Government-Owned Inventions; Availability for Licensing, 22109-22110 [2011-9571]
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<![CDATA[
Federal Register / Vol. 76, No. 76 / Wednesday, April 20, 2011 / Notices
Dated: April 13, 2011.
Vivian Horovitch-Kelley,
NCI Project Clearance Liaison, National
Institutes of Health.
Publications:
1. Baek SJ, Okazaki R, Lee SH, Martinez J,
Kim JS, Yamaguchi K, Mishina Y, Martin
DW, Shoieb A, McEntee MF, Eling TE.
Nonsteroidal anti-inflammatory drug
activated gene-1 overexpression in
transgenic mice suppresses intestinal
neoplasia. Gastroenterology. 2006
Nov;131(5):1553–1560. [PubMed:
17101328]
2. Cekanova M, Lee SH, Donnell RL,
Sukhthankar M, Eling TE, Fischer SM,
Baek SJ. Nonsteroidal anti-inflammatory
drug-activated gene-1 expression inhibits
urethane-induced pulmonary
tumorigenesis in transgenic mice. Cancer
Prev Res (Phila). 2009 May;2(5):450–458.
[PubMed: 19401523]
[FR Doc. 2011–9509 Filed 4–19–11; 8:45 am]
BILLING CODE 4140–01–P
DEPARTMENT OF HEALTH AND
HUMAN SERVICES
National Institutes of Health
Government-Owned Inventions;
Availability for Licensing
National Institutes of Health,
Public Health Service, HHS.
ACTION: Notice.
AGENCY:
The inventions listed below
are owned by an agency of the U.S.
Government and are available for
licensing in the U.S. in accordance with
35 U.S.C. 207 to achieve expeditious
commercialization of results of
federally-funded research and
development. Foreign patent
applications are filed on selected
inventions to extend market coverage
for companies and may also be available
for licensing.
ADDRESSES: Licensing information and
copies of the U.S. patent applications
listed below may be obtained by writing
to the indicated licensing contact at the
Office of Technology Transfer, National
Institutes of Health, 6011 Executive
Boulevard, Suite 325, Rockville,
Maryland 20852–3804; telephone: 301/
496–7057; fax: 301/402–0220. A signed
Confidential Disclosure Agreement will
be required to receive copies of the
patent applications.
SUMMARY:
srobinson on DSKHWCL6B1PROD with NOTICES
NAG–1 Transgenic Mouse Model
Description of Technology: The
nonsteroidal anti-inflammatory drugactivated gene-1 (NAG–1) encodes a
protein that has anti-inflammatory,
proapoptotic, and antitumor properties.
It plays a pivotal role in
antitumorigenesis induced by
chemopreventive compounds.
Transgenic mice expressing human
NAG–1 have been developed by the NIH
investigator and collaborator.
The NAG–1 transgenic mice are
shown to develop few tumors in
response to carcinogenic stimuli than
wild type mice. They are also leaner
with less fat than their wild type
counterparts. As such, these mice can be
used to investigate the development of
cancers, and they could be of value in
studying obesity and the relationship to
cancer risk, and inflammation.
Inventors: Thomas E. Eling (NIEHS),
et al.
VerDate Mar<15>2010
17:52 Apr 19, 2011
Jkt 223001
Patent Status: HHS Reference No. E–
093–2011/0—Research Tool. Patent
protection is not being pursued for this
technology.
Licensing Status: Available for
licensing under a Biological Materials
License Agreement.
Licensing Contact: Betty B. Tong,
PhD; 301–594–6565;
tongb@mail.nih.gov.
Collaborative Research Opportunity:
The NIEHS is seeking statements of
capability or interest from parties
interested in collaborative research to
further develop, evaluate, or
commercialize this technology. Please
contact Elizabeth M. Denholm, NIEHS
Office of Technology Transfer,
denholme@niehs.nih.gov, 919–541–
0981, for more information.
Altered miRNA Expression as
Diagnostics and Therapeutics for
Adrenocortical Carcinomas
Description of Technology: This
technology describes that altered human
miRNA expression such as miRNA–483
and miRNA 100 can accurately predict
if a patient’s adrenal cortex tumor is
benign or malignant. Adrenocortical
carcinomas (ACC) are rare but
aggressive cancers and typically have a
poor prognosis. Currently, there are
limited options for molecular diagnosis
to distinguish malignant tumors from
benign tumors of this type. As a result
there are few treatment strategies for
ACC.
Additionally, preliminary results
suggest that altering the expression of
this miRNA in ACC cells can effect
cancer cell growth. Therefore, inhibiting
a miRNA may serve as a therapeutic
option for ACC.
