View allAll Photos Tagged biosensors
music:
"malabar" by antoine berthiaume, in 'small tease' (2009)
open.spotify.com/track/478X0M1P4MVE0AeNCWd7io?si=0f045491...
“People could look back in 100 years and identify the coronavirus epidemic as the moment when a new regime of surveillance took over, especially surveillance under the skin which I think is maybe the most important development of the 21st Century, is this ability to hack human beings."
Yuval Harari
……..
Directly from the horse mouth —the guy who coined the term Internet of Bio Nano Things:
www.facebook.com/story.php?story_fbid=1135829204310457&am...
The biopower and biopolitics of the biotechnocracy with its nonexistent bioethics of biotechnology. The vaccine gene therapy, altering DNA, manipulating basic biology with spike protein. We will biohack the proteins and DNA that are central to your biology. Human genetic engineering will lead to artificial intelligence and bioengineering. AI and biotechnology will be the end of the real you. Take the jab, take the biohazard, receive your biopassport. Get your biochip, become a bionerd. Don’t be biosensitive; don’t let the bioink leak from yours eyes as you cry out in joy. We wouldn’t want your embedded biosensors to send out an emergency alert, now would we? Synthetic biology and biological data. 666 and the biosurveillance system. Bio-serfdom: equality for all! Let’s eradicate poverty, let’s make y’all biodigital slaves! If you don’t believe transhumanism is right around the corner, then check out the government website below.
Here is an article on the Canadian government website called: Exploring Biodigital Convergence
horizons.gc.ca/en/2020/02/11/exploring-biodigital-converg...
Here is one for you Americans: In science we trust!
“I pledge allegiance to the Flag of the United Nations, and to the New World Order for which it stands, one post-nation under pseudoscience, divisible, without liberty and justice for all.”
Abort millions of babies…oh wait…now we don’t have enough skilled labour, and who is going to pay taxes to look after our ageing population? We have low birth rates, so let’s bring in large numbers of immigrants. Multiculturalism, let’s make you a melting pot of people. We will erode your culture and values…and who needs borders? The future is tranhumanism! Humans will evolve until there is no race or gender or reproduction…as for culture and borders, they will no longer exist…it’s all part of the plan…divide, conquer, and assimilate into the transhuman revolution. Humans will continue to evolve until they no longer resemble humans. Humans will become extinct. Survival of the fittest! Many will die in this evolution of man and AI, but some will adapt and survive. You will be owned like cattle, and once your purpose is fulfilled, we will get rid of you…like we do to those in the womb today…life isn’t sacred…especially if you aren’t even human…just some sort of parasite. Welcome to the New World Order of transhumanism!
Thankfully we have a Saviour, so things will only go so far. The Mark of the Beast is as far as transhumanism will get. When Jesus returns He will throw all the transhumans into hell. That will be the end of transhumanism. There is no eternal life in transhumanism, except for eternal life in hell.
1 Corinthians 3:18-20 “Stop deceiving yourselves. If you think you are wise by this world’s standards, you need to become a fool to be truly wise. For the wisdom of this world is foolishness to God. As the Scriptures say, ‘He traps the wise in the snare of their own cleverness.’ And again, ‘The LORD knows the thoughts of the wise; he knows they are worthless.’”
VPRO Medialab maakte op de Dutch Design Week van 2017 veel indruk met de installatie AURA, ontwikkeld door Studio Nick Verstand in samenwerking met Salvador Breed en Naivi. Het interactieve werk meet emoties van de deelnemers en zet deze om in gekleurde, pulserende lichtcomposities.
iss067e190796 (7/21/2022) --- NASA astronaut Bob Hines is shown performing Genes in Space-9 aboard the International Space Station (ISS). Cell-free technology is a platform for protein production that does not include living cells. GIS-9 evaluates two approaches for using this technology in microgravity: cell-free protein production and biosensors that can detect specific target molecules. The technology could provide a portable, low-resource, and low-cost tool with potential applications for medical diagnostics, on-demand production of medicine and vaccines, and environmental monitoring on future space missions.
Het mooie van de installatie was dat het niet alleen voor de deelnemers een geweldige ervaring was, maar ook de toeschouwer kon genieten van een wonderlijk schouwspel. In deze foto zie je ook hoe een toeschouwer stiekem een blik werpt op de reactie van de man op de grond.
At the AI showcase at Google Cloud HQ today, with NASA, SETI and the Frontier Development Lab. I am adding notes here live, covering:
• Flood detection, prevention and response
• Lunar resource mapping with super-resolution for metal meteorites
• Enhanced predictability of GPS disturbances
• Generation of simulated biosensor data for astronaut health
• Expanding the capabilities of NASA's Solar Dynamics Observatory
► James Parr, FDL Exec Producer
“The secret sauce of AI: space data sets are huge. Sometimes we have to move them with a plane.”
► Eugene Tu, NASA Ames Director:
“Most of the challenging problems of the future will require multidisciplinary solutions. ALL of the future NASA missions will require partnerships. Because our future missions are so multidisciplinary, we will have to partner for a much broader range of capabilities.
Artemis – return to the moon by 2024:
Why go back to the moon? It’s not like Apollo for two reasons:
1) Sustainable presence
2) Commercial and international partnerships
The only way it is sustainable is if it engages a broader space economy. We want to go to learn how to live there, and then Mars, and maybe beyond.
Dragonfly is our next billion dollar mission. We are going to Titan to look for pre-biotic chemistry. We will put a nuclear powered quad-copter on Titan. I love saying that.
2-hour entry interface. We need AI. Most communications and control can’t come from Earth.”
► Bill Diamond, CEO of SETI
Referencing the NASA Ames Director: “I love that his initials are E.T.”
► Scott Penberthy, Director of Applied AI, Google Cloud:
“If you think about a million people on Mars, you have to practice. And the logical place to practice is the moon. Within the decade, we will return to the moon on a regular basis as scientists.”
► Anna Patterson, MD of Google Gradient Ventures:
“Ray Kurzweil points out that AI will not stay on Earth. It will expands outward at the speed of light and spread through the universe. So, AI is not only the most important technology on earth, it is the most important technology in the universe.”
► MOON FOR GOOD — LUNAR RESOURCE MAPPING
Looking for metal meteorites on moon for ISRU (in-situ resource utilization). It is estimated that billions of tons of metallic deposits could exist on the Moon from M-class impactors. How might we use data fusion and emerging super-resolution techniques to develop high-resolution lunar resource maps of these metallic deposits to aid mission planners looking to locate resources for future robotic and human lunar missions? Consider Tycho. It’s deeper than Mt Whitney is tall. Optical, thermal and magnetic signatures.
(I liked this one. Seems like a much better place to mine metal asteroids — for local lunar applications and a rail gun to Earth orbit. And they have a great team)
► DISASTER PREVENTION, PROGRESS AND RESPONSE (FLOODS)
Floods are the most common natural disaster and growing. Can AI improve our capabilities to forecast and respond to floods using orbital imagery to better predict the permeability of surfaces, the likelihood of flash flooding or a burst river? Can ML techniques coupled with USGS ground observations and social data be used to better understand how to save lives in terms of better predictive models before and during a flooding event?
Frequent visible satellite imagery (Planet) enhanced with SAR (synthetic aperture radar) imagery. Made progress on real-time river level predictions. Now using ML to calibrate flood inundation maps to do automated mapping. Goal: better situational awareness.
► LIVING WITH OUR STAR: ENHANCED PREDICTABILITY OF GPS DISTURBANCES
Can we better predict atmospheric scintillations that negatively affect GPS? GPS plays a significant role in modern communication, navigation, positioning, and timing systems. GPS signals often get disrupted while passing through earth's ionosphere, which is a volatile region of charged particles continuously getting affected by solar storms. Small-scale irregularities developed in the ionosphere as a result of solar disturbances are responsible for GPS signal disruptions, and incredibly challenging to predict at a given location and time. This challenge is to use the insight about what affects the ionospheric behavior, from the sun to the magnetosphere to aurora borealis, combined with machine learning approaches to predict GPS signal disruptions at high-latitudes.
Auroras correlate with interrupted GPS, but aurora images are diffuse and hard to analyze. Discrete structures and arcs in the aurora were found to correlate with the GPS disturbances. Several CNN layers and predictive model, but with too many false positives still. Getting better at predicting in space and time where these disturbances will occur.
Taken on an FEI Verios 460 scanning electron microscope in the Advanced Imaging Centre in Cambridge, freezing the samples preserved biological structures of the cells without desiccation. In the image the purple non-sulpur bacterium Rhodopseudomonas palustris CGA009 (red) can be seen colonizing the surface of the electrically conductive graphene coated carbon foam. Nanowires can be seen protruding from some cells and attaching either directly to the graphene surface, providing a direct bio-electrical interface, or to other cells in a circuit that extends the reach of each cell. Dominating the image is a rampaging contaminant, most likely a eukaryotic unicellular ciliate, bursting from the darkness in a frenzy of tentacle like cilia.
The first reports of electricity being generated directly from bacteria appeared over 100 years ago. Today, with improvements in imaging techniques and genetic engineering methods we are starting to fully understand why microorganisms expel electrons, how some bacteria have evolved particularly efficient ways of connecting electrically to their surroundings, and what these enabling outer membrane cytochromes and type IV conductive pili are made of.
Electrons are the currency of life, we strip them from our food to power the engine of chemiosmosis and generate proton gradients across membranes in our mitochondria that in turn drive ATP synthesis. Once they have passed through the finely tuned chemiosmotic machinery, we pass them onto oxygen in a hurry. Hold your breath and you’ll see how finely balanced that energy churning process is. In environments devoid of oxygen, many microorganisms have evolved different ways of donating electrons to a terminal electron acceptor, including directly passing them to a conductive material outside the cell and across the protective layers of the outer membrane.
We can build simple devices designed to harness electrons produced by such ‘exoelectrogenic’ bacteria. Maximum power outputs from lab scale devices reach into the hundreds of Watts per metre cubed, impressive by biological standards given these are living cells, but perhaps leaving something to be desired if competing with conventional renewable energy sources. Where microbial fuel cells (MFCs) are at an advantage is in harnessing biochemical ability of the microorganisms to use waste substrates as their food, ejecting spent electrons for our benefit. Early stage examples of MFC technology in the real world harness waste streams from breweries or farms in order to give power back to the plant. Potential applications include miniaturised devices acting as sensitive biosensors or as a means for power generation in remote areas including deep space exploration.
We are working to improve the rate of electron transfer by optimizing the electrode material. Graphene is a promising material due to its high conductivity, biocompatibility, relatively low cost, and importantly its ease of incorporation into extremely high surface area materials that maximize cell to electrode contact. The image here could represent one of the major challenges to scaling up bioenergy production, namely the instability of monocultures and vulnerability to contamination that so often scuppers industrial efforts to bring bioenergy solutions into the commercial world.
Contributors:
Toby Call, Final year PhD student in Prof. Chris Howe’s lab, Department of Biochemistry: Performed the experiment and imaged the material after Tian Carey and Dr. Felice Torrisi, PhD and PI respectively in the Graphene Centre, Department of Electrical Engineering: coated carbon foam anode with pure graphene Dr. Paolo Bombelli, Post-doc., Department of Biochemistry: design and construction of microbial fuel cells Dr. Jeremy Skepper, Advanced Imaging Centre, Anatomy Department: sample preparation and loading
This video explains the Biosensor Protocols we do with the puppies beginning the first few weeks of life. It includes a demonstration of the equilibrium exercises and olfactory stimulation. This is where we introduce them to different smells to help stimulate their sense of smell and their neurological system in general.
During this "Neonatal Period" (birth to 16 days), the puppies are deaf and blind so we concentrate our efforts on the remaining senses: touch, smell and taste.
Dr. Carmen Battaglia developed the Bio Sensor Program to be used between 3-16 days. These protocols consist of five stimulating exercises that subject the puppy to very mild neurological stress. Stimulating the neurological system in this way, and during this period of time, has benefits that are life-long. Research has shown that doing so produces a greater tolerance of stress, a faster adrenal system, greater resistance to disease, a stronger heart rate and a stronger heart beat.
The 5 stimulating protocols (exercises) are each done for a count of five:
1. Tactile stimulation: tickle between the puppies toes with a q-tip.
2. Maintain equilibrium: Hold puppy with head up
3. Maintain equilibrium: Hold puppy with head down
4. Supine position: hold puppy on back, again to challenge the neurological system.
5. Thermal stimulation: place puppy four feet down on cold washcloth.
Additionally, holding, loving, stroking, etc.each puppy also adds to the life-long benefits for a puppy. This kind of touching and caressing has been shown to lower blood pressure in adults.
Congrats to Sensei Bio on their $28M Series AA financing with the Cambrian Bio investors, including Future Ventures.
Sensei reengineers the common bacteriophage (the cool one that looks like an alien lunar lander) to expose the unique antigen signatures of tough human cancers. The viral capsid is both a cheaply-manufactured nanoparticle and a natural adjuvant for a complete, effective and safe vaccine (the phage cannot infect human cells and are inactivated). They are currently in Phase 2 clinical trials for Head and Neck Cancer and have shown broader applicability for infectious diseases.
Phage are incredible workhorses in the natural world, killing half of all bacteria on Earth every 48 hours. Their replication cycle in bacteria affords rapid and inexpensive mass manufacturing.
Company: senseibio.com
Today's news.
And from a separate U.S. gov't paper: "Phages offer many unique features useful when aiming to develop a robust inflammatory immune response targeted at viral infection or cancer. Phage‐based vaccines, like other nanotechnologies, aim to present antigen to the immune system while simultaneously activating stimulatory pathways. Phages specifically have been used in a wide array of applications ranging from biosensors to cancer immunotherapies. Reasons for this diversity include the ability to produce a large number of viral particles in a rapid and cost‐effective manner, advantageous sizes and aspect ratios, the ability to display proteins and peptides in highly‐ordered arrays, and phage safety profile in humans.
Of specific interest to vaccines and immunotherapies, phages have demonstrated an ability to activate both the innate and adaptive immune systems. The combination of both the innate and adaptive immune pathways is crucial in generating robust and long‐lasting antigen‐specific responses."
TodaysArt 2015
Electriciteitsfabriek, Den Haag
4DSOUND: Circadian opens with a performance by Lisa Park. Park works with EEG brainwave headsets as a self-monitoring tool to measure her emotional response to the world around her.
‘NUE’, meaning silkworm in Korean, transforms the physical space of 4DSOUND as Lisa moves through the system wearing a 200-metre long white dress, weaving an intricate web of passages, pockets and walls. Confined within the web, the audience interacts with Lisa as she moves in the space, through whispering, looking, and touching. Driven by Lisa’s brainwaves, a soundworld unfolds that encompasses the audience in its unravelling structure. Sonic textures melt together or fall apart based on Lisa’s emotional state, being tense or calm, focused or distracted.
