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Thursday, March 1, 2012

The Myth of the Eight-Hour Sleep


A growing body of evidence, garnered from both science and history, is beginning to suggest that the eight-hour sleep cycle may not be most natural arrangement for humans after all.  One experiment conducted in the 1990s, for example, seemed to indicate that when completely left to their own devices, people would sleep for four hours, then wake for one or two hours before falling into a second four-hour sleep.
More recently, historians have uncovered a wealth of historical evidence that humans used to sleep in two distinct segments, including diaries, court records, medical books and literature.  The historically recent change to this pattern could be the root of a condition called sleep maintenance insomnia, where people wake during the night and have trouble getting back to sleep
According to BBC News:
“... [R]eferences to the first and second sleep started to disappear during the late 17th Century. This started among the urban upper classes in northern Europe and over the course of the next 200 years filtered down to the rest of Western society ... In 1667, Paris became the first city in the world to light its streets ... [B]y the end of the century, more than 50 of Europe's major towns and cities were lit at night.  Night became fashionable and spending hours lying in bed was considered a waste of time. “

Sources:




About Dr Kevin Lau

Dr Kevin Lau DC is the founder of Health In Your Hands, a series of tools for Scoliosis prevention and treatment. The set includes his book Your Plan for Natural Scoliosis Prevention and Treatment, a companion Scoliosis Exercises for Prevention and Correction DVD and the innovative new iPhone application ScolioTrack. Dr Kevin Lau is a graduate in Doctor of Chiropractic from RMIT University in Melbourne Australia and Masters in Holistic Nutrition. He is a member of International Society On Scoliosis Orthopaedic and Rehabilitation Treatment (SOSORT), the leading international society on conservative treatment of spinal deformities. In 2006 I was awarded the "Best Health-care Provider Awards" by the largest Newspaper publication in Singapore on October 18 2006 as well as being interviewed on Primetime Channel News Asia as well as other TV and Radio. For more information on Dr Kevin Lau, watch his interviews or get a free sneak peek of his book, go to: http://www.hiyh.info.

A growing body of evidence, garnered from both science and history, is beginning to suggest that the eight-hour sleep cycle may not be most natural arrangement for humans after all.  One experiment conducted in the 1990s, for example, seemed to indicate that when completely left to their own devices, people would sleep for four hours, then wake for one or two hours before falling into a second four-hour sleep.
More recently, historians have uncovered a wealth of historical evidence that humans used to sleep in two distinct segments, including diaries, court records, medical books and literature.  The historically recent change to this pattern could be the root of a condition called sleep maintenance insomnia, where people wake during the night and have trouble getting back to sleep
According to BBC News:
“... [R]eferences to the first and second sleep started to disappear during the late 17th Century. This started among the urban upper classes in northern Europe and over the course of the next 200 years filtered down to the rest of Western society ... In 1667, Paris became the first city in the world to light its streets ... [B]y the end of the century, more than 50 of Europe's major towns and cities were lit at night.  Night became fashionable and spending hours lying in bed was considered a waste of time. “

Sources:




About Dr Kevin Lau

Dr Kevin Lau DC is the founder of Health In Your Hands, a series of tools for Scoliosis prevention and treatment. The set includes his book Your Plan for Natural Scoliosis Prevention and Treatment, a companion Scoliosis Exercises for Prevention and Correction DVD and the innovative new iPhone application ScolioTrack. Dr Kevin Lau is a graduate in Doctor of Chiropractic from RMIT University in Melbourne Australia and Masters in Holistic Nutrition. He is a member of International Society On Scoliosis Orthopaedic and Rehabilitation Treatment (SOSORT), the leading international society on conservative treatment of spinal deformities. In 2006 I was awarded the "Best Health-care Provider Awards" by the largest Newspaper publication in Singapore on October 18 2006 as well as being interviewed on Primetime Channel News Asia as well as other TV and Radio. For more information on Dr Kevin Lau, watch his interviews or get a free sneak peek of his book, go to: http://www.hiyh.info.
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Study: Lack of exercise in people suffering from arthritis


December 11, 2011 — Last week, NPR featured a story about a recent Northwestern University study on osteoarthritis.
The study, which evaluated 1,000 participants living with osteoarthritis of the knee, found that 90 percent of those surveyed did not perform at least 10 minutes of moderate activity through the course of aweek.

