Archive for the ‘Brain Works’ Category
Message: Next time you crave anything, ask yourself “What is it I really need? A glass of water? A walk? A hug?” Buying fresh flowers can be a better answer than a bowl of Rocky Road. Exercise, go to sauna, take a cold shower, invest in a massage device, buy a vail of perfume, enjoy a book… Try periodic fasts. After resuming eating, your taste buds will be satisfied with lesser taste intensity thus reducing the taste influence on the body weight set point.
Reward: it can be not about food
“Something is wanted — either a constitution or a piece of sturgeon under horseradish sauce.” M.E. Saltykov-Schedrin (19th Century)
In the late 50s, the classic experiments by Dr. Olds shook the world. He implanted electrodes into certain regions of rat brains and taught the rats how to press lever to stimulate these regions with weak electric currents. Rats stopped doing anything but pressing the lever till their death from complete starvation. The Positive Reward theory was born. It turned out that anything pleasurable in life did related to these “Centers of Pleasure” — sex, alcohol, drugs of abuse — all that mankind has invented in its hedonic journey, were but attempts to stimulate these brain regions.
We know that eating will produce a pleasant sensation so often we eat even though all we need is comfort. The truth is, exercise, sauna, cold shower, massage, pleasant odors, and mental efforts (workoholism is real!) — all increase Endorphin level while only eating, especially when your body does not need it, will cause extra pounds of fat to collect in your body’s store.
“A mechanism for opiate [e.g. endorphin] mediation of food intake was postulated. It starts with a feeding initiating signal, which produces activation of the receptors, thereby inducing eating. Eating produces a circular reaction starting with hedonic input from the eating [process]. This, in turn, produces reward, which causes further eating, completing the circle” [1].
Fasting can be as rewarding
The tricky thing with endorphins is that there are pairs of releasers resembling a thesaurus’ antonyms: exercise does the same os its antonym sleep, pleasure goes together with pain, local blood flow increase does the same to endorphin release as the local lack of oxygen. The eating-fasting pair also exists. Many people reported elation when they skipped breakfasts. Religeous fasters experience euforia.
“Severe food restriction produces opiate activity, which is reinforcing. Feeding interrupts the opiate activity and, thus, produces withdrawal. Not eating, therefore, is rewarding.” [2].
Sources
- Soc. Neurosci. Abstr. 18:369; 1992
- Appetite 19:1-13; 1992
Read also: A theory of acupuncture, spinal cord, and endorphins
Out of all nutrients known for their effects on brain functions, two groups are assumed being of particular importance for the process of learning therefore being of even more importance for children with learning disabilities. Here is what they are and why.
The process of learning is believed to rely on mechanisms providing contacts between brain cells called, as you know, neurons. These contacts take place in highly specialised tiny places where two neurons physically contact each other called synapses. One of the neurons initiates the contact by releasing a chemical substance, called neurotransmitter, into the narrow cleft separating pre-synapse from post-synapse.
As soon as the neuron-recipient feels this substance, it gets all excited and became electrically active. The more often the contact the easier the recipient gets excited. Under one important condition: if there’s enough of the substance-neurotransmitter. More synapses involved mean a higher probability of newly formed communication pathways – “learned” ones. There are enzymes and their helpers co-enzymes that work facilitating the production of neurotransmitters. Many vitamins are involved in enzymes’ work. The good example of co-enzymes is the well-known supplement co-enzyme Q10.
Another way to help the process of learning is to supply the brain with neuronal metabolites that promote neuronal growth and activity and enrich the brain architecture.
This is the list of nutrients, which were under investigation whether they work for children with learning disabilities (Alternative Therapies in Health and Medicine, 2000, 6(3): 85-91):
1. Magnesium Chelate 100 mg (at bedtime since it causes drowsiness)
2. Pure Vitamin C 100 mg (bioflavanoids were excluded due to their adverse effects on learning disabilities)
3. Vitamin B1 Thiamine 50 mg
4. Vitamin B3 Niacinamide 50 mg
5. Vitamin B6 Pyridoxine 100 mg
6. Vitamin B12 500 mcg
7. Folic Acid 400 mcg
8. Manganese Chelate 20 mg
9. Zinc Chelate22.5 mg
10. L-tyrosine 500 mg
11. L-glutamine 500 mg
12. Linoleic Acid as evening primrose oil 500 mg
13. Co-enzyme Q10 10 mg
These nutrients were tested on a group of 19 children with learning disabilities for 4 years resulting in dramatic improvement in behavior and academic grades. All the participating children were able to join the mainstream school classes. Those who discontinued the program remained in normal range of school performance for almost one year, however their grades were gradually decreasing. Those who stayed on the program, continued improving their grades during this year so that in the end of the year 4, the difference in overage grades became very significant: 94.6 in those remaining versus 79 in those who discontinued.
