網路城邦
回本城市首頁 時事論壇
市長:胡卜凱  副市長:
加入本城市推薦本城市加入我的最愛訂閱最新文章
udn城市政治社會政治時事【時事論壇】城市/討論區/
討論區知識和議題 字體:
看回應文章  上一個討論主題 回文章列表 下一個討論主題
腦不在大連接則靈-ScienceDaily
 瀏覽746|回應5推薦1

胡卜凱
等級:8
留言加入好友
文章推薦人 (1)

麥芽糖

More Sophisticated Wiring, Not Just Bigger Brain, Helped Humans Evolve Beyond Chimps, Geneticists Find

 

ScienceDaily (Aug. 22, 2012) — Human and chimp brains look anatomically similar because both evolved from the same ancestor millions of years ago. But where does the chimp brain end and the human brain begin?

 

A new UCLA study pinpoints uniquely human patterns of gene activity in the brain that could shed light on how we evolved differently than our closest relative. Published Aug. 22 in the advance online edition of Neuron, these genes' identification could improve understanding of human brain diseases like autism and schizophrenia, as well as learning disorders and addictions.

 

"Scientists usually describe evolution in terms of the human brain growing bigger and adding new regions," explained principal investigator Dr. Daniel Geschwind, Gordon and Virginia MacDonald Distinguished Professor of Human Genetics and a professor of neurology at the David Geffen School of Medicine at UCLA. "Our research suggests that it's not only size, but the rising complexity within brain centers, that led humans to evolve into their own species."

 

Using post-mortem brain tissue, Geschwind and his colleagues applied next-generation sequencing and other modern methods to study gene activity in humans, chimpanzees and rhesus macaques, a common ancestor for both chimpanzee and humans that allowed the researchers to see where changes emerged between humans and chimpanzees. They zeroed in on three brain regions -- the frontal cortex, hippocampus and striatum.

 

By tracking gene expression, the process by which genes manufacture the amino acids that make up cellular proteins, the scientists were able to search the genomes for regions where the DNA diverged between the species. What they saw surprised them.

 

"When we looked at gene expression in the frontal lobe, we saw a striking increase in molecular complexity in the human brain," said Geschwind, who is also a professor of psychiatry at the Semel Institute for Neuroscience and Behavior at UCLA.

 

While the caudate nucleus remained fairly similar across all three species, the frontal lobe changed dramatically in humans.

 

"Although all three species share a frontal cortex, our analysis shows that how the human brain regulates molecules and switches genes on and off unfolds in a richer, more elaborate fashion," explained first author Genevieve Konopka, a former postdoctoral researcher in Geschwind's lab who is now the Jon Heighten Scholar in Autism Research at University of Texas Southwestern Medical Center. "We believe that the intricate signaling pathways and enhanced cellular function that arose within the frontal lobe created a bridge to human evolution."

 

The researchers took their hypothesis one step further by evaluating how the modified genes linked to changes in function.

 

"The biggest differences occurred in the expression of human genes involved in plasticity -- the ability of the brain to process information and adapt," said Konopka. "This supports the premise that the human brain evolved to enable higher rates of learning."

 

One gene in particular, CLOCK, behaved very differently in the human brain. Considered the master regulator of Circadian rhythm, CLOCK is disrupted in mood disorders like depression and bipolar syndrome.

 

"Groups of genes resemble spokes on a wheel -- they circle a hub gene that often acts like a conductor," said Geschwind. "For the first time, we saw CLOCK assuming a starring role that we suspect is unrelated to Circadian rhythm. Its presence offers a potentially interesting clue that it orchestrates another function essential to the human brain."

 

When comparing the human brain to the non-human primates, the researchers saw more connections among gene networks that featured FOXP1 and FOXP2. Earlier studies have linked these genes to humans' unique ability to produce speech and understand language.

 

"Connectivity measures how genes interact with other genes, providing a strong indicator of functional changes," said Geschwind. "It makes perfect sense that genes involved in speech and language would be less connected in the non-human primate brains -- and highly connected in the human brain."

 

The UCLA team's next step will be to expand their comparative search to 10 or more regions of the human, chimpanzee and maque brains.