According to researchers, by exercising, muscles more effectively support the weight of the body and take pressure off the joints.

Learn what exercises you can recommend to patients living with arthritis by checking out ACA's Healthy Living Patient Fact Sheet on rheumatoid arthritis.

Source: American Chiropractic Association,www.acatoday.org


About Dr Kevin Lau

Dr Kevin Lau DC is the founder of Health In Your Hands, a series of tools for Scoliosis prevention and treatment. The set includes his book Your Plan for Natural Scoliosis Prevention and Treatment, a companion Scoliosis Exercises for Prevention and Correction DVD and the innovative new iPhone application ScolioTrack. Dr Kevin Lau is a graduate in Doctor of Chiropractic from RMIT University in Melbourne Australia and Masters in Holistic Nutrition. He is a member of International Society On Scoliosis Orthopaedic and Rehabilitation Treatment (SOSORT), the leading international society on conservative treatment of spinal deformities. In 2006 I was awarded the "Best Health-care Provider Awards" by the largest Newspaper publication in Singapore on October 18 2006 as well as being interviewed on Primetime Channel News Asia as well as other TV and Radio. For more information on Dr Kevin Lau, watch his interviews or get a free sneak peek of his book, go to: http://www.hiyh.info.

December 11, 2011 — Last week, NPR featured a story about a recent Northwestern University study on osteoarthritis.
The study, which evaluated 1,000 participants living with osteoarthritis of the knee, found that 90 percent of those surveyed did not perform at least 10 minutes of moderate activity through the course of aweek.

According to researchers, by exercising, muscles more effectively support the weight of the body and take pressure off the joints.

Learn what exercises you can recommend to patients living with arthritis by checking out ACA's Healthy Living Patient Fact Sheet on rheumatoid arthritis.

Source: American Chiropractic Association,www.acatoday.org


About Dr Kevin Lau

Dr Kevin Lau DC is the founder of Health In Your Hands, a series of tools for Scoliosis prevention and treatment. The set includes his book Your Plan for Natural Scoliosis Prevention and Treatment, a companion Scoliosis Exercises for Prevention and Correction DVD and the innovative new iPhone application ScolioTrack. Dr Kevin Lau is a graduate in Doctor of Chiropractic from RMIT University in Melbourne Australia and Masters in Holistic Nutrition. He is a member of International Society On Scoliosis Orthopaedic and Rehabilitation Treatment (SOSORT), the leading international society on conservative treatment of spinal deformities. In 2006 I was awarded the "Best Health-care Provider Awards" by the largest Newspaper publication in Singapore on October 18 2006 as well as being interviewed on Primetime Channel News Asia as well as other TV and Radio. For more information on Dr Kevin Lau, watch his interviews or get a free sneak peek of his book, go to: http://www.hiyh.info.
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Oral laxatives for feline constipation

Tam FM, Carr AP and Myers SL. Safety and palatability of polyethylene glycol 3350 as an oral laxative in cats. J Feline Med Surg. 2011; 13: 694-7.
Miralax 
Recurrent constipation is a common problem in cats. A cornerstone for the management of recurrent constipation is the use of laxatives, but there is little research into the use of laxatives in cats. In this study, the authors looked at the safety and palatability of polyethylene glycol (PEG3350) in normal cats. PEG3350 is readily available in a powdered form that can be mixed with cat food. PEG 3350 with electrolytes (Colyte oral solution; Schwarz Pharma) was administered to 6 cats for 4 weeks by mixing the powder with the food. All the cats achieved soft stools while given the laxative. Effective doses varied widely so individualizing the dose is very important. As an alternative, PEG3350 without electrolytes (Miralax, Restoralax) has been approved as an over-the-counter laxative in the United States and Canada and should be readily accessible to owners. One side effect noted was mild non-clinical hyperkalemia though the cause is unknown. PEG3350 has a potential role in the medical management of chronically constipated cats. [VT]

Related articles: Trevail TIM, Gunn-Moore D, Carrera I, Courcier E and Sullivan M. Radiographic diameter of the colon in normal and constipated cats and in cats with megacolon. Vet Radiol Ultrasound. 2011; 52: 516-20.

