Tag Archives: Doris Tsao

2024 Kavli Prize Laureates: in the fields of astrophysics, nanoscience and neuroscience

The Kavli Prize has yet to acquire the lustre of a Nobel Prize (first awarded in 1901 as per its Wikipedia entry). By comparison the Kavli Prize is relatively new (established in 2005 as per its Wikipedia entry) but it appears to be achieving big deal status in the US.

This year’s crop of prize winners was listed in a June 12, 2024 Kavli Foundation news release on EurekAlert,

Eight scientists from three countries are honored for their research that has broadened our understanding of the big, the small and the complex.

June 12, 2024 (Oslo, Norway) — The Norwegian Academy of Science and Letters today announced the 2024 Kavli Prize Laureates in the fields of astrophysics, nanoscience and neuroscience. Eight scientists from three countries are honored for their research that has broadened our understanding of the big, the small and the complex. The laureates in each field will share $1 million USD. 

The 2024 Kavli Prizes recognize groundbreaking science for the discovery and characterization of extra-solar planets and their atmospheres; foundational research integrating synthetic nanoscale materials for biomedical use; and the localization of areas in the brain specialized for face recognition and processing.  

The 2024 Kavli Prize Laureates are:  

  • Kavli Prize in Astrophysics: David Charbonneau (Canada/USA) and Sara Seager (Canada/USA) 
  • Kavli Prize in Nanoscience: Robert S. Langer (USA), Armand Paul Alivisatos (USA) and Chad A. Mirkin (USA) 
  • Kavli Prize in Neuroscience: Nancy Kanwisher (USA), Winrich Freiwald (Germany), and Doris Tsao (USA) 

“The Kavli Prize 2024 honors outstanding researchers doing fundamental science that moves the world forward. They are exploring planets outside our solar system; they have broadened the scientific field of nanoscience towards biomedicine; and they are adding to our understanding of the neurological basis of face recognition,” said Lise Øvreås, president at The Norwegian Academy of Science and Letters.  

Astrophysics: Searching for life beyond Earth  

The 2024 Kavli Prize in Astrophysics honors Sara Seager and David Charbonneau for discoveries of exoplanets and the characterization of their atmospheres. They pioneered methods for the detection of atomic species in planetary atmospheres and the measurement of their thermal infrared emission, setting the stage for finding the molecular fingerprints of atmospheres around both giant and rocky planets. Their contributions have been key to the enormous progress seen in the last 20 years in the exploration of myriad exo-planets.  

“Humans have always looked towards the stars for discoveries. The pivotal research conducted by Seager and Charbonneau has been an important first step towards finding new planets and strong evidence of life elsewhere in the universe,” remarked Viggo Hansteen, Chair of the Astrophysics Committee.  

David Charbonneau led the team that used the transit method to discover a giant exoplanet (HD 209458b). He pioneered the application of space-based observatories to perform the first studies of the atmosphere of giant extrasolar planets. This new method measures the tiny amount of light blocked by such a planet as it passes in front of its host star. Charbonneau has also used the transit method to study exoplanetary atmospheres, measuring molecular spectra using both filtered starlight and infrared emission from the planets themselves. He demonstrated these two approaches with observations from the Hubble Space Telescope in 2002 and the Spitzer Space Telescope three years later.  

Sara Seager pioneered the theoretical study of planetary atmospheres and predicted the presence of atomic and molecular species detectable by transit spectroscopy, most notably the alkali gases. She predicted how transits could be used to measure atomic and molecular characteristics in exoplanetary atmospheres, which is crucial for identifying biomarkers – signs of life. Seager made outstanding contributions to the understanding of planets with masses below that of Neptune. She also carried out extensive research on starshades – enormous petal-like structures designed to shield space observatories from the glare of a faraway Sun-like star – and was among the first to recognize their importance in detecting and characterizing the faint light from any Earth-like planet orbiting the star. 

Nanoscience: Integrating nanomaterials for biomedical advances 

The 2024 Kavli Prize in Nanoscience honors Robert S. Langer, Armand Paul Alivisatos and Chad A. Mirkin who each revolutionized the field of nanomedicine by demonstrating how engineering nanoscale materials can advance biomedical research and application. Their discoveries contributed foundationally to the development of therapeutics, vaccines, bioimaging and diagnostics.   

“The three scientists, Langer, Alivisatos and Mirkin, have broadened the scientific field of nanoscience, building from fundamental research. By scientific curiosity they have become inventors for the future of nanoscience and biomedicine,” stated Bodil Holst, Chair of the Nanoscience Committee.  