Applications:
• Technology can be developed into a
diagnostic and prognostic marker for
ACC.
• Inhibiting miRNA can serve as a
potential therapeutics for ACC.
Advantages:
PO 00000
Frm 00035
Fmt 4703
Sfmt 4703
22109
• Distinguishes malignant Adrenal
cortex tumor from a benign tumor,
options for such distinction are limited
at this time.
• Technology can help in increased
and improved diagnosis and therapeutic
options for ACC.
Development Status:
• Pre-clinical.
• Clinical study to test the markers in
biopsy and serum samples being
planned.
Inventors: Electron Kebebew (CCR,
NCI) and Erin E. Patterson (CCR, NCI)
Publication: Patterson E. E. et al.
(Cancer, 2010). [PubMed: 21061324]
Patent Status: U.S. Provisional
Application No. 12/961,298 filed
December 6, 2010 (HHS Reference No.
E–026–2011/0–US–01)
Licensing Status: Available for
licensing.
Licensing Contact: Sabarni Chatterjee,
PhD, M.B.A.; 301–435–5587;
chatterjeesa@mail.nih.gov
Collaborative Research Opportunity:
The Center for Cancer Research, Surgery
Branch, is seeking statements of
capability or interest from parties
interested in collaborative research to
further develop, evaluate, or
commercialize the use of diagnostic
miRNAs and to target these miRNAs for
treatment. Please contact John Hewes,
PhD at 301–435–3121 or
hewesj@mail.nih.gov for more
information.
Novel Inhibitors of Thymic Stromal
Lymphopoietin (TSLP) for Cancer
Therapy
Description of Technology: With
estimated overall costs in the U.S. in
2006 at $206.3 billion and WHO
predictions of 15 million new cases
globally by 2020, the overall economic
cost of cancer is staggering. There
remains a significant unmet need for
therapies to control the spread
(metastasis) of cancers to other organs in
the body. Available for licensing are
compositions and methods of using
antagonists of thymic stromal
lymphopoietin (TSLP) to prevent cancer
progression and metastasis.
TSLP, an IL–7-like type 1
inflammatory cytokine that is often
associated with the induction of Th2type allergic responses in the lungs, is
also expressed in cancers regulating
their escape (1–3). The cancerpromoting activity of TSLP primarily
required signaling through the TSLP
receptor on CD4+ T cells, promoting
Th2-skewed immune responses and
production of immunosuppressive
factors such as IL–10 and IL–13.
Expression of TSLP therefore may be a
useful prognostic marker and its
E:\FR\FM\20APN1.SGM
20APN1
srobinson on DSKHWCL6B1PROD with NOTICES
22110
Federal Register / Vol. 76, No. 76 / Wednesday, April 20, 2011 / Notices
targeting could have therapeutic
potential. Inactivation of TSLP
expression or its receptor signaling can
effectively control cancer progression
and metastasis (1).
Applications:
• In treatments to control cancer
invasion and spreading
• Cancer treatment that circumvents
cancer-induced immune suppression
• As a means to augment anti-tumor
immune responses
• For the development of prognostic
markers for disease outcome in cancer
patients
Inventors: Arya Biragyn (NIA), Warren
J. Leonard (NHLBI)
Relevant Publications:
1. Olkhanud PB, Rochman Y, Bodogai
M, Malchinkhuu E, Wejksza K, Xu M,
Gress RE, Hesdorffer C, Leonard WJ,
Biragyn A. Thymic stromal
lymphopoietin is a key mediator of
breast cancer progression. J Immunol.
2011;V:186, In Press.
2. De Monte L, Reni M, Tassi E,
Clavenna D, Papa I, Recalde H, Braga M,
Di Carlo V, Doglioni C, Protti MP.
Intratumor T helper type 2 cell infiltrate
correlates with cancer-associated
fibroblast thymic stromal lymphopoietin
production and reduced survival in
pancreatic cancer. J Exp Med. 2011 Mar
14;208(3):469–478. [PubMed: 21339327]
3. Pedroza-Gonzalez A, Xu K, Wu TC,
Aspord C, Tindle S, Marches F, Gallegos
M, Burton EC, Savino D, Hori T, Tanaka
Y, Zurawski S, Zurawski G, Bover L, Liu
YJ, Banchereau J, Palucka AK. Thymic
stromal lymphopoietin fosters human
breast tumor growth by promoting type
2 inflammation. J Exp Med. 2011 Mar
14;208(3):479–490. [PubMed: 21339324]
Patent Status: U.S. Provisional
Application No. 61/416,619 filed
November 23, 2010 (HHS Reference No.