More on cat health:
Winn Feline Foundation Library
Find us on Facebook
Follow us on Twitter
Read the Cat Health News Weekly
Join us on Google+ 
 
Tam FM, Carr AP and Myers SL. Safety and palatability of polyethylene glycol 3350 as an oral laxative in cats. J Feline Med Surg. 2011; 13: 694-7.
Miralax 
Recurrent constipation is a common problem in cats. A cornerstone for the management of recurrent constipation is the use of laxatives, but there is little research into the use of laxatives in cats. In this study, the authors looked at the safety and palatability of polyethylene glycol (PEG3350) in normal cats. PEG3350 is readily available in a powdered form that can be mixed with cat food. PEG 3350 with electrolytes (Colyte oral solution; Schwarz Pharma) was administered to 6 cats for 4 weeks by mixing the powder with the food. All the cats achieved soft stools while given the laxative. Effective doses varied widely so individualizing the dose is very important. As an alternative, PEG3350 without electrolytes (Miralax, Restoralax) has been approved as an over-the-counter laxative in the United States and Canada and should be readily accessible to owners. One side effect noted was mild non-clinical hyperkalemia though the cause is unknown. PEG3350 has a potential role in the medical management of chronically constipated cats. [VT]

Related articles: Trevail TIM, Gunn-Moore D, Carrera I, Courcier E and Sullivan M. Radiographic diameter of the colon in normal and constipated cats and in cats with megacolon. Vet Radiol Ultrasound. 2011; 52: 516-20.

More on cat health:
Winn Feline Foundation Library
Find us on Facebook
Follow us on Twitter
Read the Cat Health News Weekly
Join us on Google+ 
 
Read More


Monday, February 27, 2012

Birman cats and FIP

Final report, Winn grant 08-036
Blood parameters potentially associated with susceptibility to feline coronavirus in Birman cats
Investigators: Saverio Paltrinieri; University of Milan

This research project examined the increased susceptibility of Birman cats to FIP. The investigators specifically focused on various blood parameters to correlate with immune status and FIP susceptibility. Blood and/or feces were initially collected from 233 cats in 25 breeding catteries or colonies; 57 cats were excluded due to insufficient data or presence of disease within the cattery. Of the 176 cats tested, 5 were diagnosed with FIP. Birman cats were not found to be feline coronavirus seropositive at a higher rate than other breeds. However, the percentage of cats with detectable virus in feces was higher in breeds other than the Birman. Populations of both Birman cats and cats of other breeds had a high prevalence of FCoV infection; there was no statistical difference between the two groups. While differences in some blood parameters were noted, all, both Birman and non-Birman, were within normal reference ranges. The researchers speculate that these differences are breed related, but do not seem to correlate with FCoV infection.

No differences of biologic significance were noted among the various lymphocyte populations in any group of cats, whether Birman or non-Birman. Individual variations in cytokine levels were noted, but did not correlate with FIP development. Birman cats seemed to have a higher capability for cell-mediated immunity, which is critical for protection against FIP. The researchers speculate that poor cell-mediated immunity could induce the persistence of the virus in the host and ultimately this could increase the probability of mutation of the virus and subsequent development of FIP. [MK]

Related articles: Paltrinieri S, Comazzi S, Spagnolo V and Giordano A. Laboratory changes consistent with feline infectious peritonitis in cats from multicat environments. J Vet Med A Physiol Pathol Clin Med. 2002; 49: 503-10.

More on cat health:
Winn Feline Foundation Library
Find us on Facebook
Follow us on Twitter
Read the Cat Health News Weekly
Join us on Google+
 
Final report, Winn grant 08-036
Blood parameters potentially associated with susceptibility to feline coronavirus in Birman cats
Investigators: Saverio Paltrinieri; University of Milan

This research project examined the increased susceptibility of Birman cats to FIP. The investigators specifically focused on various blood parameters to correlate with immune status and FIP susceptibility. Blood and/or feces were initially collected from 233 cats in 25 breeding catteries or colonies; 57 cats were excluded due to insufficient data or presence of disease within the cattery. Of the 176 cats tested, 5 were diagnosed with FIP. Birman cats were not found to be feline coronavirus seropositive at a higher rate than other breeds. However, the percentage of cats with detectable virus in feces was higher in breeds other than the Birman. Populations of both Birman cats and cats of other breeds had a high prevalence of FCoV infection; there was no statistical difference between the two groups. While differences in some blood parameters were noted, all, both Birman and non-Birman, were within normal reference ranges. The researchers speculate that these differences are breed related, but do not seem to correlate with FCoV infection.