Robert S. Langer was the first to develop nano-engineered materials that enabled the controlled release, or regular flow, of drug molecules. This capability has had an immense impact for the treatment of a range of diseases, such as aggressive brain cancer, prostate cancer and schizophrenia. His work also showed that tiny particles, containing protein antigens, can be used in vaccination, and was instrumental in the development of the delivery of mRNA vaccines. 

Armand Paul Alivisatos demonstrated that semiconductor nanocrystals, or quantum dots (nanoparticles that possess bright, size-dependent light-emitting properties), can be used as multicolor probes in bioimaging. Essential to this achievement was the synthesis of biocompatible nanocrystals. Semiconductor nanocrystals became the basis for the widely used research and diagnostic tools such as live cell tracking, labelling and in vivo imaging. 

Chad A. Mirkin engineered spherical nucleic acids (SNA) using a gold nanoparticle as the core, and a cloud of radially distributed DNA or RNA strands as the shell. He was then able to show how SNAs can be combined to create larger structures and how they can be used in biodiagnostics. His discovery led to the development of fast, automated point-of-care medical diagnostic systems.  

Neuroscience: Understanding recognition of faces 

The 2024 Kavli Prize in Neuroscience honors Nancy Kanwisher, Doris Tsao and Winrich Freiwald for the discovery of a specialized system within the brain to recognize faces. Their discoveries have provided basic principles of neural organization and made the starting point for further research on how the processing of visual information is integrated with other cognitive functions.  

“Kanwisher, Freiwald and Tsao together discovered a localized and specialized neocortical system for face recognition. Their outstanding research will ultimately further our understanding of recognition not only of faces, but objects and scenes,” commented Kristine Walhovd, Chair of the Neuroscience Committee.  

Nancy Kanwisher was the first to prove that a specific area in the human neocortex is dedicated to recognizing faces, now called the fusiform face area. Using functional magnetic resonance imaging (fMRI) she found individual differences in the location of this area and devised an analysis technique to effectively localize specialized functional regions in the brain. This technique is now widely used and applied to domains beyond the face recognition system.  

Elaborating on Kanwisher’s findings, Winrich Freiwald and Doris Tsao studied macaques and mapped out six distinct brain regions, known as the face patch system, including these regions’ functional specialization and how they are connected. By recording the activity of individual brain cells, they revealed how cells in some face patches specialize in faces with particular views.  

Tsao proceeded to identify how the face patches work together to identify a face, through a specific code that enables single cells to identify faces by assembling information of facial features. For example, some cells respond to the presence of hair, others to the distance between the eyes. 

Freiwald uncovered that a separate brain region, called the temporal pole, accelerates our recognition of familiar faces, and that some cells are selectively responsive to familiar faces. 

There’s a video of the official 2024 Kavli Prize announcement which despite the Kavli Foundation being headquartered in California, US, was held (as noted in the news release) at the Norwegian Academy of Science and Letters where the organization’s president, Lise Øvreås, revealed the 2024 Kavli Prize laureates..(I’ll get back to that choice of location.)

The 2024 Kavli Prize in Nanoscience

There are many posts here featuring work from Robert S. Langer (or Robert Langer), Armand Paul Alivisatos (or Paul Alivisatos or A. Paul Alivisatos) and Chad A. Mirkin (or Chad Mirkin).

Northwestern University (Chicago, Illinois) issued a June 12, 2024 news release (also received via email) by Maria Paul that provides a few more details about the nanoscience winners (main focus: Chad Mirkin), the prize, and the Kavli Foundation. Note: A link has been removed,

Northwestern University nanoscientist Chad Mirkin has been awarded The 2024 Kavli Prize in Nanoscience by The Norwegian Academy of Science and Letters. Mirkin is the first Northwestern scientist to receive the prestigious award.

Mirkin is recognized for his discovery of spherical nucleic acids (SNAs), nanostructures comprised of a nanoparticle core and a shell of radially distributed DNA or RNA strands. These globular forms of nucleic acids have become the cornerstones of the burgeoning fields of nanomedicine and colloidal crystal engineering with DNA. They allow scientists to construct new forms of matter using particle “atoms” as the basic building blocks and DNA “bonds” as particle interconnects, and they are the basis for powerful tools that allow researchers and clinicians to track and treat disease in new ways. In particular, SNAs have led to the development of fast, automated point-of-care medical diagnostic systems and new experimental drugs for treating many forms of cancer, neurological disorders, and diseases of the skin.