 

Geschwind and Konopka's coauthors included Tara Friedrich, Jeremy Davis-Turak, Kellen Winden, Fuying Gao, Leslie Chen, Rui Luo, all of UCLA; Michael Oldham of UC San Francisco; Guang-Zhong Wang of the University of Texas Southwestern Medical Center; and Todd Preuss of Emory University.

 

The research was supported by grants from the National Institute of Mental Health (R37MH060233) and (R00MH090238); a NARSAD Young Investigator Award, the National Center for Research Resources (RR00165) and Office of Research Infrastructure Programs/OD (P51OD11132); and a James S. McDonnell Foundation grant (JSMF 21002093).

 

Story Source:

 

The above story is reprinted from materials provided by University of California, Los Angeles (UCLA), Health Sciences, via Newswise.

Note: Materials may be edited for content and length. For further information, please contact the source cited above.

 

Journal Reference:

 

1.     Genevieve Konopka, Tara Friedrich, Jeremy Davis-Turak, Kellen Winden, Michael C. Oldham, Fuying Gao, Leslie Chen, Guang-Zhong Wang, Rui Luo, Todd M. Preuss, Daniel H. Geschwind. Human-Specific Transcriptional Networks in the Brain. Neuron, 2012; 75 (4): 601 DOI: 10.1016/j.neuron.2012.05.034

 

http://www.sciencedaily.com/releases/2012/08/120822124708.htm



本文於 修改第 2 次
回應 回應給此人 推薦文章 列印 加入我的文摘

引用
引用網址:https://city.udn.com/forum/trackback.jsp?no=2976&aid=4861640
 回應文章
淺談「科學方法」
    回應給: 麥芽糖(myata) 推薦2


胡卜凱
等級:8
留言加入好友

 
文章推薦人 (2)

胡卜凱
麥芽糖

人因為有記憶,才能形成意識,人因為有記憶意識,才能分別「他」、「自」、和「環境」;也才能做比較選擇判斷實踐等行為。所謂「自,指這些分別行為的總和

 

科學(方法)研究」的目的在幫助我們了解人們所觀察到或遭遇到的現象和/或現實;「科學(方法)研究」的功能在幫助我們解決人們遭遇到現象和/或現實所帶來生活上的困難或問題

 

因此,所謂科學(方法)研究」的定義「指」或「蘊涵」:

 

被「研究」的「對象」必須具有感官或儀器能夠接觸到的性質

 

如果不具備這個「可被接觸」的性質,則此對象不在科學(方法)研究」的範圍。但它仍可用思考玄想或冥想等方法」來「研究」。

 

我不知道你稱為ego這個東西的定義是否包含這種「可被接觸」的性質。如果它包含,而且這個或這些性質能被清楚明確的列舉,則你稱為ego的這個東西能夠用「科學方法」來「研究如果它不包含任何「可被接觸」的性質,則你稱為ego的這個東西不能用「科學方法」來「研究

 

用「科學方法」來「研究」的「對象」,其「研究過程」和「研究成果」有兩個性質:

 

a.   所有「科學方法」的「過程」和「成果」都可以被複製;這是「科學研究」的成果具有「公信力」和能夠被普遍應用的基礎和原因

b.   根據科學研究」所得到的「理論」,具有預測力。這個性質是第一個性質的結果它也是科學研究」的必要條件。不具預測力的「理論」,通常無法「被反證」

 

根據Popper的觀點,不能「被反證」的理論,不能稱為「科學理論」。因為我們不能確認它是否能解釋任何現象。也就不可能幫助我們解決人們遭遇到現象和/或現實所帶來生活上的困難或問題從而,不能解釋任何現象的理論沒有任何「實用」價值或「意義」。或其(實用)價值」與「(實用)意義」相當於「鄉野傳說」或「城市故事」

 

上面提到,「所謂『自,指這些分別行為的總和。」;如果接受這個定義,科學家可以從觀察和探究某個人所做的「分別」和其他「行為」來研究個別的「自我」。然後根據這些個別的研究成果,以統計方法來得到一個可驗證的理論。

 

大腦神經科學的大腦神經網路連接理論,「記憶」指各神經細胞間的連接及其強度。這是我介紹三本書裏,其中兩本書名及其子標題的來源

 