Sound design: Salvador Breed and Stijn van Beek
New York-based artist Lisa Park has developed a series of performances using biosensors (brainwave and heart-rate devices) as a vehicle for manifesting her inner states. Lisa’s recent works “Eunoia” and “Eunoia II” involved using a commercial brainwave (EEG) headset as a self-monitoring tool to measure her physical and psychological states. These performances obtained real-time feedback of her emotional reactions- an investigation into a new form of expression and trans-sensory experience by visually and audibly reflecting her inner states into tangible forms.
In 2002 Hans Bruno Lund introduced the concept
"Multicomplex Management (MCM)" as a platform
for a new series of management concepts and tools,
e.g. "Expected Creative Potential (ECP)", desig-
ned as personal tools for the CEO of large, multicom-
plex organizations in addition to the traditional mana-
gement concepts and tools.
As of January 2010 the new concepts / tools "Multicomplex Management (MCM)" and "Expected Creative Potential (ECP)" were referred to on more than 800.000 websites or 40.000.000 webpages.
Literature:
Lund, Hans Bruno
Multicomplex Management (MCM)
Version 3
CD-ROM, 741 colored illustrations
Hans Bruno Lund
Skodsborg
Denmark
2009
A multicomplex organization:
Organization Structure Model used: Nordic Industrial Fund - Nordic Council of Ministers - Bio & Chemistry Division (BCD) - Division REI-activities (Research / Education / Innovation): 5 programmes: NordFood, Nordic Wood, NordPap, NordBio and NordYeast; 748 projects; 6.000 participating private and public companies, institutions, organizations and agencies in 62 countries. BCD connected 180.000 researchers, operators, engineers, technicians and company, organization and agency executives (1998). BCD was - in combination with NordTek (the organization managing the cooperation of the 23 Nordic technical universities) - the largest industrial and technological REI-network in Northern Europe. BCD was a 27.000 ECP Organization connecting 278.000 people totalling 2.7 million ECP.
Hans Bruno Lund
Contact: hansbrunolund@hotmail.com
Pictures to Multicomplex Management (MCM): 1, 2, 3, ... , 16.
Multicomplex Management (MCM) Pictures:
Picture 1 - 9 on Page 1
Picture 10 on Page 2
Picture 11 - 12 on Page 6
Picture 13 - 15 on Page 7
Picture 16 on Page 8
Multicomplex Management (MCM) is explained in Picture 2.
Expected Creative Potential (ECP) is explained in Picture 2.
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FOUR CATEGORIES OF ORGANIZATION STRUCTURES
--------------------------------------------------------------------------------------------
The above mentioned concepts and tools are part of an ongoing project “Multicomplex Management (MCM)”.
In “Multicomplex Management” we divide organizations into four categories according to their total ECP:
SIMPLE ORGANIZATIONS
Total ECP ranging from 0.1 to approx. 100.
SEMICOMPLEX ORGANIZATIONS
Total ECP ranging from approx. 100 to approx. 1.000.
COMPLEX ORGANIZATIONS
Total ECP ranging from approx. 1.000 to 10.000.
MULTICOMPLEX ORGANIZATIONS
Total ECP exceeding 10.000.
=====================================================
BCD BIO INDUSTRIAL COMPLEX - PROJECTS AND ACTIVITIES
=====================================================
BCD´s projects / activities was carried out within four INDUSTRIAL COMPLEXES:
BIO INDUSTRIAL COMPLEX
FOOD INDUSTRIAL COMPLEX
FOREST INDUSTRIAL COMPLEX and
OTHER INDUSTRIAL AREAS
As an example we list the projects / activities carried out within the
BIO INDUSTRIAL COMPLEX
Z001, Z002, Z003 ... ... ... are the BCD project numbers:
Aerobic (ZZ056/059)
Aeromonas (ZZ442)
Affald (ZZ197/369)
Affedtning (ZZ571)
Anaerobic (ZZ100)(ZZ50%)
Anaerobic Processes (ZZ099-102)
Animal Cell Cultures (Z047/421)
Antibodies (Z054/554)
Antimicrobial Activity (Z068)
AOX (Z087)
ARS1 plasmids (ZNY11)
Avgaser från stålugn (Z204)
Avloppsvatten (Z5.3/167)
Bacteria (Z... ...)
BioAutomation
Bioautomation (Z630)
Biodegradation (Z090/092/093)
Biofixation (Z094-098)
Biofunktionella färgsystem (Z403)
Biogasproduktion (Z354)
Biohydrometallurgi
Bioleaching (Z095)
Biological Degradation (Z091/439)
Biological fixation (Z094)
Biological off-gas treatment (Z481)
Biologisk gasrening (Z400)
Biologisk marksanering (Z465)
Biomass (Z249/498)
Bioorganic synthesis (Z061)
Bioorganisk syntese (Z380)
Bioorganiska synteser (Z333)
Bioprocess Engineering (Z037-048)
Bioreactor (Z037/040/041)
Bioreactors (Z045/046)
BioRecNetwork
Bioremediation (Z090)
Biosamarbete Norden Europa (Z459)
Bioseminar (Z468)
Biosensors (Z043)
Biosorbents (Z096)
Biosurfaktanter (Z453)
BIOTANNOR (Z595)
Biotechnica Hannover (Z474)
Biotechnology (Z031-102)
Bioteknik (Z329/349/426)
Bioteknisk metallutvinning (Z502)
Biotekniska metoden (Z2.2.1.4)
Biotekniske substanser (Z377)
Biotekniske substanser (Z454)
Bioteknologi (Z466/490/507)
Bioteknologi (Z355)
Bioteknologikonference (Z424)
Biotester (Z168/170)
Branching enzymes (Z051)
Car.pis. (Z069)
Cell Cultures (Z047)
Cell cycle gene cdc 21 (ZNY29)
Cell response (Z039)
Cellteknologi (Z421)
Cellular Development (Z458)
Cellulasbok Prot.Eng.(Z512)
Cellulase (Z031/060)
Cellulase enzymes (Z032)
Cellulose (Z057/141)
Cisacting mutations (ZNY30)
Civil Guard (Z409)
Cloning (Z051/055/060/NY02/)
Cloning (ZNY03/NY05)
Collagenolytic enzymes (Z066)
Concentration gradients (Z039)
Cryotin (Z065)
Data Man. Waste Water (Z450)
Databases (Z035)
Degradation (Z091/100/439)
Dehydrogenases (Z060)
Design of enzymes (Z356)
Dewatering of Sludges (Z089/438)
Djurkroppar (Z542)
DNA
DNA coding (ZNY03)
DNA gene sequence (ZNY08/NY28)
DNA polymeraser (Z431)
DNAmetoder (Z384)
DNAsymposium (Z401)
Dynabeads (Z471)
Energi (Z608)
Energi biomassa (Z249)
Energisnåla metoder (Z619)
Energy metabolism control (Z048)
Environm. Biotechnology (Z085-102)
Environm. Seafloor mapping (Z496)
Environment (Z120-122)
Enzymatic lipid modification (Z083)
Enzymatic Modification (Z082-084)
Enzymatic mofific. of lipids (Z084)
Enzymatisk affedtning (Z571)
Enzymatisk peptidsyntes (Z251)
Enzyme Catalysis (Z425)
Enzymer (Z147/571)
Enzymer fra marine råstoffer (Z297)
Enzymes (Z051/059/063)
Enzymes (Z090/356/635)
Enzymes in yeast (ZNY24)
Enzymes/Lipidsstipend (Z511)
EPI (Z592)
Eucaryotic tRNA (ZNY26)
EUREIN (Z613)
Evaluation NordBio (Z606)
Expression of genes (ZNY02)
Fab domain (ZNY16)
Fission yeast (ZNY08/NY27/NY29)
Fixation (Z094)
Foaming in bioreactors (Z044)
Fungies (Z... ...)
Förgasning torv (Z254)
Fouling av membran (Z264)
Gas (Z191/254/345/354/400/481)
Gasrensning (Z400)
Gener (ZNY02)
Genetic recombination (ZNY07)
Genteknik Utställning (Z456)
Genteknologi (Z327)
Geotermiska gaser (Z345)
Ginsing (Z258)
Glycoprotein (ZNY01/15/23)
Grampositive cocci (ZNY17)
Grundvandsrensning (Z486)
Gruvvatten (Z298)
Heavy Metals (Z094-098)
Hemaglutinin (ZNY12)
Hemicellulose (Z057)
Hepatocyter (Z169)
Hesteblod (Z336)
Heuristics (Z042)
Household waste (Z100)
Hushållsavfall (Z434)
Hydrolytic Enzymes (Z064-066)
Industrial Enzymes (Z056-058/635)
Industrial waste (Z100)
Inneklimasystem (Z416)
Järnverk (Z190)
Jäst- och växtceller (Z324)
Jästgenetik (Z276)
Jordrensning (Z486)
Klima (Z416)
Kloningsvektorer (Z310)
L. brevis (ZDetmold)(Z080)
L. plantarum (Zvalencia) (Z080)
Lac.Aci.Bac. (Z067-072/312/494)
Lac.Pen. (Z073)
Landfill leachates (Z101/102)
Leachates (Z101/102)
Leaching (Z095)
Light chain (ZNY16)
Lipases (Z031/033/505)
Lipids (Z082-084/511)
Loopfermentor (Z482)
Lysozyme (Z064)
Marin begroing (Z484)
Marine organisms (Z066)
Marine råstoffer (Z297)
Marksanering (Z465/590)
Marksanering (Z524/637)
Mass transfer (Z037)
Maturation processes (ZNY26)
Membrane filtration (Z086)
Membranes (ZNY03/18/19/25)
Methionine (ZNY06/14)
Microtox (Z170)
Mikroalger (Z373)
Mikrobiellt protein (Z193)
Mikrobielt peroxidas (Z259)
Mikrobiologi (Z172)
Mikroemulsioner (Z296)
Mikroformering (Z308)
Mikrosfärer (Z341)
Miljö (Z239/582/585/600/615)
Miljö i garverier (Z194)
Miljöanpassad betong (Z516)
Miljödeklarationer (Z528)
Miljökrav skrotsmält (Z323)
Miljømodellering (Z449)
Miljø-ORS-Paraply (Z527)
Miljøovervågning (Z423)
Miljöprofilering djuptryck (Z515)
Miljørisiko - Gensplejsning (Z371)
Miljøteknologi (Z489)
Mine drainage (Z094)
Mitochondria (ZNY04/18)
Molecular Imprinting (Z440)
Molecular modelling (Z035)
Molekylærbiologi (Z399)
Multidetektor (Z385/411)
Mutant saturation (ZNY08/NY27)
Närsaltreduktion (Z382)
NordBio (Z606)
Nordmiljö (Z196)
NordPhys (Z508)
NordPhys (Z610)
Nuclear dcm (ZNY28)
Nuclear envelope (ZNY20)
Off-gas (Z481)
Öppningssäkerhet (Z343)
PAH (Z092)
Panax (Z258)
PCD (Z092)
Peptidsyntes (Z251)
Phospholipase C (Z036)
Photosynthesis (Z473)
Physiological effects (Z038)
Physiological Engineering (Z508)
Plant Cell Biotechnology (Z049-055)
Pollutants (Z090-093)
Process Environments (Z043)
Profilin (ZNY13)
Prot. Eng. (Z031-036/302/402/NY13)
Proteases (Z058/429)
Protein Eng. Konferens (Z299)
Protein Eng. receptorer (Z367)
Protein secretion (ZNY01/15/23)
Protein software tools (Z031)
Proteinstrukturer (Z477)
Proteolytic mixtures (Z065)
Psychrophilic Org. (Z056-066)
Psykrofile organismer (Z370)
Pyrophosphatase (ZNY18)
Pyrophosphate (ZNY04/18)
RADIOBIO process (Z088)
Remediation (Z090)
Replication control (ZNY11)
RNA polymerases (ZNY10)
RNAs (ZNY10)
Saccharomyces cer. (Z001-030)
Scallop viscera (Z064)
Screening (Z082)
Seafloor (Z496)
Secretion in yeast (ZNY22)
Serine Proteases (Z429)
Skrotsmält (Z323)
Sludge (Z087/089/097/438)
Soil (Z090/092/097)
Solid Waste (Z099-102)
Soluble Starch Synthase (Z050)
Sorbents (Z096)
Stålugn (Z204)
Stålverk (Z190/343/518)
Støveksplosjoner (Z201)
Støy (Z4.1.3.2)
Styrenbemängd luft (Z419)
Termofile enzymer (Z383)
Termofile vektorer (Z430)
Thermophile bakterier (Z300)
Thermophile lipase activity (Z082)
Thermophile organismer (Z370)
Thermophiles (Z056/059)
Thermophiles (Z487)
Thermophilic microbiology (Z099)
Thermophilic Organisms (Z056-066)
Thorothermus Marinus (Z062)
Threonine biosynthesis (ZNY06)
Torv (Z254)
Transcription (ZNY26)
Transcription factors (ZNY10)
Transcription of RNAs (ZNY10)
Transcriptional control (ZNY21)
Transfer RNA (ZNY24)
Transport of proteins (ZNY20)
Troponin C (ZNY13)
Trypsin (Z034)
Tungmetaller (Z173)
Tyrosin hydroksylase (Z313)
Underglycosylated prot.A (ZNY30)
Vatten (Z167/604/608)
Vatten i järn- och stålverk (Z190)
Växtcellbioteknik (Z365/406)
Växtcellbioteknologi (Z406)
Vegetation Mapping (Z443)
Wastes (Z094/096)
Wastewater (Z085/095/098/450)
Water in Fish Industry (Z122)
Water Jet Deboning (Z125)
Xylan (Z062)
Xylanases (Z056/060/062)
Xylose Utilixation (Z447)
Yeast (Z001-030)
Yeast ADE4 gene (ZNY11)
Zinkholdig støv (Z518)
Literature
Lund, Hans Bruno
Multicomplex Management (MCM)
Version 3
CD-ROM, 741 colored illustrations
Dr. Hans Bruno Lund, Management Consultant
Skodsborg
Denmark
2009
Not available in libraries
Multicomplex Management (MCM) Expected Creative Potential (ECP) Picture 1 - Organization Structure
Organization Structure Model used: Nordic Industrial Fund - Nordic Council of Ministers – Bio & Chemistry Division (BCD) - Division REI-activities (Research / Education / Innovation): 5 programmes: NordFood, Nordic Wood, NordPap, NordBio and NordYeast; 748 projects; 6.000 participating private and public companies, institutions, organizations and agencies in 62 countries. BCD connected 180.000 researchers, operators, engineers, technicians and company, organization and agency executives (1998). BCD was - in combination with NordTek (the organization managing the cooperation of the 23 Nordic technical universities) - the largest industrial and technological REI-network in Northern Europe. BCD was a 27.000 ECP Organization connecting 275.000 people totalling 2.8 million ECP. Photo on Picture 1: Hans Bruno Lund visiting the governor of Oulu province, Finland Dr. Eino Siuruainen during a NordTek seminar.