E–019–2011/0–US–01)
Licensing Status: Available for
licensing.
Licensing Contact: Patrick P. McCue,
PhD; 301–435–5560;
mccuepat@mail.nih.gov
Collaborative Research Opportunity:
The National Institute on Aging,
Immunotherapeutics Unit, is seeking
statements of capability or interest from
parties interested in collaborative
research to further develop, evaluate, or
commercialize clinical application of
TSLP in cancers. Please contact Nicole
Guyton, PhD at 301–435–3101 or
darackn@mail.nih.gov for more
information.
System and Method for Producing
Nondiffracting Light Sheets That
Improves the Performance of Selective
Plane Illumination Microscopy (SPIM)
Description of Technology: The
technology offered for licensing relates
VerDate Mar<15>2010
17:52 Apr 19, 2011
Jkt 223001
to a system and method of producing
nondiffracting beams of light that
spatially overlap, but do not interfere
with each other when intersecting the
detection plane of an optical
arrangement. The system includes an
illumination source (i.e., ultrafast laser)
for transmitting a beam of light through
the optical arrangement that includes a
diffraction grating for diffracting the
light beam to produce beams of light
having different wavelengths, which are
then passed through an annular aperture
that transforms the beams of light into
nondiffracting beams having different
wavelengths. The method can be readily
utilized in Selective Plane Illumination
Microscopy (SPIM), a system that
provides optical sectioning of a sample
that is labeled with fluorescent dyes.
SPIM can provide quantitative threedimensional maps of the distribution of
a flurophore within the sample with
high spatiotemporal resolution and an
excellent signal-to-noise ratio. The
standard SPIM technique however
produces nonuniform axial resolution,
which is caused by the diffraction of the
laser beam through the sample, causing
degradation in the optical sectioning,
and forcing a compromise between field
of view and axial resolution.
Techniques for decoupling field of view
and axial resolution have previously
utilized nondiffracting beams (e.g.,
Bessel beams) for sample illumination.
The resulting interference from multiple
nondiffracting beams degrades the
quality of optical sectioning and the
quality of the image. The present
technology utilizing nondiffracting
noninterfering beams is intended to
alleviate the problems associated with
the currently used SPIM techniques.
Applications: In Selective Plane
Illumination Microscopy (SPIM) used
for optical sectioning and imaging of
biological samples.
Development Status: Proof of concept
has been demonstrated.
Inventors: Andrew York, Yicong Wu,
Hari Shroff (NIBIB)
Relevant Publications:
1. Durnin J, Micheli J Jr, Eberly JH.
Diffraction-free beams. Phys Rev Lett.
1987 Apr 13;58(15):1499–1501.
2. Greger K, Swoger J, Stelzer EH. Basic
building units and properties of a
fluorescence single plane illumination
microscope. Rev Sci Instrum. 2007
Feb;78(2):023705. [PubMed: 17578115]
3. Fahrbach F, Rohrbach A. Microscopy with
Non-diffracting Beams. Abstract at 2009
Focus on Microscopy Conference, https://
www.focusonmicroscopy.org/2009/PDF/
28l_Fahrbach.pdf.
4. Rohrbach A. Artifacts resulting from
imaging in scattering media: a theoretical
prediction. Opt Lett. 2009 Oct
1;34(19):3041–3043. [PubMed:
PO 00000
Frm 00036
Fmt 4703
Sfmt 9990
19794809]
Patent Status: U.S. Provisional
Application No. 61/360,352 filed 30 Jun
2010, entitled ‘‘System and Method of
Producing Nondiffracting Light Sheets
by a Multiplicity of Spatially
Overlapping, Minimally Interfering
Nondiffracting Optical Beams’’ (HHS
Reference No. E–118–2010/0–US–01)
Licensing Status: Available for
licensing.
Licensing Contacts:
• Uri Reichman, PhD, MBA; 301–
435–4616; UR7a@nih.gov
• Michael Shmilovich, Esq.; 301–
435–5019; shmilovm@mail.nih.gov
Collaborative Research Opportunity:
The NIBIB Section on High Resolution
Optical Imaging is seeking statements of
capability or interest from parties
interested in collaborative research to
further develop, evaluate, or
commercialize the nondiffracting Light
Sheets for SPIM. Please contact Hari
Shroff at 301–435–1995 or
hari.shroff@nih.gov for more
information.
Dated: April 14, 2011.
Richard U. Rodriguez,
Director, Division of Technology Development
and Transfer, Office of Technology Transfer,
National Institutes of Health.
