As I suggested in my proposal i have been investigating expanding the idea of artist to all aspects of my life. Just as the Holistic Detective, Dirk Gently in in Douglas Adams book of the same name, I can live life with an open mind ready to follow whatever turns and twists it makes. Just to live creatively and with artistic intent is enough.The powers of complexity theory and emergence will ensure that new startling creative events and ideas will happen of their own accord. In fact trying to control and force the issues will actually thwart the process. My interest in the notions of Transdisciplinarity is now extending to my own creative life. Why would I artificially balkanise aspects of my creative life, let alone other aspects of my existence? This type of painting belongs there whilst this other type is here? This landscape is not critically engaged, this portrait is? It has become clear that although the markets were such work might go and sell in may be different, the source and cross pollination come from a common stream.
Kon-Marie Method in Progress. Here I am following the advice of the Japanese specialist in tidying. I have discarded 70-80% of my clothes and now arrange them in fold colour-coded states. I thank my clothes and bags for their service. It is a suprising and fulfilling process.
Consciousness. Expanding such.... I am taking nootropics which are a group of chemicals which enhance brain function.
All my initial discoveries regarding Metamodernism, group crit response, reflect on my inabilities. pre language life?
Transdisciplinarity and being a Holistic artist, Kon-Marie, clothes paints, brushes. Being in Madrid and visiting studios. Jack Stephenson painter’s arrangements. being interested in life, food politics. The timid voice, is this a performance? I thought everyone thought like me, not so many do, the circumstances of childhood, non speech, being. Berger’s we feels see touch, before we speak.
Transdisciplinarity Susan Rowland, Zeki, Complexity theory
Creativity, Fasting, Meditation, Plants and Chemists.
Using TransCranial Stimulation, some quotes and excerpts:
“There are a variety of different devices, however the simplest and most common approach is to place two saline soaked sponges on the scalp and run a weak electrical current through them,” senior author Dr. Michael D. Fox of Beth Israel Deaconess Medical Center in Boston told Reuters Health by email. “It can be done at home with a couple of sponges and a 9 volt battery, which is why DIY tDCS exists. Whether it should be done is a different question.
Transcranial direct current stimulation (tDCS) can improve some brain functions, but most studies have focused on easing symptoms for patients with brain disease, said coauthor Dr. Roy H. Hamilton of the University of Pennsylvania in Philadelphia.
“Transcranial electrical stimulation of the brain seems to be safe from experimental and clinical data we have available, at least at the levels that we administer it in research studies and clinical studies,” Hamilton told Reuters Health by phone. “At those levels and durations the side effect profile for tDCS is mild.”
Some people experience an itching or burning sensation at the stimulation site, some report headache or fatigue, but generally speaking there are no serious or adverse effects in medical settings, he said.
The risks and benefits for healthy people will be different, Hamilton said.
“For individuals who are interested in enhancing their cognition, it does seem as though when applied transiently there is some gain there,” he said.
But electrical stimulation may affect other regions of the brain, beyond those directly beneath the electrodes. It may interact with ongoing brain activity if a user is active during stimulation, may improve some functions while hindering others, and effects may vary widely by individual, the authors write in the Annals of Neurology.
“I’d estimate that there have been tens of thousands of devices sold in the last few years, though it’s not clear whether people purchase them and continue to use them, or whether they purchase them and throw them away,” said Anna Wexler, visiting scholar at the Center for Neuroscience and Society at the University of Pennsylvania who was not part of the new editorial.
The strongest evidence indicates electrical stimulation can be effective for treating depression or pain, Wexler told Reuters Health by email.
“It’s unclear whether or not the risk:benefit ratio is as favorable when you’re talking not about undoing the effects of some injury or disease but taking normal individuals and enhancing them to a point above their normalcy,” Hamilton said. “It’s unclear how much risk one ought to tolerate.”
He doesn’t want to dissuade or encourage people to try this at home, he said.
“There’s no restriction that would preclude a person from purchasing a device online or going to local radio shack and creating one of these devices themselves,” he said.
“I do think it’s important for them to have a sense of the kinds of things that are known or not known about stimulation,” Hamilton said. “And possible effects that stimulation might have that they may or may not be considering.” Reported by Kathryn Doyle, in Reuters July 22, 2016.
An open letter concerning do-it-yourself users of transcranial direct current stimulation
Rachel Wurzman Phd
Roy H. Hamilton MD, MS
Alvaro Pascual-Leone MD, PhD
Michael D. Fox MD, Ph
- First published: 7 July 2016
As clinicians and scientists who study noninvasive brain stimulation, we share a common interest with do-it-yourself (DIY) users, namely administering transcranial direct current stimulation (tDCS) to improve brain function. Evidence suggests that DIY users reference the scientific literature to guide their use of tDCS, including published ethical and safety standards.[2-4] However, as discussed at a recent Institute of Medicine Workshop, there is much about noninvasive brain stimulation in general, and tDCS in particular, that remains unknown. Whereas some risks, such as burns to the skin and complications resulting from electrical equipment failures, are well recognized,[6-8] other problematic issues may not be immediately apparent. We perceive an ethical obligation to draw the attention of both professionals and DIY users to some of these issues.