Multicomplex Management (MCM) is explained in Picture 2, 04.
Expected Creative Potential (ECP) is explained in Picture 2.
Pictures to Multicomplex Management (MCM): 1, 2, 3, 4, 5, 6, 7, 8,
9, 10, 11 and 12.
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A MULTICOMPLEX ORGANIZATION STRUCTURE - ORGANIZATION
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NORDIC INDUSTRIAL FUND (NIF)
NORDIC COUNCIL OF MINISTERS (NCM)
BIO & CHEMISTRY DIVISION (BCD)
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CONTENTS
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1 BIO & CHEMISTRY DIVISION (BCD)
1.1 NIF HISTORY
1.2 BCD BUSINESS IDEA
1.3 BCD OPERATION AREA
1.4 BCD OPERATION AREA INHABITANTS
1.5 BCD PARTNER-COUNTRIES AND AUTONOMOUS AREAS
1.6 BCD GEOGRAPHIC OPERATION REGIONS
1.7 BCD PARTNERS
1.8 BCD ACTIVITIES
1.9 BCD ORGANIZATION STRUCTURE
1.9.1 - MANAGEMENT
1.9.2 - BIO INDUSTRIAL COMPLEX (BIO)
1.9.3 - FOOD INDUSTRIAL COMPLEX (FOO)
1.9.4 - FOREST INDUSTRIAL COMPLEX (FOR)
1.9.5 - OTHER INDUSTRIAL AREAS (OIA)
1.9.6 BCD – HISTORY AND ACHIEVEMENTS – A RESUME
2 MULTICOMPLEX MANAGEMENT (MCM) LITERATURE
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1.1 NIF HISTORY
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NIF HISTORY
NIF was established 1973 (the Helsinki Treaty). In 1987 the organization expanded by taking over the activities of NordForsk (a Nordic government agency for basic research). In the new century the activities of NIF (and BCD) were split up between two new-established organizations: A new NordForsk (basic research) and Nordic Innovation Centre (NICe)(applied research and innovation).
BCD (one of NIF's two divisions) was operational from 1991 to 1999.
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1.2 BCD BUSINESS IDEA
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BCD BUSINESS IDEA
Initialization, expansion and utilization of Nordic and Nordic / international cooperation networks between relevant partners from the private and the public sectors to the benefit of the Nordic countries´ competitiveness and the wealth and health of their inhabitants and based on internordic / international cooperation projects as the primary tool and improved and new concepts, methods, technologies and products as valuable spinoffs.
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1.3 BCD OPERATION AREA
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BCD OPERATION AREA
Approx. 22 million square km
Land: Approx. 6 million square km
Oceans and seas: Approx. 16 million square km
The water quality of the oceans and seas surrounding
the Nordic countries is of extreme importance to the
Nordic economies and the inhabitants health and qua-
lity of life. To protect and improve water quality at land as
well as at sea was therefore a substantial goal in almost
all BCD projects.
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1.4 BCD OPERATION AREA INHABITANTS
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BCD OPERATION AREA INHABITANTS
Approx. 45 million
Nordic Countries: Approx. 24 million
Baltic Countries: Approx. 7 million
North West Russia: Approx. 14 million
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1.5 BCD PARTNER-COUNTRIES AND AUTONOMOUS AREAS
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BCD PARTNER-COUNTRIES AND AUTONOMOUS AREAS
Aland Islands
Denmark
Estonia
Faroe Islands
Finland
Greenland
Iceland
Latvia
Lithuania
North West Russia
Norway
Sweden
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1.6 BCD GEOGRAPHIC OPERATION REGIONS
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A BCD project must have participants - private and public partners - from at least two - better three or four - Nordic countries. Most geographic regions has their specific profile in regard to industry, centers of excellence, inhabitants, culture, nature, environment etc. To identify the optimal combination of partners for a project to be initiated it can sometimes be useful to identify and select partners from related geographic regions in relation to the above mentioned parameters. BCD has 67 geographic operation regions:
Denmark: 11
Finland: 9
Iceland: 9
Norway: 10
Sweden: 8
Estonia: 3
Latvia: 3
Lithuania: 3
North West Russia: 11
The geographical allocation of BCD´s approx.
10.000 Project Participant Representatives and
other superior officers in the Nordic Countries:
(Project Participant Representatives and
other superior officers in other countries approx.
1.000).
DEN-00 Denmark 1.972
DEN-01 København 220
DEN-02 Lyngby 730
DEN-03 Nordsjælland 91
DEN-04 Øvrige Sjælland 123
DEN-05 Fyn 82
DEN-06 Kolding 132
DEN-07 Herning 137
DEN-08 Århus 228
DEN-09 Aalborg 163
DEN-10 Færøerne 47
DEN-11 Grønland 19
FIN-00 Finland 2.089
FIN-01 Helsinki & Espoo 1.274
FIN-02 Turku ( Åbo) 189
FIN-03 Tampere 194
FIN-04 Jyväskylä 57
FIN-05 Lappeenranta 105
FIN-06 Vaasa 108
FIN-07 Kuopio 35
FIN-08 Joensuu 31
FIN-09 Oulu / Kemi 96
ICE-00 Iceland 513
ICE-01 Reykjavik 396
ICE-02 Keflavik 42
ICE-03 Akranes 13
ICE-04 Isafjördur 11
ICE-05 Saudarkrökur 8
ICE-06 Akureyri 15
ICE-07 Egilsstadir 20
ICE-08 Selfoss 5
ICE-09 Vestmannaeyjar 3
NOR-00 2.173
NOR-01 Oslo 646
NOR-02 Ås 301
NOR-03 Moelv 231
NOR-04 Porsgrunn 217
NOR-05 Stavanger 167
NOR-06 Bergen 97
NOR-07 Ålesund 90
NOR-08 Trondheim 329
NOR-09 Bodø 39
NOR-10 Tromsø 56
SWE-00 3.202
SWE-01 Stockholm 868
SWE-02 Lund / Malmö 427
SWE-03 Halmstad 178
SWE-04 Göteborg 402
SWE-05 Borås 329
SWE-06 Norrköping 241
SWE-07 Uppsala 304
SWE-08 Sundsvall 213
SWE-09 Luleå 240
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1.7 BCD PARTNERS
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BCD PARTNERS
Private and public companies
Private and public organizations
Universities
Technological institutes
Governments
Government agencies
Other relevant partners
Partners: approx. 6.000 in 62 countries
Private area partners: approx. 4.800
Public area partners: approx. 1.200
See:
Flickr, Hans Bruno Lund´s photostream:
"Multicomplex Management (MCM) Picture 3
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1.8 BCD ACTIVITIES
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BCD ACTIVITIES
Research
Education
Innovation
Visits
Exchanges
Meetings
Seminars
Workshops
Cources
Reports
Articles
Newsletters
Presentations
Posters
WEB-Activities
Improved Concepts
New Concepts
Improved Methods
New Methods
Improved Technologies
New Technologies
Improved Products
New Products
Patents
Evaluation of Results
Dissemination of Results
Improved Nordic Networks
New Nordic Networks
Improved Nordic/International Networks
New Nordic/International Networks
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1.9 BCD ORGANIZATION STRUCTURE
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BCD ORGANIZATION STRUCTURE
Upper right in the picture
REI = Research-Education-Innovation
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1.9.1 MANAGEMENT
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MANAGEMENT
Management (sand-colored areas/elements)
Head of Division: Hans Bruno Lund (DEN)
Division Director BIO: Marianne Damhaug (NOR) until 1992
Division Director FOOD/OIA: Maija Uusisuo (FIN)
Division Director BIO/FOREST/OIA: Juhani Kuusilehto (FIN)
Deputy Division Director FOREST: Per Brenøe (DEN)
Associate Division Director OIA: Peter Göranson (SWE)
Associate Division Director OIA: Svein Østevik (NOR)
Associate Division Director OIA: Snæbjörn Kristjansson (ICE)
Other Division Administration Staff: 11 officers
Division Advisers: 16
DIVISION REI Areas: 92
DIVISION REI Subareas: 1.200
DIVISION Programmes: 5
DIVISION Part Programmes: 20
DIVISION REI Projects: 748
DIVISION REI Part Projects: approx. 3.000
DIVISION Senior Officers: 370
DIVISION Project Managers: 649
DIVISION Part Project Managers: approx. 2.500
DIVISION Other Officers: approx. 28.000
DIVISION Network Participants (People): approx. 278.000 (incl. NordTek)
DIVISION Network ECP: approx. 2.800.000 (incl. NordTek)
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1.9.2 BIO INDUSTRIAL COMPLEX (BIO)
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BIO INDUSTRIAL COMPLEX (BIO)
(blue-colored areas/elements)
Marianne Damhaug (NOR)
Juhani Kuusilehto (FIN)
REI = Research-Education-Innovation
BIO REI Areas: 22
BIO REI Subareas: 340
BIO Programmes: 2 - NORDYEAST & NORDBIO
BIO Part Programmes: 6
BIO REI Projects: 188
BIO REI Part Projects: approx. 750
BIO Senior Officers: 122
BIO Project Managers: 213
BIO Part Project Managers: approx. 640
BIO Other Officers: approx. 7.000
BIO Network Participants (People): approx. 45.000
BIO Network ECP: approx. 535.000
BIO REI Areas:
02 Antibodies and Antigens
04 BioEnergy
05 Biomimetic Materials
06 Bioprocess Engineering
07 BioScience and BioTechnology
20 Environmental BioTechnology
21 Environmental Technology
24 Food BioTechnology
30 Genes and GeneTechnology
35 Industrial Enzymes
37 Marine Biology and BioTechnology
40 BioHydroMetallurgi
45 NeuroBiology and InformationsTransfer
47 Biological OffGas Treatment
50 Physiological Engineering
Project example with Part Projects:
Z508 Physiological Engineering:
Part Projects:
Z508.1 Energy and redox balances during aerobic growth
Z508.2 Regulation of energy flux at anaerobic conditions
Z508.3 Xylose metabolizing Saccharomyces cerevisiae
Z508.4 Physiological responses of Sac.Cer. to SubConVar
Z508.5 Morphological charact. of Penicillium chrysogenum
Z508.6 Morphology and amylase production in Aspergillus oryzae
The Research Team:
Albers, Eva
Alexander, N J
Anderlund, Mikael
Bao, Xing
Carlsen, Morten
Christensen, Lars H
Deleuran, Jan
Edelmann, Kari
Ehlde, Magnus
Einarsson, Sigbjørn
Eliasson, Anna
Ellingsen, Trond
Enari, Tor-Magnus
Enfors, Sven-Olof
Flenø, Bent
Franzén, Carl J
George, Stefan
Gram, Jens
Granstrøm, Tom
Gustafsson, Lena
Hahn-Hägerdal, Bärbel
Haldrup, Anna
Hallborn, J
Hansen, Tronn
Hjortkjær, Poul
Holmgreb, K
Jeppsson, Helena
Johansen, Kenneth
Johansson, Björn
Jørgensen, Birthe R
Karsbøl, Birgitte
Klein, Christopher
Korhola, Matti
Krabben, Preben
Kristjansson, Jakob
Larsen, Susanne Slot
Larsson, Christer
Larsson, Gen
Lidén, Gunnar
Londonsborough, John
Meinander, Nina
Michelsen, M L
Mikkelsen, Jørn D
Mølgaard, Henrik
Mørkeberg, R
Nielsen, Jens (Project Manager)
Niklasson, Claes
Nilsson, Annika
Nybergh, Paula
Ojamo, Heikki
Olkku, Juhani
Olsson, Lisbeth
Overballe-Petersen, C
Pakula, Tiina
Palmqvist, Eva
Parkkinen, Elke
Peltola, Petri
Penttilä, Merja
Pettersson, Lennart
Pham, Hop
Prior, B A
Pronk, Jack
Påhlman, Inga-Lil
Rasmussen, Preben
Reuss, Mathias
Ruohonen, Laura
Rønnow, Birgitte
Salminen, Antti
Salonen, Laura
Santerre, Anne
Schmidt, Karsetn
Schulze, Ulrik
Skoog, K
Skov, Allan
Smits, Hans Peter
Spohr, Anders
Suhr-Jessen, Trine
Søderblom, Tore
Taherzadeh, Mohammad
Thevelein, J
Thomas, Colin
Toma, Simona
Tufvesson, Göran
Valadi, Hadi
van Dam, Karel
van Dijken, J P
Villadsen, John
Visser, Jaap
Walfridsson, Mats
Winell, Anna
Winge, Michael
Zacchi, Guido
Zimmerman, Friedrich
Aarts, Robert
Participants:
Alko Oy
Amsterdam University
Birmingham University
Bryggerilaboratorium Oy AB
Chalmers Technical University
Cheminova A/S
Danisco Biotechnology A/S
Delft University of Technology
Dumex A/S
Göteborg University
IceTec
Kungliga Tekniska Högskolan
Lahden Poltimo Oy
Novo Nordisk A/S
Pripps AB
Primalco Oy
SINTEF
Skåne Brännerier AB
Technical University of Denmark
Technische Universität Darmstadt
Universität Stuttgart
VTT
Waageningen University
51 PlantCell Biology and BioTechnology
57 Protein Engineering
Project examples (without listing Part Projects):
Z037 Fluid dynamics and mass transfer in bioreactors (BR)
Z038 Physiological effects of oscillating fermentation parameters
Z039 Kinetics of cell responce to local conc. gradients in BR
Z040 Multi-dimensional modelling of flow-processes in BR
Z041 On-line HPLC control of mammalian cell bioreactors
Z042 Bioprocess monotoring system based on ESC / HEU
Z043 Implementation of biosensors in process environments
Z044 Mechanisms of foaming in bioreactors
Z045 Productivity of bioreactors (I)
Z046 Productivity of bioreactors (II)
63 Recycling
73 Thermophilic and Psychrophilic Organisms
74 Waste and WasteWater Treatment
75 Yeast and YeastTechnology
84 LifeCycle Assessment (LCA)
NORDYEAST
Project examples (without listing Part Projects):
Z001 Protein secretion and glycoprotein production in Sac.Cer.
Z002 Molecular cloning and expression of genes by key enzymes
Z003 Cloning and studies of DNA coding for g-3-p-d of Sac.Cer.
Z004 Membrane bound IPP in mitochondria from Sac.Cer.
Z005 Cloning of DNA alkylation genes from yeast
Z006 Regulation of methionine-threonine biosynthesis
Z007 Studies on genetic recombination in Sac.Cer.
