Topping up our Energy Bucket
There's a flood of findings on how our emotions effect our perception, and how our DNA is activated or de-activated by our emotional state and triggers from the environment, coming from the world of quantum biology. Pjotr Gariaev and Vladimir Popponin's contributions to this field lead the way, but they are in no way alone. Every day I source more peer-reviewed, published articles coming from neuro-science, quantum physics, quantum biology, and psycho-neuroimmunology that all point to a major shift in the way we understand consciousness. In my latest blog, I want to explore the relationship between brain-wave state and performance.
I include four studies below that each show how our emotional state effects our performance, from the way we experience pain, to how well we can focus and complete tasks. In each of these studies it is apparent that our emotional state has an immediate impact on our brain-wave function - literally the frequency of our brain's electrical output, and this in turn affects our perception. Link this to the studies by Popponin and Gariaev and you can understand how our energy state impacts performance.
Lately I've updated my Key Principles of Energy Management to include a sixth key principle - understanding personality - because, at the end of the day, personality colors the way our emotions show up, and are experienced by others. How we experience life is colored by our personality and our emotional state in the moment. Understanding these factors allows us to work out what we need to add to our Energy Bucket to feel happier, be healthier and maximize our potential.
Why Does Feeling Low Hurt? Depressed Mood Increases the Perception of Pain
ScienceDaily (June 7, 2010) — When it comes to pain, the two competing schools of thought are that it's either "all in your head" or "all in your body." A new study led by University of Oxford researchers indicates that, instead, pain is an amalgam of the two.
Depression and pain often co-occur, but the underlying mechanistic reasons for this have largely been unknown. To examine the interaction between depression and pain, Dr. Chantal Berna and colleagues used brain imaging to see how healthy volunteers responded to pain while feeling low.
Their findings revealed that inducing depressed mood disrupted a portion of the participants' neuro-circuitry that regulates emotion, causing an enhanced perception of pain. In other words, as explained by Dr. Berna, "when the healthy people were made sad by negative thoughts and depressing music, we found that their brains processed pain more emotionally, which lead to them finding the pain more unpleasant."
The authors speculate that being in a sad state of mind and feeling low disables one's ability to regulate the negative emotion associated with feeling pain. Pain, then, has a greater impact. Rather than merely being a consequence of having pain, depressed mood may drive pain and cause it to feel worse.
"Our research suggests depressed mood leads to maladaptive changes in brain function associated with pain, and that depressed mood itself could be a target for treatment by medicines or psychotherapy in this context," commented Dr. Berna. Thus, the next step in this line of research will be to examine this mechanism in individuals who suffer from chronic pain, as these individuals also commonly experience depression. The ultimate goal, of course, is to develop more effective treatments. This is good news for the millions of individuals around the world who suffer from chronic pain and depression.
Editor's Note: This article is not intended to provide medical advice, diagnosis or treatment.
Meditation Reduces the Emotional Impact of Pain, Study Finds
ScienceDaily (June 2, 2010) — People who meditate regularly find pain less unpleasant because their brains anticipate the pain less, a new study has found.
Scientists from The University of Manchester recruited individuals into the study who had a diverse range of experience with meditation, spanning anything from months to decades. It was only the more advanced meditators whose anticipation and experience of pain differed from non-meditators.
The type of meditation practised also varied across individuals, but all included 'mindfulness meditation' practices, such as those that form the basis of Mindfulness-Based Cognitive Therapy (MBCT), recommended for recurrent depression by the National Institute for Health and Clinical Excellence (NICE) in 2004.
"Meditation is becoming increasingly popular as a way to treat chronic illness such as the pain caused by arthritis," said Dr Christopher Brown, who conducted the research. "Recently, a mental health charity called for meditation to be routinely available on the NHS to treat depression, which occurs in up to 50% of people with chronic pain. However, scientists have only just started to look into how meditation might reduce the emotional impact of pain."
The study, to be published in the journal Pain, found that particular areas of the brain were less active as meditators anticipated pain, as induced by a laser device. Those with longer meditation experience (up to 35 years) showed the least anticipation of the laser pain.