Out of the nutrients on the list, the most prominent effect had magesium, vitamins B1 and B6, Zn, and folic acid, followed by vitamin C, L-glutamine, and primrose oil. Manganese was found to have mild adverse effects.
Phytochemical-rich foods have been shown to be effective at reversing age-related deficits in memory in both animals and humans. Specifically, blueberry were effective in reversing age-related deficits in neuronal signaling and behavioral parameters following 8 weeks of feeding, possibly due to their high flavonoid content. It has been reported that blueberry-supplemented diet may not only retard but also revert declining brain functions due to aging. Young and old rats were trained to memorize objects shown them an hour ago. Old rats receiving 2% of their meals as blueberries performed as young rats while old rats on regular diet failed to memorize the objects at al. In several regions of the brain, old control diet rats had significantly higher levels of so called nuclear factor-kappa B (NF-κB) than young animals on the control diet and old rats eating blueberries (Nutritional Neuroscience, V 7, No 2, 2004, 5-83-9). NF-κB is known for its involvement in vulnerability of neurons to “excitotoxicity” – a toxic biochemical condition occurring during neuronal hyperactivity (Synapse. 2000 Feb;35(2):151-9). Errors in regulation of NF-κB may lead to cancer, inflammation and improper immune development. To resist excitotoxicity, there’s so called Brain-derived neurotrophic factor or BDNF, which function is to help supporting the survival of neurons. Recent data (Free Radical Biology and Medicine, 45, 3, 008, 295-305) on blueberry supplementation may indicate that changes in working memory in aged animals are linked to the effects of flavonoids on BDNF.
It was unclear if phytonutrients from blueberries were able to cross the blood-brain barrier and directly access the brain. Researchers in Barcelona, Spain, investigated this issue. They took old rats and fed them a diet containing 2% blueberries for 2 to 2.5 months, than tested the rats for learning and memory. in the brain areas participating in learning and memory processing and storing – cerebellum, cortex, hippocampus or striatum, 14 antioxidant substances found. The antioxidant content correlated with improvements in learning and memory normally declined in old age rats (and humans). In control rats of same age fed on regular diet, there were no changes in bioche
Phytochemical-rich foods have been shown to be effective at reversing age-related deficits in memory in both animals and humans. Specifically, blueberry were effective in reversing age-related deficits in neuronal signaling and behavioral parameters following 8 weeks of feeding, possibly due to their high flavonoid content. It has been reported that blueberry-supplemented diet may not only retard but also revert declining brain functions due to aging. Young and old rats were trained to memorize objects shown them an hour ago. Old rats receiving 2% of their meals as blueberries performed as young rats while old rats on regular diet failed to memorize the objects at al. In several regions of the brain, old control diet rats had significantly higher levels of so called nuclear factor-kappa B (NF-κB) than young animals on the control diet and old rats eating blueberries (Nutritional Neuroscience, V 7, No 2, 2004, 5-83-9). NF-κB is known for its involvement in vulnerability of neurons to “excitotoxicity” – a toxic biochemical condition occurring during neuronal hyperactivity (Synapse. 2000 Feb;35(2):151-9). Errors in regulation of NF-κB may lead to cancer, inflammation and improper immune development. To resist excitotoxicity, there’s so called Brain-derived neurotrophic factor or BDNF, which function is to help supporting the survival of neurons. Recent data (Free Radical Biology and Medicine, 45, 3, 008, 295-305) on blueberry supplementation may indicate that changes in working memory in aged animals are linked to the effects of flavonoids on BDNF.
It was unclear if phytonutrients from blueberries were able to cross the blood-brain barrier and directly access the brain. Researchers in Barcelona, Spain, investigated this issue. They took old rats and fed them a diet containing 2% blueberries for 2 to 2.5 months, than tested the rats for learning and memory. in the brain areas participating in learning and memory processing and storing – cerebellum, cortex, hippocampus or striatum, 14 antioxidant substances found. The antioxidant content correlated with improvements in learning and memory normally declined in old age rats (and humans). In control rats of same age fed on regular diet, there were no changes in bioche
Flavonoids are water soluble plant pigments that plants produce to assist in photosynthesis and are believed to function as antioxidants.
Major dietary sources of flavonoids include fruits, vegetables, cereals, tea, wine and fruit juices.
The main groups of flavonoids and their food sources are:
flavonols – found in onions, leeks and broccoli;
flavones – found in parsley and celery;
isoflavones – found in soyabeans;
flavanones – found in citrus fruit and tomatoes;
flavanols – abundant in green tea, red wine and cocoa; anthocyanidins’ sources include red wine and red berries.
A recent study has provided strong evidence that dietary flavonoid intake preserved cognitive abilities with aging. Isoflavones from soy had positive effects on cognitive function, because they were able to mimic the actions of estrogens in the brain. Isoflavone supplementation had a favourable effect on verbal memory in post-menopausal women.