Z008 MS of the DNA gene sequence in Saccharomyces Cerevisiae
Z009 Exp. and sec. in yeast of human parathyroid hormone
Z010 RNA polymerases and TF in transcription of RNAs
NORDBIO
NORDBIO Part Programmes:
NB-01 Protein Engineering
NB-02 Bioprocess Engineering
NB-03 Plant Cell Biotechnology
NB-04 Thermophiles and Psychrophiles
NB-05 Food Biotechnology
NB-06 Environmental Biotechnology
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1.9.3 FOOD INDUSTRIAL COMPLEX (FOO)
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FOOD INDUSTRIAL COMPLEX (FOO)
(orange-colored areas/elements)
Maija Uusisuo (FIN)
REI = Research-Education-Innovation
FOO REI Areas: 10
FOO REI Subareas: 180
FOO Programmes: 1 - NORDFOOD
FOO Part Programmes: 4
FOO REI Projects: 125
FOO REI Part Projects: approx. 500
FOO Senior Officers: 37
FOO Project Managers: 107
FOO Part Project Managers: approx. 425
FOO Other Officers: approx. 5.000
FOO Network Participants (People): approx. 30.000
FOO Network ECP: approx. 360.000
FOO REI Areas:
03 Aquaculture
11 Cereals
22 Fishery and Fish
Project examples (without listing Part Projects):
Z217 Nordisk Blåvilling
Z290 Frysfartyg
Z339 Atlantic Salmon
Z346 Hippoglossus
Z437 Landbaserte Anlegg
Z461 Monotoring and PC in Aquaculture
Z483 Hälleflundra, Torsk och Havskat
Z563 CIMFISK - IT in Fish Fillet Factories
Z570 BENEFISH - New Technologies in the Nordic Fishindustries
Z594 Havmiljøets påvirkning af fisks reproduktionsevne
23 Fish Diseases
25 Food Hygiene
26 Food Packaging and Transportation
27 Food Processing
Project examples (without listing Part Projects):
Z120 Cleaner production
Z121 Environmental beer production
Z122 Water in fish industry
Z123 Nordic shellfish
Z124 Value from heads
Z125 Water jet deboning
Z126 Aseptic safety
Z127 Probiotic foods
Z128 Rye technology and its influence on health
Z129 Structures in food fat
28 Food Quality
29 Food Technology
Project examples (without listing Part Projects):
Z103 Fish - Packaging and Transportation
Z104 Aroma Transfer in PET
Z105 Shelf Life Prediction
Z107 Salmon Quality
Z108 Microbial Antagonists
Z109 Managing the Meat Tend Process
Z110 Sensoric Calibration
Z111 Fluorescence Screening
Z112 Quality of Emulsions
Z113 Lean Logistics
Let us as an example take a closer look at
Project Z115 On Line Measuring Control
Project Participants
Denmark
Bioteknologisk Institut
Paaske Jensen
Danisco Sugar Development
Ole Hansen
Danmarks Fiskeriundersøgelser
Erling Larsen
Fødevaregruppen
Finn Holm
KVL
Lars Munk
Lactosan A/S
Jørgen Schmidt
Meincke A/S
Peter Clausen
Slagteriernes Forskningsinstitut
J Rud Andersen
Foss Electric A/S
Torben Lapp
Reciprotor Engineering A/S
Per Andersen
Q-Interline
Anders Larsen
Steins Laboratorium A/S
Jakob Korsgaard
Finland
Ingman Foods Oy AB
Hans Ingman
Process Flow Ltd Oy
Björn Jernström
Saarioinen Oy
Mirja Rautakoski
Oy Snellman AB
Rolf Snellman
Sucros Oy
Juha Oravainen
Hutiia Research Centre
Jonas Slotte
VTT Bio- & Livsmedelsteknik
Arvo Kinnunen
Software Point Oy
Andrea Holmberg
Iceland
Fiskeriindustriens Forskningsinstitut
Helga Eyjófsdóttir
Marel HF
Sigurpáll Jonsson
Milk Distribution Centre
Einar Matthiasson
IceTec
Hannes Hafsteinsson
Univesity of Iceland
Kristberg Kristbergsson
Landbruges Forskningsinstitut
Gudjón Torkelsson
Industriforbundet
Ragneidur Hédinsdóttir
Norwegen
Mills DA
Narinder Singh
Maarud A/S
Terje Drøyvold
A/S Margarinfabrik Norge
Aziz Fooladi
Matforsk
Jens Petter Wold
Nerliens Kemisk-Tekniske A/S
Vigdis Rustad
Norges Lantbrukshøgskole
Ingolf F Nes
Norsk Kjøtt
Ole-Johan Røtterud
Tine Norske Meierier BA
Svein Kloster
T Skretting A/S
Astrid Staumbotn
Stabburet A/S
Anita Bakker
SINTEF Kjemi Havbruk
Marit Aursand
Sweden
Abba Seafood AB
Göran Sjögren
Procordia Food AB
Ene Pilman-Willers
Lunds Universitet Kemicentrum
Ingegerd Sjöholm
Kraft Freia Marabou AB
Thomas Wassholm
Oleinitec AB
Marlene Jegeborn
Arla F&U
Clas Johan Dahlsten
Pentronic AB
Roland Gullqvist
Pripps AB
Klas Johansson
Pååls Bröd AB
Bo Folkesson
Radians Innova AB
Bengt Kleman
SIK
Christana Skjöldebrand (Project Manager)
Sveriges Lantbruksuniversitet
Ingemar Hansson
STFi
Anders Pettersson
Charkdelikatesser AB
Anna-Karin Norén
Svenska Nestlé AB
Anita Johansson
Foss Sverige AB
Ingrid Mild / Niklas Persson
Tekniska Högskolan Linköping
Alexander Lauber
Tetra Pack Food AB
Christer Lanzingh
Wasabröd AB
Bengt Carlson
Köttforskningsinstituttet
Magnus Wahlgren
Nestlé R&D AB
Jennifer Cloke
Bergman & Beving Process AB
Per Henriksson
Teltec Electronic AB
Philip Dahl
Candelia AB
Urban Eriksson
Sensor Control AB
Björn Zetterberg
Danfoss AB
Anders Leidermark
Nordic Sensor Technologies AB
Andreas Bunge
Electrona-Sievert AB
Alf Mikkelä
Mettler-Toledo AB
Peter Tinér
Korsnäs AB
Jan Jynnskog
Sigma Teknik AB
Stellan Lundberg
Foss Tecator AB
Karin Thente
The participating industrial companies
had on a global basis:
Revenue: 100 billion €
Employees: 500.000
53 Polysaccharides
NORDFOOD
NORDFOOD Part Programmes:
NF-01 Food Packaging and Transportation
NF-02 Food Quality
NF-03 Food Hygien
NF-04 Food Processing
One out of several significant milestones achieved as a result of NORDFOOD was the set up of the European REI cooperation SAFEFOODERA – Safer food for 446 million people. Headed by two of BCDs former executive officers Mr. Ola Eide from Norway and Mr. Oddur Már Gunnarsson from Iceland the National Food Authorities of 18 European countries now works together to improve food quality and food hygiene. The 18 countries are: Basque Country, Belgium, Cyprus, Denmark, Finland, France, Germany, Hungary, Iceland, Italy, Netherlands, Norway, Poland, Portugal, Slovenia, Sweden, Turkey and United Kingdom.
Over the years hundreds of Nordic Industrial Fund REI projects or initiatives has resulted in expanded efforts with new European partners under the auspices of the EU research programmes or EUREKA.
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1.9.4 FOREST INDUSTRIAL COMPLEX (FOR)
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FOREST INDUSTRIAL COMPLEX (FOR)
(green-colored areas/elements)
Juhani Kuusilehto (FIN)
Per Brenøe (DEN)
REI = Research-Education-Innovation
FOR REI Areas: 13
FOR REI Subareas: 220
FOR Programmes: 2 - NORDPAP & NORDIC WOOD
FOR Part Programmes: 10
FOR REI Projects: 170
FOR REI Part Projects: approx. 680
FOR Senior Officers: 78
FOR Project Managers: 103
FOR Part Project Managers: approx. 570
FOR Other Officers: approx. 6.000
FOR Network Participants (People): approx. 40.000
FOO Network ECP: approx. 475.000
FOR REI Areas:
49 Paper as Carrier of Informations
54 Printing Technology
58 Pulp and Paper Bleaching
59 Pulp and Paper Fibers
Project examples (without listing Part Projects):
Z133 Pot. titrering och polyelektrolyttitrering
Z134 Ytsammensättning, ytenergi och syra-base-egenskaper
Z135 Anvendelse av dielektrisk spektroskopi
Z136 Karakterisering av fiber med biotekniska metoden
Z137 Elektromikroskopi
Z138 Konfokal mikroskopi og billedanalyse
Z139 Porstorlek v.h.a. omvendt storlek kromatografi
Z140 Porstorlek v.h.a. NMR-metodik
Z141 Cellulosens reaktivitet og krystallinitet
Z142 TB-method för mättning av specific yta
60 Pulp and Paper EU-Standardization
61 Pulp and Paper Technology
76 Environmental Properties of Wood
77 Properties and Applications of Nordic Wood
78 Nordic Wood as a Construction Material
79 Marketing of Nordic Wood
80 Nordic Wood and the Asian Markets
81 Wood Production
83 Wood Technology
Project examples (without listing Part Projects):
Z177 Trä och miljö
Z527 Skog-Trä-Miljö
Z528 Miljödeklaration
Z529 Trä-F&U-Miljöinformation
Z530 Spånplader i møbelindustrien
Z531 Furu Kjernved
Z178 Datorprogram Limträ
Z179 Brandsäkra trähus
Z532 Våtlimede byggkomponenter
Z181 Styrkesortering ger mervärde
NORDPAP
NORDPAP Part Programmes:
NP-01 Pulp and Paper Fibers
NP-02 Pulp and Paper Bleaching
NP-03 Paper as Carrier of Informations
NP-04 Pulp and Paper EU-Standardization
NORDIC WOOD
NORDIC WOOD Part Programmes:
NW-01 Environmental Properties of Wood
NW-02 Properties and Applications of Nordic Wood
NW-03 Nordic Wood as a Construction Material
NW-04 Marketing of Nordic Wood
NW-05 Nordic Wood and the Asian Markets
NW-06 Wood Production
We often think that cross-border REI activities, regional or global, are the playground for large enterprises as it is often the case. BCD had more than 70% of the largest Nordic enterprises as active project participants.
Very encouraging was the fact that many SMB´s found their way to Nordic REI cooperation.
In NORDIC WOOD as an example 21 carpenter guilds from the following small or mediumzised Danish towns participated in the research: ESBJERG, FREDERICIA, FREDERIKSHAVN, HADERSLEV, HERNING, HILLERØD, HJØRRING, HOLSTEBRO, KOLDING, MARSTAL, NYKØBING FALSTER, ODENSE, RANDERS, ROSKILDE, SILKEBORG, SKIVE, SVENDBORG, SØNDERBORG, ÅBENRÅ, AALBORG / NØRRESUNDBY and ÅRHUS cooperated with large companies such as ABB, AKZO NOBEL, ASSI-DOMÄN, COWI, ENZO-GUTZEIT and IKEA.
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1.9.5 OTHER INDUSTRIAL AREAS (OIA)
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OTHER INDUSTRIAL AREAS (OIA)
(red- and brown-colored areas/elements)
Juhani Kuusilehto (FIN)
Peter Göranson (SWE)
Svein Østevik (NOR)
Maija Uusisuo (FIN)
Snæbjörn Kristjansson (ICE)
REI = Research-Education-Innovation
OIA REI Areas: 48
OIA REI Subareas: 460
OIA Programmes: 0
OIA Part Programmes: 0
OIA REI Projects: 265
OIA REI Part Projects: approx. 1.060
OIA Senior Officers: 106
OIA Project Managers: 226
OIA Part Project Managers: approx. 900
OIA Other Officers: approx. 10.000
OIA Network Participants (People): approx. 64.000
OIA Network ECP: approx. 760.000
OIA REI Areas:
01 Allergy Research
09 Cancer Research
10 Catalysis and Catalysts
12 Chemical Fibers and Polymers
13 Chemistry and Chemical Technology
Project examples (without listing Part Projects):
Z194 Miljö i garverier
Z198 Olieseparation
Z200 Chromgarvningsmetode
Z207 Korrosionsskyddfärg
Z595 Biotannor
Z497 Adsorption av polymerer
Z578 Lut- och syraprocess
Z492 Processregulering
Z491 Styrd denitrifikation
Z475 Crude oil emulsions
14 Colours and Paints
15 Concrete Technology
16 Corrosion
32 Hormones
33 Immunology and ImmunoTechnology
34 Implantations and ImplantationTechnology
39 Medicine-Pharma-Health
41 Mineralogy and Minerals
48 Offshore Technology
52 Plasma and PlasmaTechnology
69 Supercritical Technologies
70 Surfaces and SurfaceTechnology
71 Tanning and TanningTechnology
08 Business Development
17 Culture and Technology
22 Expert Systems
31 Global REI-Relations
36 Information Technology
38 Measuring Technology
42 Molecule Structures and Modelling
43 NanoTechnology
55 ProcessTechnology
56 Product Development
62 Product Quality & Quality Management
64 Research Management
66 Sensors and SensorTechnology
67 Simulation and Modelling
68 SMBs
72 Technolgy Management
82 Systems Research and Development
44 REI Networks
18 Doctoral Education
19 Engineering Education
46 Technical Universities
Project examples (without listing Part Projects):
NTU = Nordic Technical Universities
Z476 NTU Students Seminar (NTUSS)
Z540 Nordic Industrial Researcher Education Programme (NIREP)
Z551 NTU Students Exchange Programme (NTUSEP)
Z555 NTU PhD Students Exchange Programme (NTUPSEP)
Z584 NTU Presidents Meeting & Industrial Seminar Norway 1993
Z513 NTU Presidents Meeting & Industrial Seminar Iceland 1994
Z517 NTU Presidents Meeting & Industrial Seminar Denmark 1995
Z520 NTU Presidents Meeting & Industrial Seminar Finland 1996
Z633 NTU Presidents Meeting & Industrial Seminar Sweden 1997
Z722 NTU Presidents Meeting & Industrial Seminar Norway 1998
65 Technology Forecasting
85 Regional Development
86 Materials Technology - Aluminium
87 Materials Technology - Ceramics
88 Materials Technology - Composites
89 Materials Technology - Simulation
90 Materials Technology - Surfaces
91 Materials Technology - Steel
92 General Materials Technology
Project examples (without listing Part Projects):
Z275 Oxidceramics
Z282 Zeolites
Z398 Eurodyn - High Technology Gas Turbine
Z591 Material - POM - Polyacetal
Z648 Composites and Sandwich Structures in Ship Construction
Z678 SOL Materials
Z683 Ferroalloys in the Nordic Countries
Z684 Tribology (Friction - Lubrication - Wear)
Z688 Fenite Element Analysis (FEA) in the Automotive Industries
Z713 Nordic Aluminium Cluster (NAC)
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1.9.6 BCD – HISTORY AND ACHIEVEMENTS – A RESUME
--------------------------------------------------------------------------------------------
More than 25 million people in the Nordic countries – and many more around the World – are each day and many times using or consuming products which were created or improved in one of the Nordic Industrial Fund´s Bio & Chemistry Division´s more than 50.000 research-, education- and innovation activities. More than 500.000 engineers, technicians, workers, university teachers, students, researchers, managers and officials from the 5 Nordic countries have – from a start in 1973 – gained new knowledge in their combined efforts to improve Nordic competitiveness, the Nordic environment and the health and quality of life of the countries populations and in many cases in crossborder cooperation with industrial and institutional partners from 57 other countries. --------------------------------------------------------------------------------------------
2 MULTICOMPLEX MANAGEMENT (MCM) - LITERATURE
--------------------------------------------------------------------------------------------
Lund, Hans Bruno
Multicomplex Management (MCM)
CD-ROM, 678 colored illustrations
Dr. Hans Bruno Lund, Management Consultant
Skodsborg
Denmark
2009
CMOS integrated chips sitting on a 12-inch wafer where the chips were fabricated before the packaging. The microchip here ,which was designed for the electrochemical biosensor readout, is so small but it contains thousands of transistors. The number of transistors in the state-of-the-art CPUs is up to several billion. The rapid development of IC technology has revolutionised the electronics industry for the past few decades, which is acclaimed as ’silicon miracle’.
