Update on Bridge12 and Dynamic nuclear polarisation (DNP)

Dear Randy,

This month's top viewed DNP literature and news articles from our blog: 

• Kobayashi, T., et al., Dynamic Nuclear Polarization Solid-State NMR in Heterogeneous Catalysis Research. ACS Catalysis, 2015. 5(12): p. 7055-7062
• Rossini, A.J., et al., High-resolution NMR of hydrogen in organic solids by DNP enhanced natural abundance deuterium spectroscopy. J Magn Reson, 2015. 259: p. 192-8
• Glyavin, M.Y., et al., Terahertz gyrotrons: State of the art and prospects. J. Commun. Technol. Electron., 2014. 59(8): p. 792-797

Other important news this month: 

Open Position at Bridge12
We are looking to expand our scientific team and are currently looking for a scientist with emphasize on magnetic resonance spectroscopy (DNP, EPR and NMR). For more information check out the job description.

Meet us at ENC in Pittsburgh, April 10-15
Bridge12 will be attending the Experimental Nuclear Magnetic Resonance Conference (ENC), April 10-15, 2016, in Pittsburgh. This will be the first time that we will have a small booth showcasing our products.

Have a great day, 

Thorsten Maly
Bridge12 Technolgies, Inc.

Agilent abandons NMR business

My Note: I was disappointed to learn that Agilent Technologies is giving up on the NMR line it was developing. I read about this on Thorston Maly's blog DNP-NMR Literature Blog. 

http://blog.bridge12.com

Dr. Maly noted:

C&EN, the magazine of the American Chemical Society had an interesting article about Agilent leaving the NMR business, that you can find here:

http://cen.acs.org/articles/92/i47/Agilent-Draws-AcademicsIre.html

Also, if you wanna read the open letter of the NMR community to Agilent, you can find it here:

http://cen.acs.org/content/dam/cen/static/pdfs/20141118-OpenlettertoAgilent.pdf

I had posted here about Bridge12's budding partnership with Agilent:

http://terahertztechnology.blogspot.com/2011/04/more-on-agilents-use-of-bridge12s-dnp.html

Stay tuned for new developments.

The DNP-NMR Blog- Bridge 12 latest news

Email not displaying correctly? View it in your browser. Dear Randy, this month's top viewed DNP literature and news articles from our blog:  Corzilius, B., et al., Paramagnet Induced Signal Quenching in MAS-DNP Experiments in Homogeneous Solutions. J. Magn. Reson., (0)..  Claytor, K., et al., Measuring long-lived (13)C2 state lifetimes at natural abundance. J Magn Reson, 2014. 239(0): p. 81-6. Thurber, K.R. and R. Tycko, On Mechanisms of Dynamic Nuclear Polarization in Solids. Israel Journal of Chemistry, 2013: p. n/a-n/a. Other important news this month: Meet us at ENC in Boston, March 23-28 Bridge12 will be attending the 55th Experimental Nuclear Magnetic Resonance Conference, March 23 - 28, 2014, in Boston, Massachusetts. If you'd like to meet up to discuss DNP NMR, simply reply to this email and let us know. Open position at Bridge12: Microwave and THz Systems Scientist We are again looking to expand our team. Check out our new job posting for a Microwave and Terahertz Scientist. More...   Meet Bridge12: Chris Hickey, Mechanical Design Co-op Please help us welcome Chris Hickey, our new Mechanical Design Co-op student, who is joining us from Northeastern University.    Have a great day, Thorsten Maly Bridge12 Technolgies, Inc.

New SBIR award to Bridge12 - NIH Funds Development of THz resonator for solid-state DNP-NMR Probes

Press Release

NIH Funds Development of THz resonator for solid-state DNP-NMR Probes

SBIR Grant Awarded to Bridge12 for Dynamic Nuclear Polarization

http://blog.bridge12.com/

Framingham, Mass. – July 18^th, 2013 – Bridge12 Technologies, a leading provider of terahertz (THz) technology for applications in science, medicine, security, and defense, announces it has received a National Institute of Health’s small business innovation research (SBIR) grant for the development of a THz resonator for solid-state DNP-NMR probes. Dynamic Nuclear Polarization (DNP) can increase the sensitivity of a NMR experiment by several orders of magnitude, accelerating experiments that typically require weeks to complete in minutes.