Stimulation affects more of the brain than a user may think. Electrodes are often placed in specific scalp locations to target specific brain regions. However, stimulation extends well beyond the regions beneath the electrodes. Current flows between electrodes in complex ways based on different tissues in the head, and can affect the function of various structures along its path.[11-15] Furthermore, the effects of tDCS can extend beyond brain regions directly affected by the stimulation to connected brain regions and networks.[16-20] These indirect effects of stimulation on connected brain networks may alter brain functions that are unintended. In other words, brain connectivity has an effect on—and can be affected by—brain stimulation.[21-23]
Stimulation interacts with ongoing brain activity, so what a user does during tDCS changes tDCS effects. Brain stimulation with tDCS has a different effect on neurons that are active during the time of stimulation compared to neurons that are not.[24, 25] Because of this feature, the cognitive or behavioral activity occurring while tDCS is applied will modify the effects.[26-29] Stimulation while reading a book, meditating, visually fixating on a point, watching TV, doing arithmetic, sleeping, or playing video games could all cause different changes in the brain. Even activity occurring before tDCS or the time of day tDCS is administered may change the effects of stimulation. Which activity or time of day is best to achieve a certain change in brain function is not yet known.
Enhancement of some cognitive abilities may come at the cost of others. Cognition involves functional networks, with different components (or combinations thereof) responsible for different functions. In addition, brain networks interact with each other, such that modifying activity in one network can change the activity in other networks. Therefore, stimulating one brain area may improve the ability to perform one task but hurt the ability to perform another. For example, tDCS can enhance the rate of learning new material, but at the cost of processing learned material, and vice versa, depending on the stimulation site. Such tradeoffs are likely under-recognized, as most tDCS studies focus on only one or two tasks. Furthermore, such cognitive tradeoffs could develop over time and only become recognizable long after the stimulation.
Changes in brain activity (intended or not) may last longer than a user may think. Brain plasticity is an ongoing process that is in part driven by neural activity itself, so changes initiated during stimulation can be long lasting and even self-perpetuating. Cognitive enhancements (as well as concurrent tradeoffs) have been reported 6 months after stimulation, and may linger beyond then.[30-32] Ongoing regular application of tDCS may be especially effective for sustaining these benefits, but may also increase risks. We have never formally studied tDCS at the frequencies many DIY users experiment with—for example, stimulating daily for months or longer. Because we know that stimulation from just a few sessions can be quite lasting, we infer that changes induced by these protocols may be even more so. We do not know yet whether such changes are reversible, and the possible risks of a cumulative dose over years or a lifetime have not been studied.
Small differences in tDCS parameters can have a big effect. Mild changes in tDCS settings including current amplitude, stimulation duration, and electrode placement can have big and unexpected effects. For example, increasing the stimulation amplitude from 1 to 2mA or increasing the duration from 10 to 20 minutes might be expected to double the effect, but can actually reverse the effect and cause the opposite change in brain function. More stimulation is not necessarily better; more is simply different. Similarly, slight differences in electrode placement can produce dramatic shifts in the shape of the current path, and thus the neurophysiological effects.[34-36]
tDCS effects are highly variable across different people. Results reported in the scientific literature are almost always averaged across groups of subjects because the effect of tDCS on any one individual is variable and unpredictable.[37, 38] Even across groups of subjects, tDCS effects can be highly variable. Up to 30% of experimental subjects respond with changes in cortical excitability in the opposite direction from other subjects using identical tDCS settings. Even with consistent changes in cortical excitability, these changes can have different effects on individuals' ability to perform a task, including potentially undesirable effects. Furthermore, this variability occurs despite controlled experimental conditions designed to reduce it. Factors such as age,[40, 41] gender, hormones, handedness,[44, 45] cognitive ability,[46, 47] neurological or psychiatric disorders, medications,[48, 49] recreational drugs, neurotransmitter levels, prior exposure to brain stimulation, and differences in head anatomy[12, 36, 52, 53] are likely to impact and could potentially even reverse a given tDCS effect.
The risk/benefit ratio is different for treating diseases versus enhancing function. Despite all the above uncertainty, risks, tradeoffs, and potential detrimental effects of tDCS, there are numerous studies that administer repeated sessions of tDCS with the intent of causing lasting changes in brain function. However, nearly all such studies are performed in patients with brain disease, with the goal of alleviating symptoms. Such studies provide detailed disclosure of risks, according to regulations for informed consent of human research subjects, and risks are evaluated for the patient population to be studied. Consider that the level of acceptable risk is different for healthy subjects, who in general are functioning quite well and thus have less to gain, and more to lose. Application of tDCS in children warrants special consideration given the particularities of the developing nervous system, the scarcity of studies in this population, and that minors are not fully able to assess the risks of tDCS for themselves.
In sum, it is important to know that: (1) the tissue stimulated and effects induced are less deterministic than a user may think, (2) significant tradeoffs may be part of the bargain for functional gains, and (3) whatever brain changes occur may be long-lasting—for better or worse. We encourage consideration of these issues and involvement of health care providers in making decisions regarding DIY brain stimulation.