J. LeDoux, 2002, Synaptic Self: How Our Brains Become Who We areSynapse兩個神經細胞間的間隔以及它們連接後所形成的(化學)通路

R. R. Llinas, 2002, i of the Vortex: From Neurons to SelfNeuron神經細胞

 

進一步的說明請上網搜尋

 

兩本書的作者各自陳述了他們根據對大腦神經網路連接理論」的研究,所得到的他們對「自我」的了解。

 

人和人之間的衝突」的確由各個「自我」來執行,但「衝突」的來源並非各個「自我衝突」的來源或人和人之間發生「衝突」的原因是,地球上的「自然資源」不敷分配。這是政治學和經濟學試圖解決的,來自現實的問題。



本文於 修改第 1 次
回應 回應給此人 推薦文章 列印 加入我的文摘
引用網址:https://city.udn.com/forum/trackback.jsp?no=2976&aid=4863995
Ego Concious Memory
    回應給: 胡卜凱(jamesbkh) 推薦0


麥芽糖
等級:8
留言加入好友

 

自我 = 意識 = 記憶

基本上:

這三者完全不同

Ego 是人類衝突的來源

Memory 很容易瞭解 一清二楚

Concious 是可以科學分析瞭解的

Ego 則無法用科學去掌握!




回應 回應給此人 推薦文章 列印 加入我的文摘
引用網址:https://city.udn.com/forum/trackback.jsp?no=2976&aid=4863726
大腦神經科學與基因學對法庭的衝擊 – K. Kelland
推薦0


胡卜凱
等級:8
留言加入好友

 

Insight - Neuroscience in court: My brain made me do it

 

Kate Kelland, Health and Science Correspondent, Reuters, 08/29/12

 

LONDON (Reuters) - He was once a respected pediatrician, loved by patients and their parents for over 30 years. Now Domenico Mattiello faces trial for pedophilia, accused of making sexual advances towards little girls in his care.

 

Scientific experts will argue in court that his damaged brain made him do it, and his lawyers will ask for leniency.

 

It's the latest example of how neuroscience - the science of the brain and how it works - is taking the stand and beginning to challenge society's notions of crime and punishment.

 

The issue has been thrown into the spotlight by new technologies, like structural and functional magnetic resonance imaging (MRI), positron emission tomography (PET) scans and DNA analysis, that can help pinpoint the biological basis of mental disorders.

 

A series of recent studies has established that psychopathic rapists and murderers have distinct brain structures that show up when their heads are scanned using MRI.

 

And in the United States, two companies, one called No Lie MRI and another called Cephos Corp, are advertising lie-detection services using fMRI to lawyers and prosecutors.

 

CRIME AND PUNISHMENT

 

While structural MRI scans show the structure of a brain and can highlight differences between one brain and another, PET and fMRI scans can also show the brain in action, lighting up at particular points when the brain engages in certain tasks.

 

But the dazzling new technologies and detailed genetic data leave unanswered the issue of whether criminal courts are the right place to use this new information.

 

"The worry is that the law, or at least some judges, might be so overawed by the technology that they start essentially delegating the decision about guilt to a particular form of test," says Colin Blakemore, a professor of neuroscience at Oxford University.

 

The lawyers for American serial killer Brian Dugan, who was facing execution in Illinois after pleading guilty to raping and killing a 10-year-old girl, used scans of his brain activity to argue he had mental malfunctions and should be spared the death penalty. In the event, Illinois abolished capital punishment while he was on death row.

 

In a court in the Indian city of Mumbai, a woman was convicted of murder based only on circumstantial evidence and a so-called brain electrical oscillations signature profiling (BEOS) test, the results of which prosecutors said suggested she was guilty.

 

The days when mental capacity for crime is argued over by psychiatrists unaided by sophisticated machinery - such as Friday's verdict that Norwegian mass killer Anders Behring Breivik was sane when he killed 77 people - look numbered.

 

"All sorts of types of neuroscience evidence are being used for all sorts of types of claims," says Teneille Brown, a professor of law at the University of Utah. "The question is, is this technology really ready for prime time, or is it being abused?"