Nuclear magnetic resonance (NMR) spectroscopy is used broadly across many disciplines, such as analytical chemistry, structural biology or drug discovery and scientists that are using NMR are often challenged by the low sensitivity of NMR, which slows down research and increases research costs.

In recent years, Dynamic Nuclear Polarization (DNP) has proven to be vastly successful in increasing sensitivity in solid-state NMR experiments, achieving enhancement factors of > 180 at 400 MHz (¹H Larmor Frequency) corresponding to a factor of 32,400 in time savings. In other words, an experiment that would otherwise run for three weeks can be performed in less than a minute. This significantly increased overall sensitivity accelerates experiments for analytical applications of NMR spectroscopy as well as the structural characterization of bio-macromolecules or pharmaceutical drug discovery.

Abstract-Solid-State NMR on Bacterial Cells: Selective Cell Wall Signal Enhancement and Resolution Improvement using Dynamic Nuclear Polarization.

My Note: This is a repost from Dr. Thorsten Maly's blog, The DNP-NMR Blog
http://blog.bridge12.com/2013/02/solid-state-nmr-on-bacterial-cells.html
Takahashi, H., et al., Solid-State NMR on Bacterial Cells: Selective Cell Wall Signal Enhancement and Resolution Improvement using Dynamic Nuclear Polarization. J. Am. Chem. Soc., 2013.

http://dx.doi.org/10.1021/ja312501d

Dynamic nuclear polarization (DNP) enhanced solid-state nuclear magnetic resonance (NMR) has recently emerged as a powerful technique for the study of material surfaces. In this study, we demonstrate its potential to investigate cell surface in intact cells. Using Bacillus subtilis bacterial cells as an example, it is shown that the polarizing agent 1-(TEMPO-4-oxy)-3-(TEMPO-4-amino)propan-2-ol (TOTAPOL) has a strong binding affinity to cell wall polymers (peptidoglycan). This particular interaction is thoroughly investigated with a systematic study on extracted cell wall materials, disrupted cells, and entire cells, which proved that TOTAPOL is mainly accumulating in the cell wall. This property is used on one hand to selectively enhance or suppress cell wall signals by controlling radical concentrations and on the other hand to improve spectral resolution by means of a difference spectrum. Comparing DNP-enhanced and conventional solid-state NMR, an absolute sensitivity ratio of 24 was obtained on the entire cell sample. This important increase in sensitivity together with the possibility of enhancing specifically cell wall signals and improving resolution really opens new avenues for the use of DNP-enhanced solid-state NMR as an on-cell investigation tool.

Development and Applications of High—Frequency Gyrotrons in FIR FU Covering the sub-THz to THz Range

My Note: This interesting piece is taken from Doc Maly's blog "The DNP-NMR Blog"
http://blog.bridge12.com/

Idehara, T. and S. Sabchevski, Development and Applications of High—Frequency Gyrotrons in FIR FU Covering the sub-THz to THz Range. J. Infrared Millim. Te., 2012. 33(7): p. 667-694.

http://dx.doi.org/10.1007/s10762-011-9862-x

Powerful sources of coherent radiation in the sub-terahertz and in the terahertz frequency range of the electromagnetic spectrum are necessary for a great and continuously expanding number of applications in the physical research and in various advanced technological processes as well as in radars, communication systems, for remote sensing and inspection etc .. In recent years, a spectacular progress in the development of various gyro-devices and in particular of the powerful high frequency (sub-terahertz and terahertz) gyrotron oscillators has demonstrated a remarkable potential for bridging the so-called terahertz power gap and stimulated many novel and prospective applications. In this review paper we outline two series of such devices, namely the Gyrotron FU Series which includes pulsed gyrotrons and Gyrotron FU CW Series which consist of tubes operated in a CW (continuous wave) or long pulse mode, both developed at the FIR FU Center. We present the most remarkable achievements of these devices and illustrate their applications by some characteristic examples. An outlook for the further extension of the Gyrotron FU CW Series is also provided.