No differences of biologic significance were noted among the various lymphocyte populations in any group of cats, whether Birman or non-Birman. Individual variations in cytokine levels were noted, but did not correlate with FIP development. Birman cats seemed to have a higher capability for cell-mediated immunity, which is critical for protection against FIP. The researchers speculate that poor cell-mediated immunity could induce the persistence of the virus in the host and ultimately this could increase the probability of mutation of the virus and subsequent development of FIP. [MK]

Related articles: Paltrinieri S, Comazzi S, Spagnolo V and Giordano A. Laboratory changes consistent with feline infectious peritonitis in cats from multicat environments. J Vet Med A Physiol Pathol Clin Med. 2002; 49: 503-10.

More on cat health:
Winn Feline Foundation Library
Find us on Facebook
Follow us on Twitter
Read the Cat Health News Weekly
Join us on Google+
 
Read More


Sunday, February 26, 2012

How Exercise Fuels the Brain


Moving the body demands a lot from the brain. Exercise activates countless neurons, which generate, receive and interpret repeated, rapid-fire messages from the nervous system, coordinating muscle contractions, vision, balance, organ function and all of the complex interactions of bodily systems that allow you to take one step, then another.
This increase in brain activity naturally increases the brain’s need for nutrients, but until recently, scientists hadn’t fully understood how neurons fuel themselves during exercise. Now a series of animal studies from Japan suggest that the exercising brain has unique methods of keeping itself fueled. What’s more, the finely honed energy balance that occurs in the brain appears to have implications not only for how well the brain functions during exercise, but also for how well our thinking and memory work the rest of the time.
For many years, scientists had believed that the brain, which is a very hungry organ, subsisted only on glucose, or blood sugar, which it absorbed from the passing bloodstream. But about 10 years ago, some neuroscientists found that specialized cells in the brain, known as astrocytes, that act as support cells for neurons actually contained small stores of glycogen, or stored carbohydrates. And glycogen, as it turns out, is critical for the health of cells throughout the brain.
But while scientists knew that the brain had and could access these energy stores, they had been unable to study when the brain’s stored energy was being used in actual live conditions, outside of petri dishes, because brain glycogen is metabolized or burned away very rapidly after death; it’s gone before it can be measured.In petri dishes, when neurons, which do not have energy stores of their own, are starved of blood sugar, their neighboring astrocytes undergo a complex physiological process that results in those cells’ stores of glycogen being broken down into a form easily burned by neurons. This substance is released into the space between the cells and the neurons swallow it, maintaining their energy levels.
That’s where the Japanese researchers came in. They had developed a new method of using high-powered microwave irradiation to instantly freeze glycogen levels at death, so that the scientists could accurately assess just how much brain glycogen remained in the astrocytes or had recently been used.
In the first of their new experiments, published last year in The Journal of Physiology, scientists at the Laboratory of Biochemistry and Neuroscience at the University of Tsukuba gathered two groups of adult male rats and had one group start a treadmill running program, while the other group sat for the same period of time each day on unmoving treadmills. The researchers’ aim was to determine how much the level of brain glycogen changed during and after exercise.
Using their glycogen detection method, they discovered that prolonged exercise significantly lowered the brain’s stores of energy, and that the losses were especially noticeable in certain areas of the brain, like the frontal cortex and the hippocampus, that are involved in thinking and memory, as well as in the mechanics of moving.
The findings of their subsequent follow-up experiment, however, were even more intriguing and consequential. In that study, which appears in this month’s issue of The Journal of Physiology, the researchers studied animals after a single bout of exercise and also after four weeks of regular, moderate-intensity running.
After the single session on the treadmill, the animals were allowed to rest and feed, and then their brain glycogen levels were studied. The food, it appeared, had gone directly to their heads; their brain levels of glycogen not only had been restored to what they had been before the workout, but had soared past that point, increasing by as much as a 60 percent in the frontal cortex and hippocampus and slightly less in other parts of the brain. The astrocytes had “overcompensated,” resulting in a kind of brain carbo-loading.
The levels, however, had dropped back to normal within about 24 hours.
That was not the case, though, if the animals continued to exercise. In those rats that ran for four weeks, the “supercompensation” became the new normal, with their baseline levels of glycogen showing substantial increases compared with the sedentary animals. The increases were especially notable in, again, those portions of the brain critical to learning and memory formation — the cortex and the hippocampus.
Which is why the findings are potentially so meaningful – and not just for rats.
While a brain with more fuel reserves is potentially a brain that can sustain and direct movement longer, it also “may be a key mechanism underlying exercise-enhanced cognitive function,” says Hideaki Soya, a professor of exercise biochemistry at the University of Tsukuba and senior author of the studies, since supercompensation occurs most strikingly in the parts of the brain that allow us better to think and to remember. As a result, Dr. Soya says, “it is tempting to suggest that increased storage and utility of brain glycogen in the cortex and hippocampus might be involved in the development” of a better, sharper brain.
Given the limits of current technologies, brain glycogen metabolism cannot be studied in people. But even so, the studies’ findings make D.I.Y. brain-fuel supercompensation efforts seem like an attractive possibility. And, according to unpublished data from Dr. Soya’s lab, the process may even be easy.
He and his colleagues have found that “glycogen supercompensation in some brain loci” is “enhanced in rats receiving carbohydrates immediately after exhaustive exercise.” So for people, that might mean that after a run or other exercise that is prolonged or strenuous enough to leave you tired, a bottle of chocolate milk or a banana might be just the thing your brain is needing.