 

"ACQUIRED PAEDOPHILIA"

 

In Mattiello's case, the neuroscientific evidence will come in the form of a full psychiatric and biological analysis including an MRI brain scan that shows a roughly 4 centimeter tumor growing at the base of his brain.

 

This created pressure inside his skull and "altered his behavior", says Pietro Pietrini, a molecular geneticist and psychiatrist at Italy's University of Pisa who is compiling an expert report on the 65-year-old.

 

"His previous behavior was completely normal," Pietrini told Reuters. "He was a pediatrician for 30 something years and he saw tens of thousands of children and never had any problem. The question is why, at some point, did someone who has always behaved properly suddenly change so drastically?"

 

The doctor was arrested in Vicenza, northern Italy, more than a year ago and is undergoing cancer treatment after having the tumor removed. Pietrini is due to see him again next month to continue his assessment and see the effects of the treatment.

 

The case, which has yet go to court, is strikingly similar to another of "acquired pedophilia" dating back to 2002, in which a 40-year-old married American schoolteacher suddenly became obsessed with sex and began secretly to collect child pornography.

 

He was eventually removed from the family home for making sexual advances towards his step-daughter and convicted of pedophilia. But later medical examinations found he had an egg-sized tumor in a part of the brain involved in decision-making.

 

When the tumor was removed, the man recovered from his pedophilic tendencies and was able to return to his family.

 

Experts are generally agreed that conditions like psychopathy and pedophilia can't be "cured", but in this groundbreaking case it appeared that removing the tumor, and hence the pressure in the brain, may have re-established his ability to control impulses.

 

As in that case, Pietrini said he and colleague Giuseppe Sartori of Padua University believed Mattiello's tumor "may well have played a role in altering his behavior".

 

"This is what we will be arguing," Pietrini said. "But of course it will be for the judge to determine to what extent he believes this medical condition played a role."

 

Oxford's Blakemore, one of the world's leading thinkers in this field, says such cases are "startling".

 

"It makes one wonder about the notion of responsibility," he said in an interview.

 

IS "MY BRAIN MADE ME DO IT" A DEFENCE?

 

And when it comes to prison, should pedophiles, psychopaths and other violent criminals be punished less severely if their behavior can be blamed on biology? Is "my brain made me do it" a defense that warrants recognition with lighter sentences, or even no jail time at all?

 

"(It) raises the whole issue of what you think sentencing is for," says Blakemore. "Is it about punishment? Is it about retribution? Is it about remediation and rehabilitation? Is it about protecting society? Well, to some extent it's about all of those things."

 

Recent evidence - from both real and hypothetical cases - suggests judges are sympathetic to neurobiological evidence as mitigation.

 

A study published in the journal Science this month showed that criminal psychopaths in the United States whose lawyers provide biological evidence for their brain condition are more likely to be sentenced to shorter jail terms than those who are simply said to be psychopaths.

 

For the study, researchers at the University of Utah tweaked the real-life case of Stephen Mobley, a 39-year-old American who was sentenced to death in 1994 after robbing a Domino's pizza place in Georgia and shooting dead the restaurant's manager.

 

At his trial, Mobley's lawyer presented evidence in mitigation showing the accused had a variant of a gene called MAO-A that has been dubbed the "warrior" gene after scientists found it was linked to violent behavior.

 

AGGRESSIVE GENES

 

In the Science study, judges were given a hypothetical case loosely based on Mobley's, where the crime was a savage beating with a gun, rather than a fatal shooting.

 

All the judges were told the defendant was a psychopath, but only half were given expert testimony on the genetic and neurobiological causes of his psychopathy. Those who got the neuroscientific evidence were more likely to give a shorter sentence - generally about a year less, the study found.

 

Pietrini worked on a similar real-life case in Italy in 2009 - thought to be one of the first criminal cases in Europe to use this type of neuroscientific evidence.

 

It involved Abdelmalek Bayout, an Algerian living in Italy, who was tried and convicted for fatally stabbing a man who teased him in the street.

 

After conducting a series of tests on the Algerian, Pietrini and colleagues said they had found abnormalities in imaging scans of his brain, and in five genes that have been linked to violent behavior — including MAO-A.

 

A 2002 study led by researchers at the Institute of Psychiatry at King's College London linked low levels of MAO-A with aggressiveness and criminal behavior in boys who were raised in abusive environments.

