LED Ink Proofer
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LED Ink Proofer
Why you need a LED ink Curing proofer ?
Why you need a LED ink Curing proofer ?
Are you still doubt how much UV LED energy you need when you print by new LED ink because your ink proofer only run 10m/min? DPL Speedy UV LED Ink curing proofer will provide all data you need for your printing machine: test speed from 4-300m/min, curing distance adjustable from 2 to 10mm, curing energy automatic adjustable by speed. You can download all testing result to your PC as well. Welcome…
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DPL announced LED CAST&CURE for holographic business
DPL announced LED CAST&CURE for holographic business
http://leduv.dpl.dk/wp-content/uploads/2017/03/LED-CAST-CURE--www.dpl_.dk_.mp4
https://www.youtube.com/watch?v=Vc2LGLsa0mU
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UV curing technology creating an active packaging
UV curing technology creating an active packaging
What is Active packaging
Active packaging, intelligent packaging, and smart packaging refer to packaging systems used with foods, pharmaceuticals, and several other types of products. They help extend shelf life, monitor freshness, display information on quality, improve safety, and improve convenience.
The terms are closely related. Active packaging usually means having active functions beyond…
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Case study – how LED UV curing system working in security printing process
Case study – how LED UV curing system working in security printing process
What is security printing?
Security printing is the field of the printing industry that deals with the printing of items such as banknotes, cheques, passports, tamper-evident labels, product authentication, stock certificates, postage stamps and identity cards. The main goal of security printing is to prevent forgery, tampering, or counterfeiting. More recently many of the techniques used to…
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what is Modularity LED drive system
what is Modularity LED drive system
DPL Industri A/S introduce Modularity LED drive system to control our high power led curing lamp serial. Clients can install different numbers of power module according to their energy output. With this kind design, the uniformity and radiation will be controlled and keep stability for each led power module.
Each power module has 600W. Each LED modulewill be connected to each power module or…
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NIH award funds research into tiny LED devices that shine light on brain disorders
NIH award funds research into tiny LED devices that shine light on brain disorders https://www.kiwilighting.com/blog/nih-award-funds-research-tiny-led-devices-shine-light-brain-disorders/ To better understand and one day provide improved treatments for depression, addiction and anxiety, researchers at Washington University School of Medicine in St. Louis are using tiny, electronic devices to identify and map neural circuits in the brain. Wireless micro-LED devices are allowing...
NIH award funds research into tiny LED devices that shine light on brain disorders
To better understand and one day provide improved treatments for depression, addiction and anxiety, researchers at Washington University School of Medicine in St. Louis are using tiny, electronic devices to identify and map neural circuits in the brain.
Portable optogenetic LED device[/caption]
The innovative work has been recognized with a rare grant called EUREKA (Exceptional, Unconventional Research Enabling Knowledge Acceleration) that funds high-risk/high-reward projects. The National Institutes of Health (NIH) supports 12 to 18 such grants each year.
With the award, Michael R. Bruchas, PhD, assistant professor of anesthesiology, and his colleagues will conduct studies with micro-LED devices that his group recently co-developed with a team at the University of Illinois in Urbana-Champaign.
The work is part of the developing field of optogenetics, which uses advances in optics and genetics to control individual brain cells. For example, scientists can take a light-activated gene targeted at a particular type of neuron and insert the gene into a mouse. It then becomes possible to shine light into the animal’s brain either to get neurons to fire or to inhibit their activity.
In a recent study, Bruchas and his colleagues used the tiny electronic devices, which are thinner than a human hair, to tap into the internal reward system of mice, prodding their neurons to release dopamine, a chemical associated with pleasure, when the mice poked their noses through a hole in a particular part of a maze.
“Optogenetics allows us to zero in on specific populations of neurons and understand which ones are involved in complex behaviors,” Bruchas said. “What we learn from these studies will make it possible for us to target specific populations of brain cells that malfunction in depression, pain, addiction and other disorders.” The four-year, $1.2 million grant will permit Bruchas and his team to develop specialized, optically sensitive G-protein-coupled receptors on brain cells that will make it possible to control cell signaling in the brain with light. Combining these new receptor tools with wireless micro-LED devices implanted in the mouse brain should allow the researchers to uncover more information about molecular and cellular events that underlie stress, addiction and depression.
Bruchas_secondary[/caption] For example, Bruchas hopes to isolate and map the brain networks involved in stress by studying how mice interact in their cages. A dominant mouse may limit a cagemate from moving about freely, creating stress that may be apparent in the mouse’s brain networks.