http://well.blogs.nytimes.com/2012/02/22/how-exercise-fuels-the-brain/

About Dr Kevin Lau

Dr Kevin Lau DC is the founder of Health In Your Hands, a series of tools for Scoliosis prevention and treatment. The set includes his book Your Plan for Natural Scoliosis Prevention and Treatment, a companion Scoliosis Exercises for Prevention and Correction DVD and the innovative new iPhone application ScolioTrack. Dr Kevin Lau is a graduate in Doctor of Chiropractic from RMIT University in Melbourne Australia and Masters in Holistic Nutrition. He is a member of International Society On Scoliosis Orthopaedic and Rehabilitation Treatment (SOSORT), the leading international society on conservative treatment of spinal deformities. In 2006 I was awarded the "Best Health-care Provider Awards" by the largest Newspaper publication in Singapore on October 18 2006 as well as being interviewed on Primetime Channel News Asia as well as other TV and Radio. For more information on Dr Kevin Lau, watch his interviews or get a free sneak peek of his book, go to: http://www.hiyh.info.

Moving the body demands a lot from the brain. Exercise activates countless neurons, which generate, receive and interpret repeated, rapid-fire messages from the nervous system, coordinating muscle contractions, vision, balance, organ function and all of the complex interactions of bodily systems that allow you to take one step, then another.
This increase in brain activity naturally increases the brain’s need for nutrients, but until recently, scientists hadn’t fully understood how neurons fuel themselves during exercise. Now a series of animal studies from Japan suggest that the exercising brain has unique methods of keeping itself fueled. What’s more, the finely honed energy balance that occurs in the brain appears to have implications not only for how well the brain functions during exercise, but also for how well our thinking and memory work the rest of the time.
For many years, scientists had believed that the brain, which is a very hungry organ, subsisted only on glucose, or blood sugar, which it absorbed from the passing bloodstream. But about 10 years ago, some neuroscientists found that specialized cells in the brain, known as astrocytes, that act as support cells for neurons actually contained small stores of glycogen, or stored carbohydrates. And glycogen, as it turns out, is critical for the health of cells throughout the brain.
But while scientists knew that the brain had and could access these energy stores, they had been unable to study when the brain’s stored energy was being used in actual live conditions, outside of petri dishes, because brain glycogen is metabolized or burned away very rapidly after death; it’s gone before it can be measured.In petri dishes, when neurons, which do not have energy stores of their own, are starved of blood sugar, their neighboring astrocytes undergo a complex physiological process that results in those cells’ stores of glycogen being broken down into a form easily burned by neurons. This substance is released into the space between the cells and the neurons swallow it, maintaining their energy levels.
That’s where the Japanese researchers came in. They had developed a new method of using high-powered microwave irradiation to instantly freeze glycogen levels at death, so that the scientists could accurately assess just how much brain glycogen remained in the astrocytes or had recently been used.
In the first of their new experiments, published last year in The Journal of Physiology, scientists at the Laboratory of Biochemistry and Neuroscience at the University of Tsukuba gathered two groups of adult male rats and had one group start a treadmill running program, while the other group sat for the same period of time each day on unmoving treadmills. The researchers’ aim was to determine how much the level of brain glycogen changed during and after exercise.