Mirkin is one of three laureates in nanoscience recognized by The Norwegian Academy for revolutionizing the field of nanomedicine by demonstrating how engineering nanoscale structures can advance biomedical research and application. The other two are Robert Langer of the Massachusetts Institute of Technology and Paul Alivisatos of the University of Chicago [emphasis mine]. The scientists’ discoveries “contributed foundationally to the development of therapeutics, vaccines, bioimaging and diagnostics,” The Norwegian Academy said in a release. They will share the $1 million award.

“When I first found out I won The Kavli Prize, there was both excitement but also relief, because I consider Northwestern to be the ultimate center for nanotechnology research,” Mirkin said. “To be recognized with this award, along with my incredible co-awardees, was great validation of what we’ve been trying to do at Northwestern. While I’m proud of what we’ve accomplished, the best is yet to come.”

The laureates will be awarded the prize on Sept. 3 during a ceremony in Oslo, Norway, presided over the by The Royal Family. The Kavli Prizes thus far have honored 65 scientists from 13 countries. Ten laureates received the Nobel Prize after receiving The Kavli Prize. [emphasis mine]

“I am thrilled for Chad, for the International Institute for Nanotechnology and for Northwestern,” Northwestern President Michael Schill said. “Chad has earned this prestigious and influential award in a pathbreaking area of science that is aligned with two of the University’s key priorities — to lead in decarbonization, renewable energy and sustainability, and innovating in the biosciences to help prolong lives and make the world a healthier place.

“Through groundbreaking research and hard work, Chad and his team have made Northwestern a leading center for nanotechnology research and investment. The fact that he is sharing this award with President Alivisatos at U of C further emphasizes how the Chicago area has become an international hub for nano research.”

The vision for The Kavli Prize comes from Fred Kavli, a Norwegian-American entrepreneur and philanthropist [emphasis mine] who turned his lifelong fascination with science into a lasting legacy for recognizing scientific breakthroughs and supporting basic research.

Since the first awards in 2008, The Kavli Prize has recognized innovative scientific research — from the discovery of CRISPR-Cas9 to the detection of gravitational waves — transforming our understanding of the big, the small and the complex.

Mirkin’s discovery of SNAs has far-reaching implications for biology and medicine. SNAs, which have no known natural equivalents, interact uniquely with living systems compared to nucleic acids of other forms. Mirkin was the first to synthesize SNAs and elucidate the distinctive chemical and physical properties that underpin their use in transformative techniques and technologies in medicine and the life sciences. This work has led to the development of the first commercialized molecular medical diagnostic systems of the modern nanotechnology era, such as the Food and Drug Administration-cleared Verigene System, used in over half of the world’s top hospitals to detect diseases with high sensitivity and selectivity.

Illinois Gov. JB Pritzker praised Mirkin for his extraordinary contributions to the field of nanotechnology and how his innovations have helped find solutions to some of society’s biggest challenges.

“Academic institutions in Chicago and across Illinois have become the biggest drivers in nanoscience and technology over the last three decades,” Pritzker said. “Chad Mirkin and his Northwestern colleagues have made outstanding scientific discoveries that change how we view the world around us.”

In 1996, Mirkin created the first SNAs with DNA shells on gold nanoparticle cores. Over the years, he has developed numerous other types of SNAs with other shells and cores, including proteins, liposomes and FDA-approved materials, as well as core-less, hollow structures composed entirely of nucleic acids. These cores impart unique properties to the SNAs, such as optical and magnetic characteristics, while also serving as scaffolds to densely arrange the oligonucleotides, which participate in binding. This dense arrangement gives rise to the novel functional properties that differentiate SNAs from the natural linear and two-dimensional nucleic acids and make them particularly effective in interacting with certain biological structures within cells and tissues. SNAs, unlike conventional DNA and RNA, are naturally taken up by cells without the need for toxic, positively charged co-carriers, making them highly effective in RNA interference (RNAi), antisense gene regulation, and gene editing pathways.