NIH Funds Bridge 12 in the First Commercialization of Solution-State DNP-NMR Probe

My Note: Big news for Bridge 12! Congrats to Doc Maly, and the Bridge 12 team.

NIH Funds First Commercialization of Solution-State DNP-NMR Probe

Bridge12, a leading provider of THz technology for applications in science, medicine, security, and defense, announces it has received the National Institute of Health’s first SBIR grant for the development of a solution-state DNP-NMR probe.

FOR IMMEDIATE RELEASE

http://www.prlog.org/11946432-nih-funds-first-commercialization-of-solution-state-dnp-nmr-probe.html

PRLog (Press Release) - Aug 13, 2012 -
Framingham, Mass. – August 13th, 2012 – Bridge12 Technologies, a leading provider of terahertz (THz) technology for applications in science, medicine, security, and defense, announces it has received the National Institute of Health’s first small business innovation research (SBIR) grant for the development and commercialization of a solution-state DNP-NMR probe.  Dynamic Nuclear Polarization (DNP) can increase the sensitivity of an NMR experiment by several orders of magnitude, accelerating experiments that typically require weeks to complete in minutes.  Unlike cryo-probes, which typically only yield a sensitivity increase of a factor of 3 or 4, the enhancements that are available through DNP are much larger (> 40).  This significantly increased overall sensitivity accelerates experiments for analytical applications of NMR spectroscopy as well as the structural characterization of bio-macromolecules or pharmaceutical drug discovery.

Nuclear magnetic resonance (NMR) spectroscopy is used broadly across many disciplines, such as analytical chemistry, structural biology or drug discovery.  Scientists using NMR are challenged by the low sensitivity of NMR, which slows down research and increases research costs.  Currently, the only commercially available options to increase sensitivity are cryo-probes, which typically yield a sensitivity improvement of no more than a factor of 4. In contrast, the technique of Dynamic Nuclear Polarization (DNP) has proven to be vastly more successful in increasing sensitivity in both solid- and solution-state NMR experiments, showing improvements of more than a factor of 40 (400 MHz, 1H Larmor Frequency).  The new Bridge12 research is focused on responding to this demand because researchers currently cannot take advantage of these enhancements due to the lack of commercially available DNP probes.

The first prototype will be designed to operate at an NMR spectrometer frequency of 300 MHz but the technology is expected to work at NMR frequencies even above 600 MHz.  The proposed probe can be retrofitted to existing NMR spectrometers, therefore preserving the significant investments in existing NMR platforms, and making the benefits of DNP-enhanced NMR spectroscopy available to a larger community.

The successful development of this technology will enable the rapid proliferation of DNP-enhanced solution-state NMR spectroscopy for structural biology, pharmaceutical research, and analytical chemistry.

“The biggest challenge of bringing the benefits of DNP to solution-state NMR spectroscopy is the extreme sample heating caused by the microwave/THz irradiation”

 says Dr. Thorsten Maly, a Bridge12 co-founder and principal investigator for the project. “At least two academic groups are currently developing microwave/THz resonators to overcome these heating problems and their approaches are based on conventional high-field EPR resonators that typically have very poor filling factors.  At Bridge12, we have developed a novel dielectric THz resonator that is compatible with current high-resolution, solution-state NMR probe designs, which is expected to accommodate sample volumes of several microliters.”



“Sensitivity has always been a major problem in NMR spectroscopy and DNP has more than proven itself in academic research, but the industry still lacks turn-key instrumentation,”

 says Dr. Jagadishwar Sirigiri, a Bridge12 founder and principal investigator for the project. “Through the use of DNP-NMR, researchers can increase the sensitivity of a NMR experiment by more than factor 40, breaking new ground and reducing experiment costs at the same time. We want to make DNP available to a larger community to fuel ideas that solve today's pressing issues in analytical chemistry, structural biology, drug research, and other areas.”