Using their glycogen detection method, they discovered that prolonged exercise significantly lowered the brain’s stores of energy, and that the losses were especially noticeable in certain areas of the brain, like the frontal cortex and the hippocampus, that are involved in thinking and memory, as well as in the mechanics of moving.
The findings of their subsequent follow-up experiment, however, were even more intriguing and consequential. In that study, which appears in this month’s issue of The Journal of Physiology, the researchers studied animals after a single bout of exercise and also after four weeks of regular, moderate-intensity running.
After the single session on the treadmill, the animals were allowed to rest and feed, and then their brain glycogen levels were studied. The food, it appeared, had gone directly to their heads; their brain levels of glycogen not only had been restored to what they had been before the workout, but had soared past that point, increasing by as much as a 60 percent in the frontal cortex and hippocampus and slightly less in other parts of the brain. The astrocytes had “overcompensated,” resulting in a kind of brain carbo-loading.
The levels, however, had dropped back to normal within about 24 hours.
That was not the case, though, if the animals continued to exercise. In those rats that ran for four weeks, the “supercompensation” became the new normal, with their baseline levels of glycogen showing substantial increases compared with the sedentary animals. The increases were especially notable in, again, those portions of the brain critical to learning and memory formation — the cortex and the hippocampus.
Which is why the findings are potentially so meaningful – and not just for rats.
While a brain with more fuel reserves is potentially a brain that can sustain and direct movement longer, it also “may be a key mechanism underlying exercise-enhanced cognitive function,” says Hideaki Soya, a professor of exercise biochemistry at the University of Tsukuba and senior author of the studies, since supercompensation occurs most strikingly in the parts of the brain that allow us better to think and to remember. As a result, Dr. Soya says, “it is tempting to suggest that increased storage and utility of brain glycogen in the cortex and hippocampus might be involved in the development” of a better, sharper brain.
Given the limits of current technologies, brain glycogen metabolism cannot be studied in people. But even so, the studies’ findings make D.I.Y. brain-fuel supercompensation efforts seem like an attractive possibility. And, according to unpublished data from Dr. Soya’s lab, the process may even be easy.
He and his colleagues have found that “glycogen supercompensation in some brain loci” is “enhanced in rats receiving carbohydrates immediately after exhaustive exercise.” So for people, that might mean that after a run or other exercise that is prolonged or strenuous enough to leave you tired, a bottle of chocolate milk or a banana might be just the thing your brain is needing.

http://well.blogs.nytimes.com/2012/02/22/how-exercise-fuels-the-brain/

About Dr Kevin Lau

Dr Kevin Lau DC is the founder of Health In Your Hands, a series of tools for Scoliosis prevention and treatment. The set includes his book Your Plan for Natural Scoliosis Prevention and Treatment, a companion Scoliosis Exercises for Prevention and Correction DVD and the innovative new iPhone application ScolioTrack. Dr Kevin Lau is a graduate in Doctor of Chiropractic from RMIT University in Melbourne Australia and Masters in Holistic Nutrition. He is a member of International Society On Scoliosis Orthopaedic and Rehabilitation Treatment (SOSORT), the leading international society on conservative treatment of spinal deformities. In 2006 I was awarded the "Best Health-care Provider Awards" by the largest Newspaper publication in Singapore on October 18 2006 as well as being interviewed on Primetime Channel News Asia as well as other TV and Radio. For more information on Dr Kevin Lau, watch his interviews or get a free sneak peek of his book, go to: http://www.hiyh.info.
Read More