Mirkin’s pioneering work on SNAs has also advanced the development of immunotherapeutics, structures capable of stimulating a patient’s immune response to fight both infectious diseases and certain forms of cancer. Using SNAs, Mirkin has pioneered the concept of rational vaccinology, where he demonstrated that the structure of a vaccine, rather than the components alone, is crucial for dictating its therapeutic effectiveness. This insight and these “structural nanomedicines” have opened new possibilities for developing curative treatments by rearranging known components into more effective structures at the nanoscale. Mirkin founded Flashpoint Therapeutics to commercialize these innovations, focusing on nucleic acid-based nanostructure cancer vaccines. Mirkin also invented the first SNA-based antiviral vaccine, using COVID-19 as a model. These SNAs, featuring the spike protein’s RBD subunit in the core, achieved a 100% survival rate in humanized mice challenged with the live virus. These structures and concepts for designing such vaccines are poised to move vaccine development beyond the current mRNA vaccines.

In addition, Mirkin invented dip-pen nanolithography, initially a technique for molecular writing with nanometer-scale precision that has evolved into a powerful platform for tip-based materials synthesis that, when combined with artificial intelligence, is revolutionizing how materials important for many sectors, especially clean energy, are discovered. Dip-pen nanolithography, which has spurred subsequent techniques that now use tens of millions of tiny tips to rapidly synthesize materials to be explored for such purposes, was recognized by National Geographic as one of the “top 100 scientific discoveries that changed the world.” These innovations are being commercialized by Mattiq, Inc., another venture-backed company Mirkin cofounded. Mirkin and his students also invented high-area rapid printing, an additive manufacturing technology, that is being commercialized by Azul 3D and being used to disrupt the microelectronics and optical lens industries.

Mirkin’s research has progressed SNA drugs through seven human clinical trials so far for treating various cancers, including glioblastoma multiforme and Merkel cell carcinoma. One SNA drug has shown remarkable potential in stimulating the immune system, proving effective in models of breast, colorectal and bladder cancers, lymphoma and melanoma. This drug has achieved complete tumor elimination in a subset of patients with Merkel cell carcinoma during Phase 1b/2 clinical trials, earning FDA fast-track and orphan drug status. It was recently licensed to Bluejay Therapeutics to treat hepatitis.

In 2000, Mirkin founded the International Institute for Nanotechnology (IIN) at Northwestern University, which he also directs. Research at the IIN has led to over 2,000 new commercial products sold globally and the creation of more than 40 startup companies. The IIN has collectively brought together over $1.2 billion to support research, education and infrastructure at Northwestern since its inception.

Mirkin is the George B. Rathmann Professor of Chemistry and a professor of medicine, chemical and biological engineering, biomedical engineering, and materials science and engineering at Northwestern. He is among an elite group of scientists elected to all three branches of the U.S. National Academies — the National Academy of Sciences, the National Academy of Engineering and the National Academy of Medicine. He is a member of the American Academy of Arts and Sciences. Mirkin served on President Obama’s Council of Advisors on Science and Technology for eight years.

Congratulations to all of the winners in all of the categories!

As for the Norway announcement, it makes a bit of sense given that Fred Kavli was a Norwegian American. However, it’s a little hard to avoid the suspicion that there might be some regional and prize rivalry between Norway with its Kavli and Sweden its Nobel..

Nanotechnology and the US mega science project: BAM (Brain Activity Map) and more

The Brain Activity Map (BAM) project received budgetary approval as of this morning, Apr. 2, 2013 (I first mentioned BAM in my Mar. 4, 2013 posting when approval seemed imminent). From the news item, Obama Announces Huge Brain-Mapping Project, written by Stephanie Pappas for Yahoo News (Note: Links have been removed),

 President Barack Obama announced a new research initiative this morning (April 2) to map the human brain, a project that will launch with $100 million in funding in 2014.

The Brain Activity Map (BAM) project, as it is called, has been in the planning stages for some time. In the June 2012 issue of the journal Neuron, six scientists outlined broad proposals for developing non-invasive sensors and methods to experiment on single cells in neural networks. This February, President Obama made a vague reference to the project in his State of the Union address, mentioning that it could “unlock the answers to Alzheimer’s.”

In March, the project’s visionaries outlined their final goals in the journal Science. They call for an extended effort, lasting several years, to develop tools for monitoring up to a million neurons at a time. The end goal is to understand how brain networks function.

“It could enable neuroscience to really get to the nitty-gritty of brain circuits, which is the piece that’s been missing from the puzzle,” Rafael Yuste, the co-director of the Kavli Institute for Brain Circuits at Columbia University, who is part of the group spearheading the project, told LiveScience in March. “The reason it’s been missing is because we haven’t had the techniques, the tools.” [Inside the Brain: A Journey Through Time]

Not all neuroscientists support the project, however, with some arguing that it lacks clear goals and may cannibalize funds for other brain research.