TodaysArt 2015
Electriciteitsfabriek, Den Haag
4DSOUND: Circadian opens with a performance by Lisa Park. Park works with EEG brainwave headsets as a self-monitoring tool to measure her emotional response to the world around her.
‘NUE’, meaning silkworm in Korean, transforms the physical space of 4DSOUND as Lisa moves through the system wearing a 200-metre long white dress, weaving an intricate web of passages, pockets and walls. Confined within the web, the audience interacts with Lisa as she moves in the space, through whispering, looking, and touching. Driven by Lisa’s brainwaves, a soundworld unfolds that encompasses the audience in its unravelling structure. Sonic textures melt together or fall apart based on Lisa’s emotional state, being tense or calm, focused or distracted.
Sound design: Salvador Breed and Stijn van Beek
New York-based artist Lisa Park has developed a series of performances using biosensors (brainwave and heart-rate devices) as a vehicle for manifesting her inner states. Lisa’s recent works “Eunoia” and “Eunoia II” involved using a commercial brainwave (EEG) headset as a self-monitoring tool to measure her physical and psychological states. These performances obtained real-time feedback of her emotional reactions- an investigation into a new form of expression and trans-sensory experience by visually and audibly reflecting her inner states into tangible forms.
British Petroleum is working with Synthetic Genomics to convert coal directly to methane (the cleanest burning of the fossil fuels) without ever digging the coal out of the ground.
A population of microbes can strip electrons from the coal and do the bioconversion deep underground, without any sunlight, air or thermal flux.
Here in the La Jolla labs, you see various columns of coal and microbial consortia under testing for their conversion capabilities. The natural gas bubbles into the plastic bags.
To gather the microbial consortia, they drilled into a pocket of water trapped in a coal seam. It was rich with life, with 200 species living off each other and happily eating coal a mile underground, with no light or contact with the world. From carbon dating, they concluded that this genetic time capsule has evolved in isolation for 135 million years.
P.S. EDGE has recently put 6 hours of HD video on synthetic biology online. The last two lectures seem the most forward looking. Topics: “What is life, origins of life, in vitro synthetic life, mirror-life, metabolic engineering for hydrocarbons & pharmaceuticals, computational tools, electronic-biological interfaces, nanotech-molecular-manufacturing, biosensors, accelerated lab evolution, engineered personal stem cells, multi-virus-resistant cells, humanized-mice, bringing back extinct species, safety/security policy.”
Zhang Xiangdong, Chairman and President, Organic and Beyond, People's Republic of China, Regina Cervera, Projects Coordinator, Future of Earth Lab, C Minds, Mexico, Carrol Plummer, Co-Founder and Chief Executive Officer, Vivent Biosensor, Switzerland speaking in the Exponential Agriculturesession at the at the Annual Meeting of the New Champions 2023 in Tianjin, People's Republic of China, 28 June 2023. Tianjin Meijiang Convention Center - Hub A Room. Copyright: World Economic Forum/Greg Beadle
Vanjie Alocilja, AgBioResearch scientist and professor of Biosystems and Agricultural Engineering, is working on biosensors that can detect dangerous pathogens.
Alocilja works at the nano level using extremely tiny nanoparticles, nanotubes, nanomagnets, and nanopores to build her sensors.
George Church is professor of genetics at Harvard medical school and also heads the Lipper Center for Computational Genetics, MIT-Harvard/ Department of Energy Genomes to Life Center, and the National Institutes of Health (NIH) Center for Excellence in Genomic Science. Church’s Harvard lab is a member of the genome-sequencing technology development project of the NIH-National Human Genome Research Institute.
He’s also the inspiration behind a number of companies including Genome Therapeutics (since 1989), the sequencing part of which merged with Agencourt Biosciences in 2003, arguably the largest current-generation gene-sequencing company (recently acquired by Beckman Coulter for more than $100 million (depending on earn-outs) and a 2005 spin-off called Agencourt Personal Genomics. He has also contributed ideas to Codon Devices, a “synthetic biology” company that constructs large-scale integrated genetic circuits for anything from pharmaceutical manufacturing to biosensors and smart materials; Codon has funding from Kleiner Perkins (including Vinod Khosla personally) as well as Flagship and Alloy.
Most recently, Church led Harvard’s research project to design a faster and therefore cheaper way to sequence genomes, reported August 4 in the journal Science.. This followed by four days an announcement by company 454 Life Sciences, based in Branford, CT, of a similar achievement.
**Three magnitudes down, two more to go **
Both groups have automated and miniaturized the process, which makes it much cheaper, faster and more accurate. The very first human genome sequence took 13 years and cost $2.7 billion (though the second was much quicker!). The current cost – if someone wanted it – would be about $20 million, or the price of Dennis Tito’s trip into space. Church’s and 454’s separate but similar approaches drop the cost to about $2 million. Their ultimate goal is about $1000, though Church points out that even $20,000 would be compatible with our current medical system: not for everyone, but akin to a complex operation.
But 454 sells its equipment for $500,000, whereas Church’s group is aiming for a more “community-oriented” effort. Church expects his approach to be used by 454’s three major competitors (including Agencourt) and, indeed, labs all around the world. In fact, he says “You can use equipment that’s currently available in most labs, for about $150,000, starting with a digital camera and a microscope; everyone has those. “The science paper includes step-by-step instructions, although they may not be for “anybody”: The final words of the paper are: "We collected ~786 gigabits of image data from which we gleaned only ~60 megabits of sequence. This sparsity - one useful bit of information per 10,000 bits collected - is a ripe avenue for improvement. The natural limit of this direction is single-pixel sequencing, in which the commonplace analogy between bytes and bases will be at its most manifest."
“I like commerce,” says Church, who is loosely connected with some 20 companies as an advisor or scientific contributor (as well as more closely with Agencourt and Codon). “But here, commercially, we’re going to race to the bottom. We’ll run workshops and do everything we can to spread the technology. Agencourt may want to become Amazon or eBay and do useful applications, not make money on the "browser", which spreads freely academically. We wrote the paper to make it extremely enabling. It’s a total cookbook: where to order the parts, how to use them…the opposite of how a commercial entity would write a paper.”
He describes the process, which can use tissues as simple as blood or swabs from a mouth: The material is immobilized into beads on a slide, while various solutions flow through it slowly. The system works basically by matching fragments from the sample onto a reference genome. That is, you can’t do the first instance of any species’ genome this way. You have to start with the multi-million-dollar model. But after that, it’s more like checking a new document against a reference copy for subtle changes, or fitting complementary pieces onto a long jigsaw puzzle. “I’m mostly a scientist, but when I touch engineering I get this rush of excitement,“ says Church. “You have to ignore all the things you can’t do, and not beat yourself up over what you could have done long ago. It’s so arbitrary, but so wonderful when you just make something work!”
Open-source medicine
But Church isn’t content merely to create the technology; he understands that some people don’t want their genomes sequenced, and many more don’t want to share their information. “I see privacy attitudes in three buckets,” he says. “Some people want total privacy; they might not even want to know the information themselves. In the middle, people want just you and your own health-care provider to see it. And on the other end, a large group of researchers could see it. These views all exist; my colleagues think the norm veers towards the private.” But here too, Church is an engineer as well as a scientist, with his Personal Genome Project (see resources page for URL). “We don't seek controversy,” he says, “but we do seek a safe way to explore extremes in order to arrive at a reasonable middle.”
After 12 months Church’s Personal Genome Project (PGP) has been approved by the Harvard Medical School Internal Review Board, which vets the ethics of all human-subjects research proposals at the Med school. Its mission is not to expedite research but to ensure proper treatment of subjects, so this approval is a significant win.
The idea is very simple: to sequence the genomes of individuals – “ however many we can afford, initially” – and to publish them along with the full medical records of those individuals, publicly identified. Then, the idea is to see what kinds of activities and research the presence of such information will foster. And how will the individuals involved feel about it after the fact?’
Church has already gone ahead and put his own medical records online and will do the same with his genome; he’ll be the first research subject. “It’s already very useful,” he says cheerfully. “I was giving a medical seminar one day, and a hematologist in the third row told me I should get my cholesterol checked…He said ‘I looked at your Web page and you’ve been taking Lovastatin. You should have checked after 6 weeks whether it was working.’ And indeed he was right. I had expected the drug to take care of things, but my cholesterol level was up to 288. Following up on his suggestions brought it down to 150.”
The PGP study is carefully designed to meet ethical standards, and it’s a social as well as a technical experiment. The volunteers (we are one, tentatively, though we haven’t seen the fine print) don’t get free medical care, payment or any other benefits that might be considered coercion to say yes. The volunteers are not supposed to be representative, but rather to be articulate, well-informed people who will take the time and trouble to learn about the science and medicine behind the project, and to be spokespeople for genomic research and, by example, openness about medical matters. Yes, we can understand why a certain proportion of people might legitimately want privacy for themselves and family members, just as some people do about other matters, but openness should be perceived as, at best, generosity with data, rather than exhibitionism.
Says Church: “Ultimately, to do epidemiology and association studies we need genome and phenome data, both of which are currently expensive.. but both types of costs can drop dramatically. The phenome data costs could drop via data-mining in medical records and the genomics will drop via technology initiatives from the NIH & DOE. The more patients feel comfortable with the dual use of medical records for health care and research, the more everyone could benefit.”
Oedipus project
He’s optimistic that he’ll get the volunteers, and he also expects a high-end, early adopter market to emerge, along with a more coerced group of people desperate to understand their own anomalous conditions. “I’m looking for Oedipus,” he says. “I don’t want them to poke their eyes out, but they must want to know everything. Consider how much people love their objects – homes and cars…. They could have the same fascination with their bodies and genomes.” Certainly, Ray Kurzweil and Larry Ellison come to mind, along with any number of age-defying Hollywood starlets.
“Imagine having 200 physicians,” he says. “Even in medicine, there’s the wisdom of crowds.
It could be a social phenomenon, which could be good: the weather, or football, or your genome. It’s up to the individual to learn to be witty about their genome. The first thing is to be brief. Find out what you share genetically. If you don’t want to bore them about cholesterol, find out what you do have in common, like kidney disease. And of course, sometimes there’s good news. You might find out that you can marry your cousin with no special risk.”
In 2002 Hans Bruno Lund introduced the concept
"Multicomplex Management (MCM)" as a platform
for a new series of management concepts and tools,
e.g. "Expected Creative Potential (ECP)", desig-
ned as personal tools for the CEO of large, multicom-
plex organizations in addition to the traditional mana-
gement concepts and tools.
As of January 2010 the new concepts / tools "Multicomplex Management (MCM)" and "Expected Creative Potential (ECP)" were referred to on more than 800.000 websites or 40.000.000 webpages.
Literature:
Lund, Hans Bruno
Multicomplex Management (MCM)
Version 3
CD-ROM, 741 colored illustrations
Hans Bruno Lund
Skodsborg
Denmark
2009
A multicomplex organization:
Organization Structure Model used: Nordic Industrial Fund - Nordic Council of Ministers - Bio & Chemistry Division (BCD) - Division REI-activities (Research / Education / Innovation): 5 programmes: NordFood, Nordic Wood, NordPap, NordBio and NordYeast; 748 projects; 6.000 participating private and public companies, institutions, organizations and agencies in 62 countries. BCD connected 180.000 researchers, operators, engineers, technicians and company, organization and agency executives (1998). BCD was - in combination with NordTek (the organization managing the cooperation of the 23 Nordic technical universities) - the largest industrial and technological REI-network in Northern Europe. BCD was a 27.000 ECP Organization connecting 278.000 people totalling 2.7 million ECP. Photo on Picture 1: Hans Bruno Lund visiting the governor of Oulu province, Finland Dr. Eino Siuruainen during a NordTek seminar.
Hans Bruno Lund
Contact: hansbrunolund@hotmail.com
Pictures to Multicomplex Management (MCM): 1, 2, 3, ... , 16.
Multicomplex Management (MCM) Pictures:
Picture 1 - 9 on Page 1
Picture 10 on Page 2
Picture 11 - 12 on Page 6
Picture 13 - 15 on Page 7
Picture 16 on Page 8
Multicomplex Management (MCM) is explained in Picture 2.
Expected Creative Potential (ECP) is explained in Picture 2.
NORDIC INDUSTRIAL FUND
BIO & CHEMISTRY DIVISION (BCD)
RESEARCH SUBJECTS A - K:
Comment: are symboles for REI-areas which could
not be transferred from the original file.