 

Bayout's lawyers got his sentence reduced by arguing that this and other bad genes had affected his brain and were partly to blame for the attack.

 

WHERE WILL IT END?

 

Experts say it's almost inevitable that neuroscience and law will become yet more intertwined. After all, while neuroscience seeks to find out how the brain functions and affects behavior, the law's main concern is with regulating behavior.

 

Yet many are uneasy about the use in courts of law - and in matters of life and death - of basic science that is only just creeping out of the lab.

 

Observers such as Hank Greely, a professor of law at Stanford University, point out that no scientific peer-reviewed studies have been published demonstrating that BEOS - the brain test used in the Mumbai case - actually works.

 

Others stress that while genes like MAO-A have been associated with violence, there are also plenty of people with similar genotypes who don't go out and kill, rape or abuse.

 

"Neuroscience is being used by serious scientists in real labs, but the people trying to apply it in courts are not those same people," says Utah's Brown. "So they're taking something that looks very objective, that looks like gold standard science, but then morphing it into a forensic use it wasn't developed for.

 

"This isn't snake-oil science. It's real science. But it's being misapplied."

 

Seena Fazel, a clinical senior lecturer in forensic psychiatry at Oxford University, says he's uncomfortable with the long-term implications and wonders where it will end.

 

There are already known biological bases for many brain disorders criminals suffer from, including drug addiction, alcoholism and antisocial personality disorder, which is thought to affect up to half of all those in prison.

 

"If psychopathy reduces your sentence because it has a biological basis, why shouldn't these other more common conditions also result in reduced sentences? The problem here is where do we draw the line?"

 

(Reporting by Kate Kelland, editing by David Stamp and Will Waterman)

 

http://news.yahoo.com/insight-neuroscience-court-brain-made-070322193.html



本文於 修改第 1 次
回應 回應給此人 推薦文章 列印 加入我的文摘
引用網址:https://city.udn.com/forum/trackback.jsp?no=2976&aid=4863706
靈魂及意識
    回應給: 麥芽糖(myata) 推薦1


胡卜凱
等級:8
留言加入好友

 
文章推薦人 (1)

麥芽糖

研究和靈魂相關「現象」的領域稱為Parapsychology請參考Parapsychology, http://en.wikipedia.org/wiki/Parapsychology

 

就我讀過的書中,意識」這個概念切入,涉及「靈魂(雖然學者們避免使用此詞)的研究,早幾年有:

 

M. Velmans, Ed., 2000, Investigating Phenomenal Consciousness, John Benjamins Publishing Co.

 

另外,介紹以主流「研究典範」為基礎來研究「意識」的書則有:

 

M. Velmans, Ed., 1996, The Science of Consciousness: Psychological, Neuropsychological, and Clinical Reviews,  Routledge

 

J. LeDoux, 2002, Synaptic Self: How Our Brains Become Who We are, Penguin Books

 

 R. R. Llinas, 2002, i of the Vortex: From Neurons to Self, The MIT Press

 

我是唯物論者。因此,我相當懷疑「靈魂」的存在我相信科學家們能夠以大腦神經科學的概念和研究成果解釋大概60% (> 50%)以上和「精神」這個概念相關的現象我也相信科學家們現在能夠以大腦神經科學的概念和研究成果解釋大概60%以上和「自我」這個概念相關的行為和現象。我的口號是

 

自我 = 意識 = 記憶



本文於 修改第 2 次
回應 回應給此人 推薦文章 列印 加入我的文摘
引用網址:https://city.udn.com/forum/trackback.jsp?no=2976&aid=4863563
科學研究
    回應給: 胡卜凱(jamesbkh) 推薦0


麥芽糖
等級:8
留言加入好友

 

科學家在腦與情緒, 身體之間的研究, 取得長足進步.

不過, 他們總是故意忽略: 靈魂的角色, 不進行研究.

等他們認真考慮靈魂, 開始研究, 人類對於自己的結構, 才會達到真正的瞭解!

回應 回應給此人 推薦文章 列印 加入我的文摘
引用網址:https://city.udn.com/forum/trackback.jsp?no=2976&aid=4863511