….

I believe the $100M mentioned for 2014 would one installment in a series totaling up to $1B or more. In any event, it seems like a timely moment to comment on the communications campaign that has been waged on behalf of the BAM. It reminds me a little of the campaign for graphene, which was waged in the build up to the decision as to which two projects (in a field of six semi-finalists, then narrowed to a field of four finalists) should receive a FET (European Union’s Future and Emerging Technology) 1 billion euro research prize each. It seemed to me even a year or so before the decision that graphene’s win was a foregone conclusion but the organizers left nothing to chance and were relentless in their pursuit of attention and media coverage in the buildup to the final decision.

The most recent salvo in the BAM campaign was an attempt to link it with nanotechnology. A shrewd move given that the US has spent well over $1B since the US National Nanotechnology Initiative (NNI) was first approved in 2000. Linking the two projects means the NNI can lend a little authority to the new project (subtext: we’ve supported a mega-project before and that was successful) while the new project BAM can imbue the ageing NNI with some excitement.

Here’s more about nanotechnology and BAM from a Mar. 27, 2013 Spotlight article by Michael Berger on Nanowerk,

A comprehensive understanding of the brain remains an elusive, distant frontier. To arrive at a general theory of brain function would be an historic event, comparable to inferring quantum theory from huge sets of complex spectra and inferring evolutionary theory from vast biological field work. You might have heard about the proposed Brain Activity Map – a project that, like the Human Genome Project, will tap the hive mind of experts to make headway in the understanding of the field. Engineers and nanotechnologists will be needed to help build ever smaller devices for measuring the activity of individual neurons and, later, to control how those neurons function. Computer scientists will be called upon to develop methods for storing and analyzing the vast quantities of imaging and physiological data, and for creating virtual models for studying brain function. Neuroscientists will provide critical biological expertise to guide the research and interpret the results.

Berger goes on to highlight some of the ways nanotechnology-enabled devices could contribute to the effort. He draws heavily on a study published Mar. 20, 2013 online in ACS (American Chemical Society)Nano. Shockingly, the article is open access. Given that this is the first time I’ve come across an open access article in any of the American Chemical Society’s journals, I suspect that there was payment of some kind involved to make this information freely available. (The practice of allowing researchers to pay more in order to guarantee open access to their research in journals that also have articles behind paywalls seems to be in the process of becoming more common.)

Here’s a citation and a link to the article about nanotechnology and BAM,

Nanotools for Neuroscience and Brain Activity Mapping by A. Paul Alivisatos, Anne M. Andrews, Edward S. Boyden, Miyoung Chun, George M. Church, Karl Deisseroth, John P. Donoghue, Scott E. Fraser, Jennifer Lippincott-Schwartz, Loren L. Looger, Sotiris Masmanidis, Paul L. McEuen, Arto V. Nurmikko, Hongkun Park, Darcy S. Peterka, Clay Reid, Michael L. Roukes, Axel Scherer, Mark Schnitzer, Terrence J. Sejnowski, Kenneth L. Shepard, Doris Tsao, Gina Turrigiano, Paul S. Weiss, Chris Xu, Rafael Yuste, and Xiaowei Zhuang. ACS Nano, 2013, 7 (3), pp 1850–1866 DOI: 10.1021/nn4012847 Publication Date (Web): March 20, 2013
Copyright © 2013 American Chemical Society

As these things go, it’s a readable article for people without a neuroscience education provided they don’t mind feeling a little confused from time to time. From Nanotools for Neuroscience and Brain Activity Mapping (Note: Footnotes and links removed),

The Brain Activity Mapping (BAM) Project (…) has three goals in terms of building tools for neuroscience capable of (…) measuring the activity of large sets of neurons in complex brain circuits, (…) computationally analyzing and modeling these brain circuits, and (…) testing these models by manipulating the activities of chosen sets of neurons in these brain circuits.

As described below, many different approaches can, and likely will, be taken to achieve these goals as neural circuits of increasing size and complexity are studied and probed.

The BAM project will focus both on dynamic voltage activity and on chemical neurotransmission. With an estimated 85 billion neurons, 100 trillion synapses, and 100 chemical neurotransmitters in the human brain,(…) this is a daunting task. Thus, the BAM project will start with model organisms, neural circuits (vide infra), and small subsets of specific neural circuits in humans.