Absorbent (413)
Acetylering (366)
Actin (NY13)
Acustic (240)
Adsorption (291/497)
Aerobic (056/059)
Aeromonas (442)
Affald (197/369) XMX
Affedtning (571)
Akvakultur (339/378/448/483)
Alkoholfuktvatten - Offset (574)
Alkyl-aryl-aromater (309)
Al-legering (202)
Aluminium (680)
Ammonia (047/462)
Anaerobic (100)(50%)
Anaerobic Processes (099-102)
Ändträförsegling (265) XMX
Animal Cell Cultures (047/421)
Antibodies (054/554)
Antimicrobial Activity (068)
AOX (087)
Aquaculture (461)
Aquaform (362)
Aroma development (073-076)
Aroma Transfer in PET (104)
Aromater (309)
ARS1 plasmids (NY11)
Aseptic Safety (126) XMX
Aseptic Symposium (521) XMX
Aseptiska processer (338) XMX
Associativa förtjockare (337)
Atlanterhavslaks (339)
Atlantic cod (065)
Atlantisk laks (378)
Automatisk prickräkning (166)
Avfallsfiber (197) XMX
Avgaser från stålugn (204) XMX
Avloppsvatten (5.3/167) XMX
Avsvärtningsteknologi (227)
Bacon (075)
Bacteria (057/090)
Bacteria (066)(067)(068)(069)(070)(072)
Bacteriocins (070/072)
Bakning - Energi (229) XMX
Bakteriell njurinflammation (347)
Balticum II(722)
Barley (049/050/052/055) XMX
Barriär och migration (171)
Bättre finpapper (432)
Beer (121) XMX
BENEFISH (570)
Benzyl (303)
Bergarter (674)
Bestruket papper (158/159)
Betonelement (375)
Betonelementer (686)
Betong (266/516)
Bildanalys (318)
Billedanalyse (138)
Bioautomation (630)
BioAutomation(533)
Biodegradation (090/092/093) XMX
Biofixation (094-098) XMX
Biofunktionella färgsystem (403)
Biogasproduktion (354) XMX
Biohydrometallurgi (397/479) XMX
Bioleaching (095) XMX
Biological Degradation (091/439) XMX
Biological fixation (094) XMX
Biological off-gas treatment (481) XMX
Biologisk gasrening (400) XMX
Biologisk marksanering (465) XMX
Biomass (249/498) XMX
Bioorganic synthesis (061)
Bioorganisk syntese (380)
Bioorganiska synteser (333)
Biopreservation (067)
Biopreservation (067-072)
Bioprocess Engineering (037-048)
Bioreactor (037/040/041)
Bioreactors (045/046)
BioRecNetwork(542)
Bioremediation (090) XMX
Biosamarbete Norden Europa (459)
Bioseminar (468)
Biosensors (043)
Biosorbents (096)
Biosurfaktanter (453)
BIOTANNOR (595) XMX
Biotechnica Hannover (474)
Biotechnology (031-102)
Bioteknik (329/349/426)
Bioteknisk metallutvinning (502) XMX
Biotekniska metoden (2.2.1.4)
Biotekniske substanser (377)
Biotekniske substanser (454)
Bioteknologi (466/490/507)
Bioteknologi (355)
Bioteknologikonference (424)
Biotester (168/170)
Bjelkelag (575)
Blandsyra (212)
Blåvilling (217)
Blekning (148) XMX
Blekningens miljöpåverkan (239) XMX
Bleksteg (143) XMX
Blekteknik (143-152/632) XMX
Blockpolymerer (307)
Branching enzymes (051)
Brandsäkra trähus (179/622)
Broer i tre (184/626)
Brokarage event (526)
Brus (153/155)
BSC (077/078/081)
Bullerskärmar i trä (187) XMX
Byggkomponenter (532)
Bygninger - Miljø (615) XMX
Car.pis. (069)
Carbohydrates (054/520)
Catalysis (425)
Cell Cultures (047)
Cell cycle gene cdc 21 (NY29)
Cell response (039)
Cellteknologi (421)
Cellular Development (458)
Cellulase (031/060)
Cellulase enzymes (032)
Cellulose (057/141)
Cerealier (263)
Chlorinated compounds (085) XMX
Chromgarvning (200) XMX
CIMFISK (563)
Cis-acting mutations (NY30)
Civil Guard (409) XMX
Cleaner Production (120) XMX
Cloned Polysaccharide Genes (509) XMX
Cloning (051/055/060/NY02/) XMX
Cloning (NY03/NY05) XMX
CO2-extraktion (414)
Cod (065)
Cod trypsin (034)
Collagenolytic enzymes (066)
Concentration gradients (039)
Control Methods (118)
Crude Oil Emulsions (475)
Cryotin (065)
Cured in bag bacon (075)
Cyclodextrin (631)
Dairies (119)
Dairy Hygiene (117) XMX
DAIRYNI (616)
Data Management Waste Water (450) XMX
Databases (035)
Datasystem - Fiskeindustrien (557)
Datorprogram Limträ (178)
Defibrering (488)
Degradation (091/100/439) XMX
Dehydrogenases (060)
Denitrifikation (491) XMX
Design of enzymes (356)
Destillationsregulering (359)
Dewatering of Sludges (089/438) XMX
Dextrin (631)
Dextrinase (055)
Dieelektrisk spektroskopi (135)
DIXI (612)
Djuptryck (515)
Djurkroppar (542)
DNA
DNA coding (NY03)
DNA gene sequence (NY08/NY28)
DNA polymeraser (431)
DNA-metoder (384)
DNA-symposium (401)
Doktorandutbytte (555)
Dörrar (183/546)
Dryforming paper (231) XMX
Dynabeads (471)
EDI i træindustrin (599)
EDISAW - Norden (182/588)
Egenskaper (178-179)
EG-netværk (463)
Electronic Miniturisation (629)
Elektronmikroskopi (137)
Emulgerte system (436)
Emulsioner (296)
Emulsions (112)
Energi (608) XMX
Energi biomassa (249) XMX
Energisnåla metoder (619)
Energy metabolism control (048)
Environm. Beer Production (121) XMX
Environm. Biotechnology (085-102) XMX
Environment (120-122) XMX
Environmental Seafloor mapping (496) XMX
Enzymatic lipid modification (083)
Enzymatic Modification (082-084)
Enzymatic modifications of lipids (084)
Enzymatisk affedtning (571)
Enzymatisk peptidsyntes (251)
Enzyme Catalysis (425)
Enzymer (147/571)
Enzymer fra marine råstoffer (297)
Enzymes (090/356/635)
Enzymes in yeast (NY24)
Enzymes/Lipids-stipend (511)
EPI (592) XMX
EROD-aktiviteten (169)
Eucaryotic tRNA (NY26)
EUREIN (613)
Eurodyn (398)
Europastandarder (165-176)
Evaluation - NordBio (606)
Expertsystem Medicin (270)
Expression of genes (NY02)
Fab domain (NY16)
Fabrik för blekt massa (277) XMX
Facadefilm (685)
Färg (155/207/237/335) XMX
Färgbrusmätning (155)
Färger (291/294) XMX
Färgers reologi (335)
Färgsystem (403) XMX
Fartøy (712)
Fartyg (290)
Fasadytor (541/573)
Fat (386)
Fatty Acid Synthethases (452)
Fatty acids (063)
Fermentated sausage (074)
Fermentation (038/076/079)
FerroAlloys (687)
Fiber (136/197)
Fiberåtervinning (2.3) XMX
Fiberlindningsteknologi (295)
Fibermaterial (2.1)
Fiberväggens egenskaper (2.2.3)
FIMS (562)
Fingerskarvning (597)
Finkemikalieområdet (286)
Fish Packaging (103) XMX
Fish Transportation (103) XMX
Fisk (124/169/395/557/558/563)
Fisk (267)
Fisk (564/568/570/594/609/617)
Fiskavfallenzym (268) XMX
Fiskeoppdrett (301)
Fiskeriutbildning (219)
Fiskfars (247) XMX
Fiskindustriell vattenvård (206) XMX
Fiskodling (292/412) XMX
Fission yeast (NY08/NY27/NY29
Fixation (094) XMX
Fjernvarmerør (352)
Flexotryckning (495)
Flow injection (048)
Flow processes (040)
Fluid dynamics (037)
Fluorescence (111)
FMS i nordisk treindustri (188)
Foaming in bioreactors (044)
Fönster (183/537/560)
Food (607/616/618)
Food Biotechnology (067-084)
Food Brokerage (593)
Food Fat (129)
Food Hygiene (116-119) XMX
Food Packaging (103-106/605) XMX
Förgasning torv (254) XMX
Förpackningar (548)
Forskerseminar (569)
Förstudie kemiområdet (260)
Förtjockare (337)
Förureningar (5.2)
Fouling av membran (264)
Friktion (174)
Frysfartyg (290)
Frysing (284)
Fuktvatten (574)
Functional starch types (053)
Furu kjernved (531)
Fyrfärgsproduktion (237)
Fytokemi (289)
Garvning (194/200/242/246/278) XMX
Garvning (595) XMX
Gas (191/254/345/354/400/481) XMX
Gasrensning (400) XMX
Gener (NY02)
Genetic recombination (NY07)
Genteknik - Utställning (456)
Genteknologi (327)
Geometriska tolleranser (218)
Geotermiska gaser (345) XMX
Ginsing (258)
Glasfiber (679)
Gluten (215)
Grafiska produkter (241)
Grain (132)
Gram-positive cocci (NY17)
Gran (536)
Gravity Ice Island (236) XMX
Grundvandsrensning (486) XMX
Gruvvatten (298) XMX
Hallbyggnader i limtræ (577)
Hälleflundra (483)
Hållfastighet - Træ (624)
Hårdförkromningsmetal (415)
Havskatt (483)
Health (128)
Heavy Metals (094-098) XMX
Hemaglutinin (NY12)
Hemicellulose (057)
Hepatocyter (169)
Hesteblod (336)
Heuristics (042)
HH Stansning (536)
High Pressure (130)
Hippoglossus (346)
Höga tryck (248)
Household waste (100) XMX
Høyutbyttemassa (330) XMX
HPLC control (041)
Hudpermeation (358)
Hum. mon. antikroppar (344/422)
Human parathyroid hormone (NY09/372)
Hushållsavfall (434) XMX
Hydrofobe fasadefilmer (573)
Hydrofobering (315)
Hydrogen Al-legering (202)
Hydrokarbonkjemi (281)
Hydrolytic Enzymes (064-066)
Hydrothermal Grain (132)
Hygiene (075/116-119) XMX
Hygienic Milk Packages (106) XMX
Hygienisering foder (273) XMX
Hygienproblem (470) XMX
Hygienproblem (503) XMX
Hyperbarisk CO2 (325)
Iminobenzyl (303)
Immunologi (478)
Immuntechnology (510)
Immunteknologi-NW (517)
Impregnerat virke (545)
Industrial Enzymes (056-058/635)
Industrial waste (100) XMX
Industrisamarbejde Island/Norden (353)
Infektionsskydd (304)
Influenza virus (NY12)
Inneklimasystem (416) XMX
Inorganic pyrophosphatase (NY18)
Inorganic pyrophosphate (NY04)
Instant pulping (256)
INVIS-projektet (602)
Islandsk perlit (203)
Japan (185)
Järnverk (190) XMX
Jäst- och växtceller (324)
Jästgenetik (276)
Jordrensning (486) XMX
Katalysatorgifte (391)
Katalysatorgifter (280)
Kem.mek. massa (550) XMX
Kemikalier (286)
Kemiområdet (260)
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Literature
Lund, Hans Bruno
Multicomplex Management (MCM)
Version 3
CD-ROM, 741 colored illustrations
Dr. Hans Bruno Lund, Management Consultant
Skodsborg
Denmark
2009
Not available in libraries
An illustration of how fluorescent-tagged DNA interacts with functionalized graphene. Both single-stranded DNA (A) and double-stranded DNA (B) are adsorbed onto a graphene surface, but the interaction is stronger with ssDNA, causing the fluorescence on the ssDNA to darken more. C) A complimentary DNA nears the ssDNA and causes the adsorbed ssDNA to detach from the graphene surface. D) DNA adsorbed onto graphene is protected from being broken down by enzymes.
Terms of Use: Our images are freely and publicly available for use with the credit line, "Courtesy of Pacific Northwest National Laboratory." Please use provided caption information for use in appropriate context.
Mircea Cotlet (standing), post-doc Huidong Zang (center), and graduate student Prahlad Kumar Routh, hope their research on quantum dots for solar cells will brighten our energy future. (They're wearing laser safety goggles required for their experiments)
Quantum dots—tiny semiconductor crystals with diameters measured in billionths of a meter—have enormous potential for applications that make use of their ability to absorb or emit light and/or electric charges. Examples include more vividly colored light-emitting diodes (LEDs), photovoltaic solar cells, nanoscale transistors, and biosensors. But because these applications have differing—sometimes opposite—requirements, finding ways to control the dots’ optical and electronic properties is crucial to their success. A new study conducted at Brookhaven's Center for Functional Nanomateials shows that shrinking the core of a quantum dot can enhance the ability of a surrounding polymer to extract electric charges generated in the dot by the absorption of light.
Graphene and DNA can combine to create a stable and accurate biosensor, reports a study published in the nanotechnology journal Small. The tiny biosensor might eventually help doctors and researchers better understand and diagnose disease.
Using resources at the Department of Energy’s EMSL, scientists at the Department of Energy's Pacific Northwest National Laboratory and Princeton University showed that single-stranded DNA strongly interacts with graphene, a nanomaterial made of sheets of carbon atoms just a single atom thick. They also found that graphene protects DNA from being broken down by enzymes similar to those found in body fluids - a characteristic that should make graphene-DNA biosensors highly durable.
The illustration shows how fluorescent-tagged DNA interacts with functionalized graphene. Both single-stranded DNA (A) and double-stranded DNA (B) are adsorbed onto a graphene surface, but the interaction is stronger with ssDNA, causing the fluorescence on the ssDNA to darken more. C) A complimentary DNA nears the ssDNA and causes the adsorbed ssDNA to detach from the graphene surface. D) DNA adsorbed onto graphene is protected from being broken down.
In 2002 Hans Bruno Lund introduced the concept
"Multicomplex Management (MCM)" as a platform
for a new series of management concepts and tools,
e.g. "Expected Creative Potential (ECP)", desig-
ned as personal tools for the CEO of large, multicom-
plex organizations in addition to the traditional mana-
gement concepts and tools.
As of January 2010 the new concepts / tools "Multicomplex Management (MCM)" and "Expected Creative Potential (ECP)" were referred to on more than 800.000 websites or 40.000.000 webpages.
Literature:
Lund, Hans Bruno
Multicomplex Management (MCM)
Version 3
CD-ROM, 741 colored illustrations
Hans Bruno Lund
Skodsborg
Denmark
2009
A multicomplex organization:
Organization Structure Model used: Nordic Industrial Fund - Nordic Council of Ministers - Bio & Chemistry Division (BCD) - Division REI-activities (Research / Education / Innovation): 5 programmes: NordFood, Nordic Wood, NordPap, NordBio and NordYeast; 748 projects; 6.000 participating private and public companies, institutions, organizations and agencies in 62 countries. BCD connected 180.000 researchers, operators, engineers, technicians and company, organization and agency executives (1998). BCD was - in combination with NordTek (the organization managing the cooperation of the 23 Nordic technical universities) - the largest industrial and technological REI-network in Northern Europe. BCD was a 27.000 ECP Organization connecting 278.000 people totalling 2.7 million ECP.
Hans Bruno Lund
Contact: hansbrunolund@hotmail.com
Pictures to Multicomplex Management (MCM): 1, 2, 3, ... , 16.
