory neurons and is relayed via somatostatin and opioid interneurons to VIP/nitric-oxide synthase inhibitory motor neurons and via cholinergic interneurons to acetylcholine/tachykinin excitatory motor neurons.

Xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx

Appendix IV

Peptides. 1984 May-Jun;5(3):593-606.
Co-existence of peptide HI (PHI) and VIP in nerves regulating blood flow and bronchial smooth muscle tone in various mammals including man.
Abstract
By immunohistochemistry it was found that PHI- and VIP-like immunoreactivity (-IR) occurred in the same autonomic neurons in the upper respiratory tract, tongue and salivary glands with associated ganglia in rat, guinea-pig, cat, pig and man. VIP- and PHI-like immunoreactivity was also found in similar locations in the human heart. The N-terminally directed, but not the C-terminally directed, PHI antiserum or the VIP antiserum stained endocrine cells in the pig duodenum. This suggests the existence of an additional PHI-like peptide. Ligation of nerves acutely caused marked overlapping axonal accumulations of PHI- and VIP-IR central to the lesion. Two weeks after transection of the nerves, both types of immunoreactivities were still observed in accumulations both in the axons as well as in the corresponding cell bodies. The levels of PHI- and VIP-IR in normal tissues from the cat were around 10-50 pmol/g with a molar ratio of about 1 to 2. Systemic administrations of PHI and VIP induced hypotension, probably due to peripheral vasodilation in both guinea-pig and cat. Furthermore, both PHI and VIP caused an inhibition of the vagally induced increase in respiratory insufflation pressure in guinea-pig. PHI and VIP relaxed the guinea-pig trachea in vitro, suggesting a direct action on tracheobronchial smooth muscle. VIP was about 5-10 times more potent than PHI with regard to hypotensive effects and 2-3-fold, considering respiratory smooth muscle-relaxant effects in the guinea-pig. PHI was about 50-fold less potent to induce hypotension in the cat than in the guinea-pig. Although species differences seem to exist as regards biological potency, PHI should also be considered when examining the role of VIP as an autonomic neurotransmitter.
xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx





No comments:

Post a Comment

Note: Only a member of this blog may post a comment.