Brain-imaging studies in humans have demonstrated that the consumption of flavanol-rich cocoa may enhance blood flow to the brain cortex. Berries, in particular blueberries, are effective at reversing age-related deficits in movements and memory.
Animal studies with tea, grape juice or flavonols such as quercetin have shown that they all are beneficial in reversing the course of neuronal and behavioural ageing. Such beneficial effects have been attributed to antioxidant activities, however, there are growing body of evidence that their mechanisms involve a modulation of neurotransmitter release, a stimulation of neurogenesis and changes in neuronal signaling.
Source: Proceedings of the Nutrition Society (2008), 67: 238-252
Flavonoids are water soluble plant pigments that plants produce to assist in photosynthesis and are believed to function as antioxidants. Major dietary sources of flavonoids include fruits, vegetables, cereals, tea, wine and fruit juices.
The main groups of flavonoids and their food sources are:
- flavonols – found in onions, leeks and broccoli;
- flavones – found in parsley and celery;
- isoflavones – found in soyabeans;
- flavanones – found in citrus fruit and tomatoes;
- flavanols – abundant in green tea, red wine and cocoa; anthocyanidins’ sources include red wine and red berries.
A recent study has provided strong evidence that dietary flavonoid intake preserved cognitive abilities with aging. Isoflavones from soy had positive effects on cognitive function, because they were able to mimic the actions of estrogens in the brain. Isoflavone supplementation had a favourable effect on verbal memory in post-menopausal women.
Brain-imaging studies in humans have demonstrated that the consumption of flavanol-rich cocoa may enhance blood flow to the brain cortex. Berries, in particular blueberries, are effective at reversing age-related deficits in movements and memory.
Animal studies with tea, grape juice or flavonols such as quercetin have shown that they all are beneficial in reversing the course of neuronal and behavioural ageing. Such beneficial effects have been attributed to antioxidant activities, however, there are growing body of evidence that their mechanisms involve a modulation of neurotransmitter release, a stimulation of neurogenesis and changes in neuronal signaling.
Source: Proceedings of the Nutrition Society (2008), 67: 238-252
It has been suggested that nutrition may play a role in age-related hearing loss and that it may be associated with poor micronutrient status. For example, Vitamin B-12 or folate deficiencies may negatively influence blood flow to the cochlea, leading to age-related hearing loss. Australian researchers showed that people with hearing loss were more likely to be exposed to workplace noise, be a current smoker, have a doctor-diagnosed history of stroke or type 2 diabetes, and to have Vitamin B-12 (1).
In Finland, two groups of 40-59-year olds were studied, 1) one on a diet high in saturated animal fats, 2) the other on a diet high in polyunsaturated fats. After 5 years of follow up, blood vessel condition was better in the group 2 and the participants hearing ability was also significantly better in all frequencies. After that, the diets in the two groups were reversed. Four years after the diet reversal the hearing in the now low-fat group was improved and the hearing in the now high-fat group was deteriorating. The authors concluded that a diet high in polyunsaturated fats may stop, if not reverse, hearing loss (2).
In a recent Dutch study, 720 participants 50–70 years of age without hearing loss were tested for levels of polyunsaturated fats, very long-chain n-3 PUFA in their plasma. In high sound frequencies, there was no correlation of hearing acuity and PUFA concentrations in plasma. However, in the low frequencies, the higher PUFA levels corresponded to better hearing abilities. The authors found their results “encouraging, but requirig confirmation from future studies.” (3)
Serum Homocysteine and Folate Concentrations Are Associated with Prevalent Age-Related Hearing Loss. Journal of Nutrition, Vol. 140, No. 8, 1469-1474, Aug, 2010
DIETARY PREVENTION OF HEARING LOSS. Acta Otolaryng 70: 242-247, 1970
PLASMA VERY LONG-CHAIN N-3 POLYUNSATURATED FATTY ACIDS AND AGE-RELATED HEARING LOSS IN OLDER ADULTS. THE JOURNAL OF NUTRITION, HEALTH & AGING Volume 14, Number 5, 347-351, 200
It has been suggested that nutrition may play a role in age-related hearing loss and that it may be associated with poor micronutrient status. For example, Vitamin B-12 or folate deficiencies may negatively influence blood flow to the cochlea, leading to age-related hearing loss. Australian researchers showed that people with hearing loss were more likely to be exposed to workplace noise, be a current smoker, have a doctor-diagnosed history of stroke or type 2 diabetes, and to have Vitamin B-12 (1).