Among the approaches that show promise for the required dynamic, parallel measurements are optical and electro-optical methods that can be used to sense neural cell activity such as Ca2+,(7) voltage,(…) and (already some) neurotransmitters;(…) electrophysiological approaches that sense voltages and some electrochemically active neurotransmitters;(…) next-generation photonics-based probes with multifunctional capabilities;(18) synthetic biology approaches for recording histories of function;(…) and nanoelectronic measurements of voltage and local brain chemistry.(…) We anticipate that tools developed will also be applied to glia and more broadly to nanoscale and microscale monitoring of metabolic processes.

Entirely new tools will ultimately be required both to study neurons and neural circuits with minimal perturbation and to study the human brain. These tools might include “smart”, active nanoscale devices embedded within the brain that report on neural circuit activity wirelessly and/or entirely new modalities of remote sensing of neural circuit dynamics from outside the body. Remarkable advances in nanoscience and nanotechnology thus have key roles to play in transduction, reporting, power, and communications.

One of the ultimate goals of the BAM project is that the knowledge acquired and tools developed will prove useful in the intervention and treatment of a wide variety of diseases of the brain, including depression, epilepsy, Parkinson’s, schizophrenia, and others. We note that tens of thousands of patients have already been treated with invasive (i.e., through the skull) treatments. [emphases mine] While we hope to reduce the need for such measures, greatly improved and more robust interfaces to the brain would impact effectiveness and longevity where such treatments remain necessary.

Perhaps not so coincidentally, there was this Mar. 29, 2013 news item on Nanowerk,

Some human cells forget to empty their trash bins, and when the garbage piles up, it can lead to Parkinson’s disease and other genetic and age-related disorders. Scientists don’t yet understand why this happens, and Rice University engineering researcher Laura Segatori is hoping to change that, thanks to a prestigious five-year CAREER Award from the National Science Foundation (NSF).

Segatori, Rice’s T.N. Law Assistant Professor of Chemical and Biomolecular Engineering and assistant professor of bioengineering and of biochemistry and cell biology, will use her CAREER grant to create a toolkit for probing the workings of the cellular processes that lead to accumulation of waste material and development of diseases, such as Parkinson’s and lysosomal storage disorders. Each tool in the kit will be a nanoparticle — a speck of matter about the size of a virus — with a specific shape, size and charge.  [emphases mine] By tailoring each of these properties, Segatori’s team will create a series of specialized probes that can undercover the workings of a cellular process called autophagy.

“Eventually, once we understand how to design a nanoparticle to activate autophagy, we will use it as a tool to learn more about the autophagic process itself because there are still many question marks in biology regarding how this pathway works,” Segatori said. “It’s not completely clear how it is regulated. It seems that excessive autophagy may activate cell death, but it’s not yet clear. In short, we are looking for more than therapeutic applications. We are also hoping to use these nanoparticles as tools to study the basic science of autophagy.”

There is no direct reference to BAM but there are some intriguing correspondences.

Finally, there is no mention of nanotechnology in this radio broadcast/podcast and transcript but it does provide more information about BAM (for many folks this was first time they’d heard about the project) and the hopes and concerns this project raises while linking it to the Human Genome Project. From the Mar. 31, 2013 posting of a transcript and radio (Kera News; a National Public Radio station) podcast titled, Somewhere Over the Rainbow: The Journey to Map the Human Brain,

During the State of the Union, President Obama said the nation is about to embark on an ambitious project: to examine the human brain and create a road map to the trillions of connections that make it work.

“Every dollar we invested to map the human genome returned $140 to our economy — every dollar,” the president said. “Today, our scientists are mapping the human brain to unlock the answers to Alzheimer’s.”

Details of the project have slowly been leaking out: $3 billion, 10 years of research and hundreds of scientists. The National Institutes of Health is calling it the Brain Activity Map.

Obama isn’t the first to tout the benefits of a huge government science project. But can these projects really deliver? And what is mapping the human brain really going to get us?

Whether one wants to call it a public relations campaign or a marketing campaign is irrelevant. Science does not take place in an environment where data and projects are considered dispassionately. Enormous amounts of money are spent to sway public opinion and policymakers’ decisions.

ETA Ap. 3, 2013: Here are more stories about BAM and the announcement:

BRAIN Initiative Launched to Unlock Mysteries of Human Mind

Obama’s BRAIN Only 1/13 The Size Of Europe’s

BRAIN Initiative Builds on Efforts of Leading Neuroscientists and Nanotechnologists