[FR Doc. 2011–9571 Filed 4–19–11; 8:45 am]
BILLING CODE 4140–01–P
DEPARTMENT OF HEALTH AND
HUMAN SERVICES
National Institutes of Health
National Institute of Environmental
Health Sciences; Amended Notice of
Meeting
Notice is hereby given of a change in
the meeting of the Board of Scientific
Counselors, NIEHS, March 20, 2011, 7
p.m. to March 22, 2011, 12:30 p.m.,
Doubletree Guest Suites, 2515 Meridian
Parkway, Research Triangle Park, NC,
27713 which was published in the
Federal Register on February 23, 2011,
76 FR 36.
This Federal Register Notice has been
amended to change the meeting date.
The meeting will be held Sunday, May
22, 2011 at 7 p.m. through Tuesday,
May 24, 2011 at 12:30 p.m. The meeting
is partially Closed to the public.
Dated: April 12, 2011.
Jennifer S. Spaeth,
Director, Office of Federal Advisory
Committee Policy.
[FR Doc. 2011–9492 Filed 4–19–11; 8:45 am]
BILLING CODE 4140–01–P
E:\FR\FM\20APN1.SGM
20APN1
]]>Agencies
[Federal Register Volume 76, Number 76 (Wednesday, April 20, 2011)]
[Notices]
[Pages 22109-22110]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: 2011-9571]
-----------------------------------------------------------------------
DEPARTMENT OF HEALTH AND HUMAN SERVICES
National Institutes of Health
Government-Owned Inventions; Availability for Licensing
AGENCY: National Institutes of Health, Public Health Service, HHS.
ACTION: Notice.
-----------------------------------------------------------------------
SUMMARY: The inventions listed below are owned by an agency of the U.S.
Government and are available for licensing in the U.S. in accordance
with 35 U.S.C. 207 to achieve expeditious commercialization of results
of federally-funded research and development. Foreign patent
applications are filed on selected inventions to extend market coverage
for companies and may also be available for licensing.
ADDRESSES: Licensing information and copies of the U.S. patent
applications listed below may be obtained by writing to the indicated
licensing contact at the Office of Technology Transfer, National
Institutes of Health, 6011 Executive Boulevard, Suite 325, Rockville,
Maryland 20852-3804; telephone: 301/496-7057; fax: 301/402-0220. A
signed Confidential Disclosure Agreement will be required to receive
copies of the patent applications.
NAG-1 Transgenic Mouse Model
Description of Technology: The nonsteroidal anti-inflammatory drug-
activated gene-1 (NAG-1) encodes a protein that has anti-inflammatory,
proapoptotic, and antitumor properties. It plays a pivotal role in
antitumorigenesis induced by chemopreventive compounds. Transgenic mice
expressing human NAG-1 have been developed by the NIH investigator and
collaborator.
The NAG-1 transgenic mice are shown to develop few tumors in
response to carcinogenic stimuli than wild type mice. They are also
leaner with less fat than their wild type counterparts. As such, these
mice can be used to investigate the development of cancers, and they
could be of value in studying obesity and the relationship to cancer
risk, and inflammation.
Inventors: Thomas E. Eling (NIEHS), et al.
Publications:
1. Baek SJ, Okazaki R, Lee SH, Martinez J, Kim JS, Yamaguchi K,
Mishina Y, Martin DW, Shoieb A, McEntee MF, Eling TE. Nonsteroidal
anti-inflammatory drug activated gene-1 overexpression in transgenic
mice suppresses intestinal neoplasia. Gastroenterology. 2006
Nov;131(5):1553-1560. [PubMed: 17101328]
2. Cekanova M, Lee SH, Donnell RL, Sukhthankar M, Eling TE, Fischer
SM, Baek SJ. Nonsteroidal anti-inflammatory drug-activated gene-1
expression inhibits urethane-induced pulmonary tumorigenesis in
transgenic mice. Cancer Prev Res (Phila). 2009 May;2(5):450-458.
[PubMed: 19401523]
Patent Status: HHS Reference No. E-093-2011/0--Research Tool.
Patent protection is not being pursued for this technology.
Licensing Status: Available for licensing under a Biological
Materials License Agreement.
Licensing Contact: Betty B. Tong, PhD; 301-594-6565;
tongb@mail.nih.gov.
Collaborative Research Opportunity: The NIEHS is seeking statements
of capability or interest from parties interested in collaborative
research to further develop, evaluate, or commercialize this
technology. Please contact Elizabeth M. Denholm, NIEHS Office of
Technology Transfer, denholme@niehs.nih.gov, 919-541-0981, for more
information.
Altered miRNA Expression as Diagnostics and Therapeutics for
Adrenocortical Carcinomas
Description of Technology: This technology describes that altered
human miRNA expression such as miRNA-483 and miRNA 100 can accurately
predict if a patient's adrenal cortex tumor is benign or malignant.