In Finland, two groups of 40-59-year olds were studied, 1) one on a diet high in saturated animal fats, 2) the other on a diet high in polyunsaturated fats. After 5 years of follow up, blood vessel condition was better in the group 2 and the participants hearing ability was also significantly better in all frequencies. After that, the diets in the two groups were reversed. Four years after the diet reversal the hearing in the now low-fat group was improved and the hearing in the now high-fat group was deteriorating. The authors concluded that a diet high in polyunsaturated fats may stop, if not reverse, hearing loss (2).
In a recent Dutch study, 720 participants 50–70 years of age without hearing loss were tested for levels of polyunsaturated fats, very long-chain n-3 PUFA in their plasma. In high sound frequencies, there was no correlation of hearing acuity and PUFA concentrations in plasma. However, in the low frequencies, the higher PUFA levels corresponded to better hearing abilities. The authors found their results “encouraging, but requirig confirmation from future studies.” (3)
- Serum Homocysteine and Folate Concentrations Are Associated with Prevalent Age-Related Hearing Loss. Journal of Nutrition, Vol. 140, No. 8, 1469-1474, Aug, 2010
- DIETARY PREVENTION OF HEARING LOSS. Acta Otolaryng 70: 242-247, 1970
- PLASMA VERY LONG-CHAIN N-3 POLYUNSATURATED FATTY ACIDS AND AGE-RELATED HEARING LOSS IN OLDER ADULTS. THE JOURNAL OF NUTRITION, HEALTH & AGING Volume 14, Number 5, 347-351, 200
The B-complex include: biotin, choline, folic acid, inositol, PABA (para-aminobenzoic acid), and the six “numbered” B vitamins–vitamin B-1 (thiamin), B-2 (riboflavin), B-3 (niacin), B-5 (pantothenic acid), B-6 (pyridoxine), and B-12 (cobalamin). Combination products can simplify the process of taking individual B vitamins for a range of ailments including depression and stress. They are needed to make the feel-good brain chemical serotonin from the raw material – amino acid tryptophan (New England Journal of Medicine 1988;318:1720–8.)
Deficiency of vitamin B12 can create disturbances in mood and B12 supplementation helps to normalize the mood. The vitamin B12 increases the probability of recovery from major depression and is though to do its best when taken together with other B-vitamins.
Studies suggest that vitamin B9 (folate) may be associated with depression more than any other nutrient. Between 15% and 38% of people with depression have low folate levels in their bodies and those with very low levels tend to be the most depressed .
Many healthcare providers recommend a multivitamin that contains folate. If the multivitamin alone is not enough to improve folate function, the provider may suggest adding vitamins B6 and B12 to improve feelings of depression.
There is plenty of anecdotal evidence that after about one week on a low carbohydrate diet, mood and energy levels go through the roof. Researchers speculate that this can be explained by interplay of brain chemicals after the brain stops running on glucose and switches on ketons for fuel.
The brain is the organ most sensitive to a change in blood glucose level – too little produces fatigue, confusion, irritability and aggression. Decreased glucose sensitivity often develops due to excessive consumption of refined sugar and simple carbohydrates, like in white flour. When the brain adapts to the use of ketones instead glucose, these symptoms disappears.
A low-fat diet may be good for your body, but not necessarily for your mind. In a study at Wake Forest University, researchers found that monkeys on a low-fat diet were more hostile than monkeys that were fed foods high in fat. It is though that lower cholesterol decreases levels of serotonin and weakens emotional control.
Low fat diets can make you depressed. Research has linked diets that drastically cut down on all types of fat with an increase in symptoms of depression. Study conducted by University of Sheffield, demonstrated that meals rich in fat, significantly reduced pain perception in healthy human subjects (Physiology & Behavior. 65(4-5):643-8, 1999)
Any restrictive diet can cause depression sometime called diet blues. For people on a low fat diet a quick fix can be a carbohydrate-containing snack – a fruit or a hard candy. For people on the initial stages of low carbohydrate diets a quick fix is completely different. Turkey and chicken contain a good source of mood-enhancer tryptophan, an amino acid which is a raw material for serotonin – which can be low in people suffering from depression. Poorly eating and sleep habits can negatively influence otherwise normal serotonin levels.
Hypericum (St. John’s Wort) is a common perennial plant with yellow flowers growing in the meadows and along the roads. It contains many chemical compounds. The active ingredients include hypericin and hyperforin.
St. John’s Wort likely lifts mood by boosting serotonin levels, a brain chemical that is a big part of emotion control. Serotonin is “messenger” that affects sleep, appetite, and mood. Low levels of it may result in depression, food cravings and low quality sleep. Clinical trials found that St. John’s Wort controls moderate depression as well as antidepressants do, and with practically no side effects.
In Germany herbal medicines are government-regulated and almost 30 million prescriptions for St. John’s Wort are written annually instead of pharmaceutical grade antidepressants. Recent studies suggest that St. John’s wort is of no benefit in treating major depression. Don’t try to substitute your prescription antidepressants before you discuss it with your doctor.