The SBIR grant was awarded from the National Institute of General Medicine (NIGMS), part of the National Institute of Health (NIH), in the amount of US$ 197,717 over a one-year period.

About Bridge12
Bridge12 Technologies develops terahertz technology for applications in science, medicine, security and defense.  Overcoming current technology barriers, the company closes the ‘terahertz gap’ with compact sources that are powerful, efficient, and rapidly deployable.  Bridge12 Technologies’

 solutions help accelerate scientific research, protect national security, and fight terminal diseases.

Bridge12 is a high-tech start-up founded by former scientists of the Massachusetts Institute of Technology (MIT).  Its scientific team has over a decade of expertise in high-frequency terahertz (THz) sources such as gyrotrons, microwave technology, and magnetic resonance spectroscopy.  The executive team combines know-how of over 3 decades in project management, information technology, health care, and consumer products.  For more information, visit www.bridge12.com.

THz Transmission Lines for DNP-NMR

My Note:This is a repost from Doc Maly's interesting blog,The DNP-NMR Blog
http://blog.bridge12.com/2012/04/thz-transmission-lines-for-dnp-nmr.html

A transmission line, linking the gyrotron (or solid-state) source to the NMR probe is an essential piece of THz instrumentation for DNP-NMR spectrometers. While quasi-optical transmission system have been used for setups using low-power solid-state sources, far more typical is the use of circular (corrugated) waveguides to deliver the THz power to the sample. Below is a list of two articles that have been published recently covering the topic of low-loss THz transmission lines for application in DNP-NMR spectroscopy:

Nanni, E., et al., Low-loss Transmission Lines for High-power Terahertz Radiation. J. Infrared Millim. Te., 2012: p. 1-20.
http://dx.doi.org/10.1007/s10762-012-9870-5

Bogdashov, A., et al., Transmission Line for 258 GHz Gyrotron DNP Spectrometry. J. Infrared Millim. Te., 2011. 32(6): p. 823-837.
http://dx.doi.org/10.1007/s10762-011-9787-4

Follow up to my end of the year post

Well, the year has certainly gotten off to a bang, and looking back at my comments on my end of the year post for 2011, they appear almost prescient, regarding API, and progress I anticipated it would make in the further penetration of the Industrial/Commercial THz market. In that post, I told readers that  "I’m optimistic that 2012 will be the year for API, that I had hoped 2011 would be." 


Yesterday's news about API selling industrial applications of it's T-Ray 4000, to two separate Fortune 500 companies, more than proved me right, but it certainly came much, much  sooner, and in a more grandiose fashion, than I  expected, or even hoped for.


What's exciting is that there are now 3 distinct, industrial applications of the T-Ray 4000, being used in 3 separate industries. In my opinion, it won't be long before that number will  in the thousands.  (If you follow the blog, you know that I've previously opined that I believe THz will provide the vehicle for a technological sea change in virtually every industry, and technological application we use today.)
The transformation is coming, and while API is trail-blazing a path for other terahertz companies, a number of the other THz pioneers will also get their fair share of the commercial bonanza I envision.  
http://terahertztechnology.blogspot.com/2011/01/terahertz-after-decades-of.html




The foregoing is just my opinion, and heaven knows, I've been wrong about the true state of the progress in THz before, so do your own diligence.

I also, wanted to share a new years comment, from Dr. Thorsten Maly from Bridge12 with readers which came early last week, and didn't make the original post. Thanks Doc! Please note that Doc Maly, publicly follows this blog, and hence will always get a plug for Bridge12, by me here. If you don't follow the blog,  please consider doing so, and please check out the Bridge12 newsletter, and blog, listed below.


Hi Randy,


Thanks for making us your top 3 pick of your 2011 top blog stories. I'm reading your blog with much interest and feeling really bad that I haven't commented yet either because the phone rings or I get another email I need to answer right away. Our prototype is coming along well and we hope that we are able to assemble the complete demo system at Agilent's facilities in Loveland in the next coming months.