Although many scientists use optogenetic techniques to isolate pathways in the mouse brain, often those animals are tethered to wires. Bruchas and his colleagues have the advantage of studying animals that are able to move freely because the LED devices that he and his colleagues have developed are portable and wireless. With funding from the EUREKA grant, his team plans to make them even smaller and add sensing capabilities to measure dynamic changes in the brain’s chemical transmission.
The EUREKA grant is part of a program by the National Institutes of Health (NIH) to fund exceptionally innovative research projects enabling the establishment of novel concepts and approaches to solve important problems or open new areas for investigation.
Washington University School of Medicine’s 2,100 employed and volunteer faculty physicians also are the medical staff of Barnes-Jewish and St. Louis Children’s hospitals. The School of Medicine is one of the leading medical research, teaching and patient care institutions in the nation, currently ranked sixth in the nation by U.S. News & World Report. Through its affiliations with Barnes-Jewish and St. Louis Children’s hospitals, the School of Medicine is linked to BJC HealthCare.
NIH award funds research into tiny LED devices that shine light on brain disorders
NIH award funds research into tiny LED devices that shine light on brain disorders https://www.kiwilighting.com/blog/nih-award-funds-research-tiny-led-devices-shine-light-brain-disorders/ To better understand and one day provide improved treatments for depression, addiction and anxiety, researchers at Washington University School of Medicine in St. Louis are using tiny, electronic devices to identify and map neural circuits in the brain. Wireless micro-LED devices are allowing...
NIH award funds research into tiny LED devices that shine light on brain disorders
To better understand and one day provide improved treatments for depression, addiction and anxiety, researchers at Washington University School of Medicine in St. Louis are using tiny, electronic devices to identify and map neural circuits in the brain.
Portable optogenetic LED device[/caption]
The innovative work has been recognized with a rare grant called EUREKA (Exceptional, Unconventional Research Enabling Knowledge Acceleration) that funds high-risk/high-reward projects. The National Institutes of Health (NIH) supports 12 to 18 such grants each year.
With the award, Michael R. Bruchas, PhD, assistant professor of anesthesiology, and his colleagues will conduct studies with micro-LED devices that his group recently co-developed with a team at the University of Illinois in Urbana-Champaign.
The work is part of the developing field of optogenetics, which uses advances in optics and genetics to control individual brain cells. For example, scientists can take a light-activated gene targeted at a particular type of neuron and insert the gene into a mouse. It then becomes possible to shine light into the animal’s brain either to get neurons to fire or to inhibit their activity.
In a recent study, Bruchas and his colleagues used the tiny electronic devices, which are thinner than a human hair, to tap into the internal reward system of mice, prodding their neurons to release dopamine, a chemical associated with pleasure, when the mice poked their noses through a hole in a particular part of a maze.
“Optogenetics allows us to zero in on specific populations of neurons and understand which ones are involved in complex behaviors,” Bruchas said. “What we learn from these studies will make it possible for us to target specific populations of brain cells that malfunction in depression, pain, addiction and other disorders.” The four-year, $1.2 million grant will permit Bruchas and his team to develop specialized, optically sensitive G-protein-coupled receptors on brain cells that will make it possible to control cell signaling in the brain with light. Combining these new receptor tools with wireless micro-LED devices implanted in the mouse brain should allow the researchers to uncover more information about molecular and cellular events that underlie stress, addiction and depression.
Bruchas_secondary[/caption] For example, Bruchas hopes to isolate and map the brain networks involved in stress by studying how mice interact in their cages. A dominant mouse may limit a cagemate from moving about freely, creating stress that may be apparent in the mouse’s brain networks.
Although many scientists use optogenetic techniques to isolate pathways in the mouse brain, often those animals are tethered to wires. Bruchas and his colleagues have the advantage of studying animals that are able to move freely because the LED devices that he and his colleagues have developed are portable and wireless. With funding from the EUREKA grant, his team plans to make them even smaller and add sensing capabilities to measure dynamic changes in the brain’s chemical transmission.
The EUREKA grant is part of a program by the National Institutes of Health (NIH) to fund exceptionally innovative research projects enabling the establishment of novel concepts and approaches to solve important problems or open new areas for investigation.
Washington University School of Medicine’s 2,100 employed and volunteer faculty physicians also are the medical staff of Barnes-Jewish and St. Louis Children’s hospitals. The School of Medicine is one of the leading medical research, teaching and patient care institutions in the nation, currently ranked sixth in the nation by U.S. News & World Report. Through its affiliations with Barnes-Jewish and St. Louis Children’s hospitals, the School of Medicine is linked to BJC HealthCare.