Multicomplex Management (MCM) Pictures:
Picture 1 - 9 on Page 1
Picture 10 on Page 2
Picture 11 - 12 on Page 6
Picture 13 - 15 on Page 7
Picture 16 on Page 8
Multicomplex Management (MCM) is explained in Picture 2.
Expected Creative Potential (ECP) is explained in Picture 2.
--------------------------------------------------------------------------------------------
FOUR CATEGORIES OF ORGANIZATION STRUCTURES
--------------------------------------------------------------------------------------------
The above mentioned concepts and tools are part of an ongoing project “Multicomplex Management (MCM)”.
In “Multicomplex Management” we divide organizations into four categories according to their total ECP:
SIMPLE ORGANIZATIONS
Total ECP ranging from 0.1 to approx. 100.
SEMICOMPLEX ORGANIZATIONS
Total ECP ranging from approx. 100 to approx. 1.000.
COMPLEX ORGANIZATIONS
Total ECP ranging from approx. 1.000 to 10.000.
MULTICOMPLEX ORGANIZATIONS
Total ECP exceeding 10.000.
=====================================================
BCD AND THE NORDIC ENVIRONMENT
=====================================================
The Nordic Industrial Fund´s Bio & Chemistry Division
was through more than 250 projects heavily engaged
in protection and improvement of the environment of
the Nordic geographic area and that on all levels from
deep in the earth to space initiatives.
Here some activity-examples (marked ENVIRONMENT) from BCD´s
BIO INDUSTRIAL COMPLEX:
Aerobic (ZZ056/059)
Aeromonas (ZZ442)
Affald (ZZ197/369) (ENVIRONMENT)
Affedtning (ZZ571)
Anaerobic (ZZ100)(ZZ50%)
Anaerobic Processes (ZZ099-102)
Animal Cell Cultures (Z047/421)
Antibodies (Z054/554)
Antimicrobial Activity (Z068)
AOX (Z087) (ENVIRONMENT)
ARS1 plasmids (ZNY11)
Avgaser från stålugn (Z204) (ENVIRONMENT)
Avloppsvatten (Z5.3/167) (ENVIRONMENT)
Bacteria (Z... ...)
BioAutomation
Bioautomation (Z630)
Biodegradation (Z090/092/093) (ENVIRONMENT)
Biofixation (Z094-098) (ENVIRONMENT)
Biofunktionella färgsystem (Z403)
Biogasproduktion (Z354)
Biohydrometallurgi (ENVIRONMENT)
Bioleaching (Z095) (ENVIRONMENT)
Biological Degradation (Z091/439) (ENVIRONMENT)
Biological fixation (Z094) (ENVIRONMENT)
Biological off-gas treatment (Z481) (ENVIRONMENT)
Biologisk gasrening (Z400) (ENVIRONMENT)
Biologisk marksanering (Z465) (ENVIRONMENT)
Biomass (Z249/498)
Bioorganic synthesis (Z061)
Bioorganisk syntese (Z380)
Bioorganiska synteser (Z333)
Bioprocess Engineering (Z037-048)
Bioreactor (Z037/040/041)
Bioreactors (Z045/046)
BioRecNetwork
Bioremediation (Z090) (ENVIRONMENT)
Biosamarbete Norden Europa (Z459)
Bioseminar (Z468)
Biosensors (Z043)
Biosorbents (Z096)
Biosurfaktanter (Z453)
BIOTANNOR (Z595)
Biotechnica Hannover (Z474)
Biotechnology (Z031-102)
Bioteknik (Z329/349/426)
Bioteknisk metallutvinning (Z502) (ENVIRONMENT)
Biotekniska metoden (Z2.2.1.4)
Biotekniske substanser (Z377)
Biotekniske substanser (Z454)
Bioteknologi (Z466/490/507)
Bioteknologi (Z355)
Bioteknologikonference (Z424)
Biotester (Z168/170)
Branching enzymes (Z051) (ENVIRONMENT)
Car.pis. (Z069)
Cell Cultures (Z047)
Cell cycle gene cdc 21 (ZNY29)
Cell response (Z039)
Cellteknologi (Z421)
Cellular Development (Z458)
Cellulasbok Prot.Eng.(Z512)
Cellulase (Z031/060)
Cellulase enzymes (Z032)
Cellulose (Z057/141)
Cisacting mutations (ZNY30)
Civil Guard (Z409) (ENVIRONMENT)
Cloning (Z051/055/060/NY02/)
Cloning (ZNY03/NY05)
Collagenolytic enzymes (Z066)
Concentration gradients (Z039)
Cryotin (Z065)
Data Management Waste Water (Z450) (ENVIRONMENT)
Databases (Z035)
Degradation (Z091/100/439) (ENVIRONMENT)
Dehydrogenases (Z060)
Design of enzymes (Z356)
Dewatering of Sludges (Z089/438) (ENVIRONMENT)
Djurkroppar (Z542)
DNA
DNA coding (ZNY03)
DNA gene sequence (ZNY08/NY28)
DNA polymeraser (Z431)
DNAmetoder (Z384)
DNAsymposium (Z401)
Dynabeads (Z471)
Energi (Z608)
Energi biomassa (Z249)
Energisnåla metoder (Z619)
Energy metabolism control (Z048)
Environm. Biotechnology (Z085-102 (ENVIRONMENT))
Environm. Seafloor mapping (Z496) (ENVIRONMENT)
Environment (Z120-122) (ENVIRONMENT)
Enzymatic lipid modification (Z083)
Enzymatic Modification (Z082-084)
Enzymatic mofific. of lipids (Z084)
Enzymatisk affedtning (Z571)
Enzymatisk peptidsyntes (Z251)
Enzyme Catalysis (Z425)
Enzymer (Z147/571)
Enzymer fra marine råstoffer (Z297)
Enzymes (Z051/059/063)
Enzymes (Z090/356/635)
Enzymes in yeast (ZNY24)
Enzymes/Lipidsstipend (Z511)
EPI (Z592) (ENVIRONMENT)
Eucaryotic tRNA (ZNY26)
EUREIN (Z613)
Evaluation NordBio (Z606)
Expression of genes (ZNY02)
Fab domain (ZNY16)
Fission yeast (ZNY08/NY27/NY29)
Fixation (Z094) (ENVIRONMENT)
Foaming in bioreactors (Z044)
Fungies (Z... ...)
Förgasning torv (Z254) (ENVIRONMENT)
Fouling av membran (Z264)
Gas (Z191/254/345/354/400/481) (ENVIRONMENT)
Gasrensning (Z400) (ENVIRONMENT)
Gener (ZNY02)
Genetic recombination (ZNY07)
Genteknik Utställning (Z456)
Genteknologi (Z327)
Geotermiska gaser (Z345) (ENVIRONMENT)
Ginsing (Z258)
Glycoprotein (ZNY01/15/23)
Grampositive cocci (ZNY17)
Grundvandsrensning (Z486) (ENVIRONMENT)
Gruvvatten (Z298) (ENVIRONMENT)
Heavy Metals (Z094-098) (ENVIRONMENT)
Hemaglutinin (ZNY12)
Hemicellulose (Z057)
Hepatocyter (Z169)
Hesteblod (Z336)
Heuristics (Z042)
Household waste (Z100) (ENVIRONMENT)
Hushållsavfall (Z434) (ENVIRONMENT)
Hydrolytic Enzymes (Z064-066)
Industrial Enzymes (Z056-058/635)
Industrial waste (Z100) (ENVIRONMENT)
Inneklimasystem (Z416) (ENVIRONMENT)
Järnverk (Z190) (ENVIRONMENT)
Jäst- och växtceller (Z324)
Jästgenetik (Z276)
Jordrensning (Z486) (ENVIRONMENT)
Klima (Z416) (ENVIRONMENT)
Kloningsvektorer (Z310)
L. brevis (ZDetmold)(Z080)
L. plantarum (Zvalencia) (Z080)
Lac.Aci.Bac. (Z067-072/312/494)
Lac.Pen. (Z073)
Landfill leachates (Z101/102) (ENVIRONMENT)
Leachates (Z101/102) (ENVIRONMENT)
Leaching (Z095) (ENVIRONMENT)
Light chain (ZNY16)
Lipases (Z031/033/505)
Lipids (Z082-084/511)
Loopfermentor (Z482)
Lysozyme (Z064)
Marin begroing (Z484)
Marine organisms (Z066)
Marine råstoffer (Z297)
Marksanering (Z465/590) (ENVIRONMENT)
Marksanering (Z524/637) (ENVIRONMENT)
Mass transfer (Z037)
Maturation processes (ZNY26)
Membrane filtration (Z086)
Membranes (ZNY03/18/19/25)
Methionine (ZNY06/14)
Microtox (Z170) (ENVIRONMENT)
Mikroalger (Z373)
Mikrobiellt protein (Z193)
Mikrobielt peroxidas (Z259)
Mikrobiologi (Z172) (ENVIRONMENT)
Mikroemulsioner (Z296)
Mikroformering (Z308)
Mikrosfärer (Z341)
Miljö (Z239/582/585/600/615) (ENVIRONMENT)
Miljö i garverier (Z194) (ENVIRONMENT)
Miljöanpassad betong (Z516) (ENVIRONMENT)
Miljödeklarationer (Z528) (ENVIRONMENT)
Miljökrav skrotsmält (Z323) (ENVIRONMENT)
Miljømodellering (Z449) (ENVIRONMENT)
Miljø-ORS-Paraply (Z527) (ENVIRONMENT)
Miljøovervågning (Z423) (ENVIRONMENT)
Miljöprofilering djuptryck (Z515) (ENVIRONMENT)
Miljørisiko - Gensplejsning (Z371) (ENVIRONMENT)
Miljøteknologi (Z489) (ENVIRONMENT)
Mine drainage (Z094) (ENVIRONMENT)
Mitochondria (ZNY04/18)
Molecular Imprinting (Z440)
Molecular modelling (Z035)
Molekylærbiologi (Z399)
Multidetektor (Z385/411) (ENVIRONMENT)
Mutant saturation (ZNY08/NY27)
Närsaltreduktion (Z382) (ENVIRONMENT)
NordBio (Z606) (ENVIRONMENT)
Nordmiljö (Z196) (ENVIRONMENT)
NordPhys (Z508) (ENVIRONMENT)
NordPhys (Z610) (ENVIRONMENT)
Nuclear dcm (ZNY28)
Nuclear envelope (ZNY20)
Off-gas (Z481) (ENVIRONMENT)
Öppningssäkerhet (Z343) (ENVIRONMENT)
PAH (Z092) (ENVIRONMENT)
Panax (Z258)
PCD (Z092) (ENVIRONMENT)
Peptidsyntes (Z251)
Phospholipase C (Z036)
Photosynthesis (Z473)
Physiological effects (Z038)
Physiological Engineering (Z508)
Plant Cell Biotechnology (Z049-055) (ENVIRONMENT)
Pollutants (Z090-093) (ENVIRONMENT)
Process Environments (Z043) (ENVIRONMENT)
Profilin (ZNY13)
Prot. Eng. (Z031-036/302/402/NY13) (ENVIRONMENT)
Proteases (Z058/429)
Protein Eng. Konferens (Z299)
Protein Eng. receptorer (Z367)
Protein secretion (ZNY01/15/23)
Protein software tools (Z031)
Proteinstrukturer (Z477)
Proteolytic mixtures (Z065)
Psychrophilic Org. (Z056-066) (ENVIRONMENT)
Psykrofile organismer (Z370)
Pyrophosphatase (ZNY18)
Pyrophosphate (ZNY04/18)
RADIOBIO process (Z088)
Remediation (Z090) (ENVIRONMENT)
Replication control (ZNY11)
RNA polymerases (ZNY10)
RNAs (ZNY10)
Saccharomyces cer. (Z001-030)
Scallop viscera (Z064)
Screening (Z082)
Seafloor (Z496) (ENVIRONMENT)
Secretion in yeast (ZNY22)
Serine Proteases (Z429)
Skrotsmält (Z323) (ENVIRONMENT)
Sludge (Z087/089/097/438) (ENVIRONMENT)
Soil (Z090/092/097) (ENVIRONMENT)
Solid Waste (Z099-102) (ENVIRONMENT)
Soluble Starch Synthase (Z050)
Sorbents (Z096)
Stålugn (Z204) (ENVIRONMENT)
Stålverk (Z190/343/518) (ENVIRONMENT)
Støveksplosjoner (Z201) (ENVIRONMENT)
Støy (Z4.1.3.2) (ENVIRONMENT)
Styrenbemängd luft (Z419) (ENVIRONMENT)
Termofile enzymer (Z383)
Termofile vektorer (Z430)
Thermophile bakterier (Z300)
Thermophile lipase activity (Z082)
Thermophile organismer (Z370)
Thermophiles (Z056/059)
Thermophiles (Z487)
Thermophilic microbiology (Z099)
Thermophilic Organisms (Z056-066)
Thorothermus Marinus (Z062)
Threonine biosynthesis (ZNY06)
Torv (Z254)
Transcription (ZNY26)
Transcription factors (ZNY10)
Transcription of RNAs (ZNY10)
Transcriptional control (ZNY21)
Transfer RNA (ZNY24)
Transport of proteins (ZNY20)
Troponin C (ZNY13)
Trypsin (Z034)
Tungmetaller (Z173) (ENVIRONMENT)
Tyrosin hydroksylase (Z313)
Underglycosylated prot.A (ZNY30)
Vatten (Z167/604/608) (ENVIRONMENT)
Vatten i järn- och stålverk (Z190) (ENVIRONMENT)
Växtcellbioteknik (Z365/406) (ENVIRONMENT)
Växtcellbioteknologi (Z406) (ENVIRONMENT)
Vegetation Mapping (Z443) (ENVIRONMENT)
Wastes (Z094/096) (ENVIRONMENT)
Wastewater (Z085/095/098/450) (ENVIRONMENT)
Water in Fish Industry (Z122) (ENVIRONMENT)
Water Jet Deboning (Z125) (ENVIRONMENT)
Xylan (Z062)
Xylanases (Z056/060/062)
Xylose Utilixation (Z447)
Yeast (Z001-030) (ENVIRONMENT)
Yeast ADE4 gene (ZNY11)
Zinkholdig støv (Z518) (ENVIRONMENT)
Literature
Lund, Hans Bruno
Multicomplex Management (MCM)
Version 3
CD-ROM, 741 colored illustrations
Dr. Hans Bruno Lund, Management Consultant
Skodsborg
Denmark
2009
Not available in libraries
“I sing the body electric” takes on new meaning in our brave new digital world, where devices let us monitor everything from our stress levels to our genetic sequences, and devices with 100 real-time biosensors loom on the horizon. Join moderator Arianna Huffington, @ariannahuff, as she leads Deepak Chopra, MD, @DeepakChopra, Founder of The Chopra Foundation and Chopra Center, Deepak Chopra LLC, David Daly, Head of Oncology, Life Technologies, @LIFECorporation, Andrew Thompson, President & CEO, Proteus Digital, @Proteusdh, Reed V. Tuckson, @DrReedTuckson, MD, FACP, Executive Vice President and Chief of Medical Affairs, UnitedHealth Group, @CEShealth, and Sonny Vu, Co-Founder & CEO, Misfit Wearables, @MisfitWearables, in conversation on the latest innovations in the field, how those innovations have the potential to change lives, and what the digital revolution means for the body, mind, and soul.