Thanks again for mentioning us.
Cheers and Happy New Year,
Thorsten
**********************************************
Thorsten Maly
Bridge12 Technologies, Inc.
37 Loring Drive
Framingham, MA 01702, USA
Signup for our newsletter at
http://eepurl.com/M8yn
or follow our DNP-NMR blog at
http://hyperpolarization.blogspot.com/

Agilent Technologies to Develop 1-GHz NMR Spectrometer; Will Collaborate with Bridge12 Technologies on DNP Technology

MY NOTE: THIS IS EXCITING NEWS. CONGRATULATIONS TO THORSTEN MALY AND
JAGADISHWAR SIRIGIRL!
http://www.4-traders.com/ARGLNT-TECH-11488/news/ARGLNT-TECH-TRADE-NEWS-Agilent-Technologies-to-Develop-1-GHz-NMR-Spectrometer-Will-Collaborate-with--13599221/
Agilent Technologies Inc. (NYSE: A) today announced that it is developing a series of new ultra-high-field nuclear magnetic resonance (NMR) spectrometers at 850 MHz and 1GHz.
"Agilent Technologies is committed to working closely with our customers and partners to develop next-generation NMR technology," said Nick Roelofs, president of Agilent's Life Sciences Group. "The gigahertz project will leverage the company's full capabilities in magnet and probe design, electronic measurement and systems integration to deliver world class performance for researchers working to understand the structure and dynamics of macromolecules."
As part of its strategy to expand NMR applications, Agilent has also entered into a comarketing agreement with Bridge12 Technologies. Bridge12 is a provider of terahertz technology, a critical component for an emerging application known as dynamic nuclear polarization. DNP can significantly improve measurement sensitivity for solid-state samples. The co-marketing agreement enables the commercialization of DNP NMR systems, including Bridge12's terahertz gyrotron and transmission line system.
"The Bridge12 team is very excited about the collaboration with Agilent," said Dr. Jagadishwar Sirigiri, founder of Bridge12 Technologies. "Our gyrotrons for DNP-NMR systems are turnkey, low-maintenance, and designed specifically for the requirements of the NMR community."
These projects are significant milestones toward establishing Agilent as a technology leader in nuclear magnetic resonance. In addition to its expanded Center of Excellence in Santa Clara, Calif., the company is building an ultra-high-field demonstration facility at its Magnet Technology Centre in Yarnton, England. The Santa Clara center is currently open, while the facility in Yarnton will open in September. Both are designed to give customers hands-on experience with the newest NMR systems throughout the development process.
About Bridge12 Technologies
Bridge12 develops terahertz technology for applications in science, medicine, security and defense. Overcoming current technology barriers, the company closes the "terahertz gap" with compact sources that are powerful, efficient and rapidly deployable. Former scientists of the Massachusetts Institute of Technology founded the company, and its scientific team has over a decade of expertise in high-frequency terahertz sources such as gyrotrons. For more information, visit http://cts.businesswire.com/ct/CT?id=smartlink&url=http%3A%2F%2Fwww.bridge12.com&esheet=6677964&lan=en-US&anchor=www.bridge12.com&index=1&md5=8924b380660c35883394ab1571142c6f.
About Agilent Technologies
Agilent Technologies Inc. (NYSE: A) is the world's premier measurement company and a technology leader in chemical analysis, life sciences, electronics and communications. The company's 18,500 employees serve customers in more than 100 countries. Agilent had net revenues of $5.4 billion in fiscal 2010. Information about Agilent is available at http://cts.businesswire.com/ct/CT?id=smartlink&url=http%3A%2F%2Fwww.agilent.com&esheet=6677964&lan=en-US&anchor=www.agilent.com&index=2&md5=09164e5a6d97e81cc3b6cffd7cf6f9f5.
NOTE TO EDITORS: Further technology, corporate citizenship and executive news is available athttp://cts.businesswire.com/ct/CT?id=smartlink&url=http%3A%2F%2Fwww.agilent.com%2Fgo%2Fnews&esheet=6677964&lan=en-US&anchor=www.agilent.com%2Fgo%2Fnews&index=3&md5=104de590c05f08300d0e1759844e6c29.