Dr Brown, who is based in the University's School of Translational Medicine, found that people who meditate also showed unusual activity during anticipation of pain in part of the prefrontal cortex, a brain region known to be involved in controlling attention and thought processes when potential threats are perceived.
He said: "The results of the study confirm how we suspected meditation might affect the brain. Meditation trains the brain to be more present-focused and therefore to spend less time anticipating future negative events. This may be why meditation is effective at reducing the recurrence of depression, which makes chronic pain considerably worse."
Dr Brown said the findings should encourage further research into how the brain is changed by meditation practice. He said: "Although we found that meditators anticipate pain less and find pain less unpleasant, it's not clear precisely how meditation changes brain function over time to produce these effects.
"However, the importance of developing new treatments for chronic pain is clear: 40% of people who suffer from chronic pain report inadequate management of their pain problem."
In the UK, more than 10 million adults consult their GP each year with arthritis and related conditions. The estimated annual direct cost of these conditions to health and social services is £5.7 billion.
Study co-author Professor Anthony Jones said: "One might argue that if a therapy works, then why should we care how it works? But it may be surprising to learn that the mechanisms of action of many current therapies are largely unknown, a fact that hinders the development of new treatments. Understanding how meditation works would help improve this method of treatment and help in the development of new therapies.
"There may also be some types of patient with chronic pain who benefit more from meditation-based therapies than others. If we can find out the mechanism of action of meditation for reducing pain, we may be able to screen patients in the future for deficiencies in that mechanism, allowing us to target the treatment to those people.
Editor's Note: This article is not intended to provide medical advice, diagnosis or treatment.
Brain Waves and Meditation
ScienceDaily (Mar. 31, 2010) — Forget about crystals and candles, and about sitting and breathing in awkward ways. Meditation research explores how the brain works when we refrain from concentration, rumination and intentional thinking. Electrical brain waves suggest that mental activity during meditation is wakeful and relaxed.
"Given the popularity and effectiveness of meditation as a means of alleviating stress and maintaining good health, there is a pressing need for a rigorous investigation of how it affects brain function," says Professor Jim Lagopoulos of Sydney University, Australia. Lagopoulos is the principal investigator of a joint study between his university and researchers from the Norwegian University of Science and Technology (NTNU) on changes in electrical brain activity during non-directive meditation.
Constant brain waves
Whether we are mentally active, resting or asleep, the brain always has some level of electrical activity. The study monitored the frequency and location of electrical brain waves through the use of EEG (electroencephalography). EEG electrodes were placed in standard locations of the scalp using a custom-made hat.
Participants were experienced practitioners of Acem Meditation, a non-directive method developed in Norway. They were asked to rest, eyes closed, for 20 minutes, and to meditate for another 20 minutes, in random order. The abundance and location of slow to fast electrical brain waves (delta, theta, alpha, beta) provide a good indication of brain activity.
Relaxed attention with theta
During meditation, theta waves were most abundant in the frontal and middle parts of the brain.
"These types of waves likely originate from a relaxed attention that monitors our inner experiences. Here lies a significant difference between meditation and relaxing without any specific technique," emphasizes Lagopoulos.
"Previous studies have shown that theta waves indicate deep relaxation and occur more frequently in highly experienced meditation practitioners. The source is probably frontal parts of the brain, which are associated with monitoring of other mental processes."
"When we measure mental calm, these regions signal to lower parts of the brain, inducing the physical relaxation response that occurs during meditation."
Silent experiences with alpha
Alpha waves were more abundant in the posterior parts of the brain during meditation than during simple relaxation. They are characteristic of wakeful rest.
"This wave type has been used as a universal sign of relaxation during meditation and other types of rest," comments Professor Øyvind Ellingsen from NTNU. "The amount of alpha waves increases when the brain relaxes from intentional, goal-oriented tasks.This is a sign of deep relaxation, -- but it does not mean that the mind is void."
Neuroimaging studies by Malia F. Mason and co-workers at Dartmouth College NH suggest that the normal resting state of the brain is a silent current of thoughts, images and memories that is not induced by sensory input or intentional reasoning, but emerges spontaneously "from within."