The Digital Health Summit at the 2013 International CES®
bit.ly/DigitalHealthCES - Focuses on the latest products and consumers' growing demand for high-tech health services. See solutions for diagnosing, monitoring and treating a variety of illnesses - from obesity to ADHD, from poor vision to high blood pressure.
Learn about games that reinforce healthy behaviors, body sensors that let people take more responsibility for their own health, affordable gene sequencing, real-time medicine monitoring, and more. You'll gain an understanding of the digital health infrastructure and how your organization can capitalize on this hot market.
Official Hashtag: #DigiHealthCES News & Press Articles: #DigiHealthCESPress CES Hashtag: #2013CES
Website: bit.ly/DigitalHealthWebsite
Twitter: bit.ly/DigitalHealthTwitter
YouTube Videos: bit.ly/DigitalHealthYouTube
Flickr Photos: bit.ly/DigitalHealthFlickr
Linkedin: bit.ly/DigitalHealthLinkedIn
Facebook: bit.ly/DigitalHealthFB
Google+: bit.ly/DigitalHealthGPlus
Pinterest: bit.ly/DigitalHealthPinterest
Instagram: bit.ly/DigitalHealthInstagram
Foursquare: bit.ly/DigitalHealthFourSquare
Thank you! AARP bit.ly/AARP_DHS for sponsoring Digital Health Summit Live.
Social Media Team: www.newmediasynergy.com
Photos by Asa Mathat www.asamathat.com
PNNL researchers genetically engineered this microscopic marine diatom to become a biosensor for the sugar ribose. From left to right: The engineered diatom without fluorescence; the same diatom exhibiting blue fluorescence; and, when no ribose is present, the diatom generates a bright yellow fluorescence via fluorescence resonance energy transfer. Amnis Corp. of Seattle, Wash., used its ImageStream imaging flow cytometer to take these images.
Terms of Use: Our images are freely and publicly available for use with the credit line, "Courtesy of Pacific Northwest National Laboratory." Please use provided caption information for use in appropriate context.
www.inc.com/magazine/201504/extreme-relaxation-tech-gadge...
Thync is the most radical new product that promises to put calm in your palm. Using Bluetooth, it delivers "vibes"--or "intelligent waveforms"--directly to the brain via thumb-drive-size patches that attach to your neck and forehead. It soothes or stirs, depending on whether you choose "Calm" or "Energy" from its app. The company says thousands of volunteers have tested the product, which goes on sale this year.
At January's Consumer Electronics Show, one subject looked nervous as Thync's patches went on. (Not surprisingly, he selected the calm setting.) But soon his shoulders sank and his head drooped. After about 20 minutes, he said he felt completely relaxed, though later he reported a headache and feeling like he'd overslept.
Thync, which has raised $13 million, uses the term "neurosignaling" to describe its use of electrical pulses to modulate brain activity. Co-founder Jamie Tyler envisions consumers using Thync instead of coffee or cocktails--a reassuringly familiar metaphor.
"People are really excited by this, and rightly so," says Roi Cohen Kadosh, a doctor in the department of experimental psychology at Oxford University. But he is concerned such devices might be used on people--stroke victims, say--for whom results might differ. He also knows of no studies that assess how such stimulation, over time, affects the brain. "The brain is a very complex system," says Kadosh. "We might stimulate areas involved with mood. I don't know if it will affect brain areas involved in other cognitive functions."
Tyler points to all those who have tried Thync, and insists his company would have never acquired funding if it hadn't been proven. But, counters Kadosh, "it's a big experiment. People should be aware of that."
Most companies address stress with more traditional biofeedback tools. Thync sends signals to the brain (think of it as push); other gadgets record brain or heart activity (think of them as pull) and offer exercises to help users chill out. The Melon Headband has sensors that track electrical pulses from the brain, and it comes with a relaxation app: Stay calm to stop a blue screen from turning red. PIP (see below) measures stress through your skin and offers relaxing apps as well.
Pplkpr (say "people keeper") helps you manage stress by dodging those who cause it. Wear its Fitbit-like wristband, scroll through your contacts, and learn who makes you tense, angry, or joyful. Over time, as Pplkpr gathers data on your responses, it can delete contact info for harshers of your mellow.
The appeal of Thync is obvious: You can dial down stress as easily as the volume on your tunes. Products relying on biofeedback and self-management require more from users, but their benefits may last longer. Relieve a founder's stress and she can function for a while. Teach her to manage stress and she can function for a lifetime. --Leigh Buchanan
PIP (top): This pad senses stress on the basis of how much you sweat, and its programs teach you to chill. Pplkpr (middle): Strap it to your wrist, read your contact list, and learn who you really like--and who really makes you tense. Melon Headband (bottom): You may not want to be seen in one--but it teaches relaxation and focus.
The Touchpad That Read My Sweat for Stress
When I heard about the PIP biosensor, I had to try one out. But I made sure to pick an especially hectic week, when my to-do list was much longer than usual, to see if the device could calm me down and make me work smarter.
The PIP looks like a portable fingerprint reader: It's shaped like a teardrop and has a pad for a finger. That pad read my electro-dermal activity--that is, the sweat I produce when I get nervous--while its Stress Tracker app showed me a real-time indicator of my anxiety, moving down when I was stressed and up when I relaxed. The PIP comes with app-based games that train you to relax. In one, calming down makes a winter scene thaw and trees blossom. In another, a dragonfly, somewhat counterintuitively, flies faster the more you chill out.
During my workdays, I stopped every three hours to take a quick reading with the PIP and use the Stress Tracker app. Each time I did, a sense of relaxation lasting about 10 minutes followed. I also found I had a bit more energy. But after a few days, I realized that the ritual was mostly what lowered my stress--stopping work, opening the app, placing my finger on the sensor, and focusing on something else--since I was making a point to stop and relax.
All the same, it worked. I felt less stressed, especially when juggling multiple tasks like email, research, and social media. At $179, the PIP is a bit pricey. But I plan to keep using it when things get hectic. --John Brandon
Radical Stress Relief Through the Ages
Today's gadgets are just the latest out-there attempts to relieve pain, stress, and depression. --J.B.
1801
Direct brain stimulation: Sending electrical currents through the brain is nothing new. The Italian researcher Giovanni Aldini was the first to use the technique on patients.
1974
The TENS Unit: These battery-operated padsuse electricityto excite your nerve endingsand relieve pain.
2003
Neuronetics-: This company makes a headset that sends magnetic waves through the brain, as a means to treat depression.
2006
HeartMath EmWave Personal Stress Reliever-: The EmWave measures the time between heartbeats---an accurate indicator of your stress level--and teaches relaxation by focusing on that interval.
2013
Zensorium Tinké-: By measuring heart rate, respiratory rate, and blood oxygen saturation via a finger sensor, this monitor teaches you to take deep, relaxing breaths.
For booking: advanced-stemcells.euroscicon.com/registration
Meet the founder and CEO of AgeX Therapeutics, Inc, Alameda, California at our conference on Dec 03-04, 2018 at Valencia, Spain
#stemcellstherapy #stemcells #cordblood #cancer #arthritis #stemcellsresearch #advancedmedicine #Autism
Presentació de la 6ª edició de la cursa solidària de la PKU Corre per ells.
www.visitsitges.com/ca/carrera-pku-atm-sitges-2019
La presentació ha comptat amb l’assistència de l’alcalde de Sitges, Miquel Forns; la presidenta de la Fundació PKU, Lula Vila; el responsable del Laboratori Metabòlic de l’Hospital Sant Joan de Déu, Dr. Rafael Artuch; els promotors i organitzadors de la Cursa Solidaria Corre per Ells, i membres de la Fundació PKU, Charo Sánchez-Cancio i Alfonso Lügstenmann; el director del Sitges- Festival Internacional de Cinema Fantàstic de Catalunya, Xavier Durán; la cap de zona de “La Caixa”, Esther Magallon; i el director de Sensors i Biosensors del departament de química de la Universitat Autónoma de Barcelona (UAB), Julián Alonso.
Dissolved nanoparticles made from noble metals and metal oxides. Their size, constitution and shape determines the color of the solution. These parameters are tuned to best fit a certain application. This kind of nanoparticles can be used in optical biosensor applications. For this application, the nanoparticles are functionalized with biomolecules that specifically bind the target molecule.
June 20, 2012 - Empowerment health technologies allow us to take greater control over decisions that affect our health. Lab visitors discovered technologies that can help tinker with our eating habits, sleep, and exercise to “make health” for yourself. They built their own glucose meter to test the glucose levels of common foods and create biosensors to measure physical movement and blood pressure.
Photos: Luke Abiol
© 2012 Solomon R. Guggenheim Foundation, New York
June 20, 2012 - Empowerment health technologies allow us to take greater control over decisions that affect our health. Lab visitors discovered technologies that can help tinker with our eating habits, sleep, and exercise to “make health” for yourself. They built their own glucose meter to test the glucose levels of common foods and create biosensors to measure physical movement and blood pressure.
Photos: Luke Abiol
© 2012 Solomon R. Guggenheim Foundation, New York
“I sing the body electric” takes on new meaning in our brave new digital world, where devices let us monitor everything from our stress levels to our genetic sequences, and devices with 100 real-time biosensors loom on the horizon. Join moderator Arianna Huffington, @ariannahuff, as she leads Deepak Chopra, MD, @DeepakChopra, Founder of The Chopra Foundation and Chopra Center, Deepak Chopra LLC, David Daly, Head of Oncology, Life Technologies, @LIFECorporation, Andrew Thompson, President & CEO, Proteus Digital, @Proteusdh, Reed V. Tuckson, @DrReedTuckson, MD, FACP, Executive Vice President and Chief of Medical Affairs, UnitedHealth Group, @CEShealth, and Sonny Vu, Co-Founder & CEO, Misfit Wearables, @MisfitWearables, in conversation on the latest innovations in the field, how those innovations have the potential to change lives, and what the digital revolution means for the body, mind, and soul.
The Digital Health Summit at the 2013 International CES®
bit.ly/DigitalHealthCES - Focuses on the latest products and consumers' growing demand for high-tech health services. See solutions for diagnosing, monitoring and treating a variety of illnesses - from obesity to ADHD, from poor vision to high blood pressure.
Learn about games that reinforce healthy behaviors, body sensors that let people take more responsibility for their own health, affordable gene sequencing, real-time medicine monitoring, and more. You'll gain an understanding of the digital health infrastructure and how your organization can capitalize on this hot market.
Official Hashtag: #DigiHealthCES News & Press Articles: #DigiHealthCESPress CES Hashtag: #2013CES
Website: bit.ly/DigitalHealthWebsite
Twitter: bit.ly/DigitalHealthTwitter
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Flickr Photos: bit.ly/DigitalHealthFlickr
Linkedin: bit.ly/DigitalHealthLinkedIn
Facebook: bit.ly/DigitalHealthFB
Google+: bit.ly/DigitalHealthGPlus
Pinterest: bit.ly/DigitalHealthPinterest
Instagram: bit.ly/DigitalHealthInstagram
Foursquare: bit.ly/DigitalHealthFourSquare
Thank you! AARP bit.ly/AARP_DHS for sponsoring Digital Health Summit Live.
Social Media Team: www.newmediasynergy.com
Photos by Asa Mathat www.asamathat.com
Engineers have developed a tiny, ultra-low power chip that could be injected just under the surface of the skin for continuous, long-term alcohol monitoring. The chip is powered wirelessly by a wearable device such as a smartwatch or patch. The goal of this work is to develop a convenient, routine monitoring device for patients in substance abuse treatment programs.
Press release: jacobsschool.ucsd.edu/news/news_releases/release.sfe?id=2521
Photo credit: David Baillot/UC San Diego Jacobs School of Engineering
June 20, 2012 - Empowerment health technologies allow us to take greater control over decisions that affect our health. Lab visitors discovered technologies that can help tinker with our eating habits, sleep, and exercise to “make health” for yourself. They built their own glucose meter to test the glucose levels of common foods and create biosensors to measure physical movement and blood pressure.
Photos: Luke Abiol
© 2012 Solomon R. Guggenheim Foundation, New York
Soledad Peresin, assistant professor of forest biomaterials in the School of Forestry and Wildlife Sciences, received a grant from the Alabama Department of Economic and Community Affairs for a project in which she and Auburn colleagues will develop advanced biosensors for contaminant detection.
June 20, 2012 - Empowerment health technologies allow us to take greater control over decisions that affect our health. Lab visitors discovered technologies that can help tinker with our eating habits, sleep, and exercise to “make health” for yourself. They built their own glucose meter to test the glucose levels of common foods and create biosensors to measure physical movement and blood pressure.
Photos: Luke Abiol
© 2012 Solomon R. Guggenheim Foundation, New York
College of Engineering faculty, staff and students recently met with Rick Nork, Wayne State vice president, treasurer and chief financial officer, and representatives from Wayne State’s Facilities Planning and Management team to walk through the newly renovated core research lab facility in the Engineering Building. The lab is the first in the College of Engineering to be home to professors from different college departments.
Harini G. Sundararaghavan, biomedical engineering professor, is a neural tissue engineering expert. She is working to fabricate materials to promote and direct nerve regeneration. “In this lab we fabricate and characterize clinically relevant biomaterials targeted toward repair of both the peripheral and central nervous system. We synthesize these materials, construct patterned scaffolds, culture them with neuronal cells and evaluate cell response.”
Zhiqiang Cao, chemical engineering professor, is an expert in biomaterials. “We use a multidisciplinary approach to study new materials and understand their translational applications in healthcare and biomedical engineering” His research interests are material/surface chemistry, biomaterials, antifouling/antimicrobial coatings, biosensors, nanomedicine and tissue engineering. Cao develops new technologies to diagnose and treat cancers and diabetes.
The space has eight benches, two cell culture rooms, one micro-spinning room, space for a freezer farm and two graduate student offices. According to Dean Farshad Fotouhi, the college expects to welcome a third faculty member to join this research lab by Fall 2013.
A close-up of a vial of porphrin solution in the Vangie Alocilja lab at MSU.
Alocilja, an MSU AgBioResearch scientist and professor of Biosystems and Agricultural Engineering, has recently developed a sensor to detect Bacillus species and bovine viral diarrhea virus.
"Nanoscale materials are very different from their larger counterparts," said Alocilja. "For example, the smaller the particles get, the greater the changes in the particles' chemical, electronic, magnetic and mechanical properties. Nanoparticles also have an increased surface area, which offers more space for interaction with other substances."