Agilent Technologies Inc.
Stuart Matlow, +1-408-553-7191
stuart_matlow@agilent.com

 

Bridge12 Founders provide exclusive Questions and Answers to readers of Terahertz Technology, regarding Dynamic Nuclear Polarization, and about the company

(Co-Founders of Bridge12, Dr. Thorsten Maly, and Dr.Jagadishwar Sirigiri)

MY NOTE: The following are questions, I submitted to Dr. Thorsten Maly to consider answering to better explain to the lay community, precisely what Bridge12 does. Remarkably, he has been

generous enough to do, and here are the questions and answers. 







  Terahertz Technology Q&A

  Bridge12 Technologies, Inc. http://www.bridge12.com/  is a high-tech start-up formed by former scientists of the Massachusetts Institute of Technology (MIT). Its core expertise is in the area of high-frequency terahertz (THz) instrumentation for applications in Science, Medicine, Security and Defense, with its current focus on THz instrumentation for DNP-enhanced NMR spectroscopy. The company recently received a SBIR grant from the U.S. National Institutes of Health to develop a compact, cost-effective gyrotron system for DNP-enhanced solid-state NMR spectroscopy.

1. Why the name Bridge12?

  Many people ask us this question. Despite several valuable applications, the adoption of THz waves has been slow because of the limited output power of currently available THz sources. Today moderate size sources can only generate a few milliwatts of continuous wave (cw) power and therefore, systems employing such sources require sophisticated signal detection schemes. The lack of commercially available instrumentation (sources, detectors etc.) in the THz region led to the term “Terahertz Gap”.

  Bridge12 is committed to close this gap. Overcoming current technology barriers, we close the Terahertz Gap by providing compact, high-power, turn-key THz sources and instrumentation that are cost-effective, efficient and rapidly deployable.

2. What kind of products does Bridge12 offer?

  The gyrotron is our flagship product. Our unique, standardized tube design allows us to offer gyrotrons with a wide range of operating frequencies (100 GHz to 1 THz), large tuning bandwidth and high output-power (>10 W).

  Besides gyrotrons, we offer high-frequency, low-loss corrugated transmission lines and other THz components such as miterbends, waveguide adapters and extensions, power monitors and microwave windows. Furthermore, we offer a THz consulting services for customers that need advice for designing and developing THz systems for various applications.

3. What is a gyrotron and how does it work?

  A gyrotron is a vacuum electronic device (VED) capable to generate high-power, high-frequency THz radiation. Its operation is based on the stimulated cyclotron radiation of electrons oscillating in a strong magnetic field typically provided by a superconducting magnet.

  In a gyrotron, an electron beam is accelerated by a high voltage in a strong magnetic field of a superconducting magnet. While the electron beam travels through the intense magnetic field, the electrons follow a corkscrew trajectory (they gyrate) with a frequency given by the strength of the magnetic field. In the cavity, located at the position with the highest magnetic field strength, the THz radiation is generated and extracted by a waveguide. The spent electron beam is then dissipated in the collector.

4. What is so special about the Gyrotron?

  The gyrotron is a so-called fast-wave device because the dimension of its interaction structure is much larger compared to the wavelength of the radiation. This is in contrast to slow-wave device, which have interaction structures that are of the order of the wavelength of the generated radiation. However, especially at high frequencies, these interaction structures can be very small (sub millimeter) and therefore can easily burn out at the high power densities required to generate sufficient output power, significantly limiting the lifetime of the tube.

  Since gyrotrons are typically operated in a higher mode the interaction structure (cavity) can be much larger compared to the wavelength of the radiation. Furthermore, the cavity is typically a metal tube (copper) and can be effectively cooled, due to its simple structure. Therefore, the gyrotron can provide high output power, at high frequencies and guarantees a long lifetime.

5. What is the main application of your gyrotrons?

  In general, the gyrotron can be used in all scientific areas that require high-power, high-frequency THz radiation. At Bridge12 we are currently working on several applications in the area of science, medicine, security and defense. One application that currently gets a lot of attention is Dynamic Nuclear Polarization (DNP) for Structural Biology and herein the structure determination of bio-macromolecules by DNP-enhanced solid-state Nuclear Magnetic Resonance (NMR) spectroscopy.