"Spontaneous wandering of the mind is something you become more aware of and familiar with when you meditate," continues Ellingsen, who is an experienced practitioner. "This default activity of the brain is often underestimated. It probably represents a kind of mental processing that connects various experiences and emotional residues, puts them into perspective and lays them to rest."
Different from sleep
Delta waves are characteristic of sleep. There was little delta during the relaxing and meditative tasks, confirming that non-directive meditation is different from sleep.
Beta waves occur when the brain is working on goal-oriented tasks, such as planning a date or reflecting actively over a particular issue. EEG showed few beta waves during meditation and resting.
"These findings indicate that you step away from problem solving both when relaxing and during meditation," says Ellingsen.
Nondirective versus concentration
Several studies indicate better relaxation and stress management by meditation techniques where you refrain from trying to control the content of the mind.
"These methods are often described as nondirective, because practitioners do not actively pursue a particular experience or state of mind. They cultivate the ability to tolerate the spontaneous wandering of the mind without getting too much involved. Instead of concentrating on getting away from stressful thought and emotions, you simple let them pass in an effortless way."
Take home message
Nondirective meditation yields more marked changes in electrical brain wave activity associated with wakeful, relaxed attention, than just resting without any specific mental technique.
Editor's Note: This article is not intended to provide medical advice, diagnosis or treatment.
Meditation Helps Increase Attention Span
ScienceDaily (July 16, 2010) — It's nearly impossible to pay attention to one thing for a long time. A new study looks at whether Buddhist meditation can improve a person's ability to be attentive and finds that meditation training helps people do better at focusing for a long time on a task that requires them to distinguish small differences between things they see.
The research was inspired by work on Buddhist monks, who spend years training in meditation. "You wonder if the mental skills, the calmness, the peace that they express, if those things are a result of their very intensive training or if they were just very special people to begin with," says Katherine MacLean, who worked on the study as a graduate student at the University of California, Davis. Her co-advisor, Clifford Saron, did some research with monks decades ago and wanted to study meditation by putting volunteers through intensive training and seeing how it changes their mental abilities.
About 140 people applied to participate; they heard about it via word of mouth and advertisements in Buddhist-themed magazines. Sixty were selected for the study. A group of thirty people went on a meditation retreat while the second group waited their turn; that meant the second group served as a control for the first group. All of the participants had been on at least three five-to-ten day meditation retreats before, so they weren't new to the practice. They studied meditation for three months at a retreat in Colorado with B. Alan Wallace, one of the study's co-authors and a meditation teacher and Buddhist scholar.
The people took part in several experiments; results from one are published in Psychological Science, a journal of the Association for Psychological Science. At three points during the retreat, each participant took a test on a computer to measure how well they could make fine visual distinctions and sustain visual attention. They watched a screen intently as lines flashed on it; most were of the same length, but every now and then a shorter one would appear, and the volunteer had to click the mouse in response.
Participants got better at discriminating the short lines as the training went on. This improvement in perception made it easier to sustain attention, so they also improved their task performance over a long period of time. This improvement persisted five months after the retreat, particularly for people who continued to meditate every day.
The task lasted 30 minutes and was very demanding. "Because this task is so boring and yet is also very neutral, it’s kind of a perfect index of meditation training," says MacLean. "People may think meditation is something that makes you feel good and going on a meditation retreat is like going on vacation, and you get to be at peace with yourself. That's what people think until they try it. Then you realize how challenging it is to just sit and observe something without being distracted."
This experiment is one of many that were done by Saron, MacLean and a team of nearly 30 researchers with the same group of participants. It's the most comprehensive study of intensive meditation to date, using methods drawn from fields as diverse as molecular biology, neuroscience, and anthropology. Future analyses of these same volunteers will look at other mental abilities, such as how well people can regulate their emotions and their general well-being.
Editor's Note: This article is not intended to provide medical
Lis Faenza is a Performance expert with a passion for communicating the latest scientific findings about consciousness. You can subscribe to Lis' free newsletter at her website: http://www.thebucketrevolution.com