6. What is Dynamic Nuclear Polarization?

  Currently NMR and X-ray crystallography are the two methods to determine structures of bio-macromolecules such as proteins and enzymes. These structures for example play an important role in the drug development process of the pharmaceutical industry. Briefly, in a NMR experiment, a sample is placed in a strong magnetic field and irradiated with intense radio frequency fields. When placed in a magnetic field, nuclei such as protons (¹H) or carbon nuclei (¹³C) absorb at a characteristic frequency, proportional to the strength of the external magnetic field. For example, at a magnetic field of 14 Tesla (2,800,000 times stronger than the earth’s magnetic field) protons resonate at a frequency of 900 MHz. Since the local magnetic fields at the position of the studied nuclei are very sensitive to their environment, small deviations of the resonance frequency (ppm regime), can be used to extract structural information about the surrounding of the nuclei. Furthermore, distance measurements between individual nuclei can provide geometrical information, which can be used to calculate molecular structures.

  However, NMR has a major drawback; due to the very small nuclear magnetic moment of the nuclei studied by NMR, the method is inherently insensitive. Therefore, NMR experiments to determine structures of large bio-macromolecules require several days to weeks of signal averaging to achieve an acceptable signal-to-noise ratio. In contrast, the magnetic moment of electrons is much larger, due its lower mass. For example, while for protons the characteristic absorption frequency at 14 Tesla is 600 MHz, the electron resonance frequency is 396 GHz at the same magnetic field strength. For NMR spectroscopy, larger magnetic moments (and polarization) translate directly into larger signal intensities. Therefore, transferring polarization from electrons to nuclei can greatly enhance signal intensities in NMR spectroscopy and dramatically reduce acquisition times in NMR experiments.

  Dynamic Nuclear Polarization (DNP) can achieve such a polarization transfer by on-resonant microwave (terahertz) radiation. With DNP signal enhancements of factor 100 or larger can be achieved, resulting in factor 10,000 shorter acquisition times and experiments that typically require days to weeks of signal averaging periods can be performed in just minutes or hours.

7. Are there other applications for your gyrotron?

  Currently our main focus is on the development of compact and cost-effective gyrotrons for DNP-enhanced NMR spectroscopy. However, the same gyrotron can be used in several other applications that require high-frequency, high-power terahertz radiation. For example, it is known that certain cancer types have characteristic absorptions in the THz regime that can be used to distinguish cancer tissue from non-cancer tissue. Since current detection schemes rely on low-power THz sources only small areas can be scanned at a time. With much higher power levels available from a gyrotron source we envision whole-body scans that are currently not possible due to the lack of THz power. With sufficient power available, such whole-body scans could be performed in seconds. This is comparable to switching on a 500 W light bulb in the dark to inspect a room instead of relying on a small keychain flashlight. .

  This is just one application that we can imagine. In general we are providing the gyrotron sources for customers who require higher output power (several watts to several kW).

  A gyrotron does not need to be a large, bulky piece of equipment. The largest component of the system is the superconducting magnet. In most research labs, gyrotron-based applications have magnets that typically have large fringe fields, which is basically dead-space. Our gyrotron however, are based on actively shielded magnets, with a 5 Gauss line very close to the outer dimension of the cryostat of the magnet. This makes our gyrotrons very compact and easily deployable even in crowded NMR facilities or factory areas.

8. Are there any plans for taking the company public?

  Bridge12 is a young start-up. We are currently developing our first prototypes to demonstrate our vision of compact and cost-effective gyrotron devices. We started the venture with seed funding from private investors, but currently have no plans to take the company public.

9. Which private or governmental organizations do you work with?

  Bridge12 recently received SBIR phase I funding from the U.S. National Institutes of Health for developing a gyrotron device for high-field DNP-enhanced solid-state NMR spectroscopy. Furthermore, we are regularly submitting new research proposals to government agencies for additional funding.

MY COMMENTS: It is so very exciting that such cutting edge technology and thought is being shared with us, here! Thank you again!