Adrenocortical carcinomas (ACC) are rare but aggressive cancers and
typically have a poor prognosis. Currently, there are limited options
for molecular diagnosis to distinguish malignant tumors from benign
tumors of this type. As a result there are few treatment strategies for
ACC.
Additionally, preliminary results suggest that altering the
expression of this miRNA in ACC cells can effect cancer cell growth.
Therefore, inhibiting a miRNA may serve as a therapeutic option for
ACC.
Applications:
Technology can be developed into a diagnostic and
prognostic marker for ACC.
Inhibiting miRNA can serve as a potential therapeutics for
ACC.
Advantages:
Distinguishes malignant Adrenal cortex tumor from a benign
tumor, options for such distinction are limited at this time.
Technology can help in increased and improved diagnosis
and therapeutic options for ACC.
Development Status:
Pre-clinical.
Clinical study to test the markers in biopsy and serum
samples being planned.
Inventors: Electron Kebebew (CCR, NCI) and Erin E. Patterson (CCR,
NCI)
Publication: Patterson E. E. et al. (Cancer, 2010). [PubMed:
21061324]
Patent Status: U.S. Provisional Application No. 12/961,298 filed
December 6, 2010 (HHS Reference No. E-026-2011/0-US-01)
Licensing Status: Available for licensing.
Licensing Contact: Sabarni Chatterjee, PhD, M.B.A.; 301-435-5587;
chatterjeesa@mail.nih.gov
Collaborative Research Opportunity: The Center for Cancer Research,
Surgery Branch, is seeking statements of capability or interest from
parties interested in collaborative research to further develop,
evaluate, or commercialize the use of diagnostic miRNAs and to target
these miRNAs for treatment. Please contact John Hewes, PhD at 301-435-
3121 or hewesj@mail.nih.gov for more information.
Novel Inhibitors of Thymic Stromal Lymphopoietin (TSLP) for Cancer
Therapy
Description of Technology: With estimated overall costs in the U.S.
in 2006 at $206.3 billion and WHO predictions of 15 million new cases
globally by 2020, the overall economic cost of cancer is staggering.
There remains a significant unmet need for therapies to control the
spread (metastasis) of cancers to other organs in the body. Available
for licensing are compositions and methods of using antagonists of
thymic stromal lymphopoietin (TSLP) to prevent cancer progression and
metastasis.
TSLP, an IL-7-like type 1 inflammatory cytokine that is often
associated with the induction of Th2-type allergic responses in the
lungs, is also expressed in cancers regulating their escape (1-3). The
cancer-promoting activity of TSLP primarily required signaling through
the TSLP receptor on CD4+ T cells, promoting Th2-skewed immune
responses and production of immunosuppressive factors such as IL-10 and
IL-13. Expression of TSLP therefore may be a useful prognostic marker
and its
[[Page 22110]]
targeting could have therapeutic potential. Inactivation of TSLP
expression or its receptor signaling can effectively control cancer
progression and metastasis (1).
Applications:
In treatments to control cancer invasion and spreading
Cancer treatment that circumvents cancer-induced immune
suppression
As a means to augment anti-tumor immune responses
For the development of prognostic markers for disease
outcome in cancer patients
Inventors: Arya Biragyn (NIA), Warren J. Leonard (NHLBI)
Relevant Publications:
1. Olkhanud PB, Rochman Y, Bodogai M, Malchinkhuu E, Wejksza K, Xu
M, Gress RE, Hesdorffer C, Leonard WJ, Biragyn A. Thymic stromal
lymphopoietin is a key mediator of breast cancer progression. J
Immunol. 2011;V:186, In Press.
2. De Monte L, Reni M, Tassi E, Clavenna D, Papa I, Recalde H,
Braga M, Di Carlo V, Doglioni C, Protti MP. Intratumor T helper type 2
cell infiltrate correlates with cancer-associated fibroblast thymic
stromal lymphopoietin production and reduced survival in pancreatic
cancer. J Exp Med. 2011 Mar 14;208(3):469-478. [PubMed: 21339327]
3. Pedroza-Gonzalez A, Xu K, Wu TC, Aspord C, Tindle S, Marches F,
Gallegos M, Burton EC, Savino D, Hori T, Tanaka Y, Zurawski S, Zurawski
G, Bover L, Liu YJ, Banchereau J, Palucka AK. Thymic stromal
lymphopoietin fosters human breast tumor growth by promoting type 2
inflammation. J Exp Med. 2011 Mar 14;208(3):479-490. [PubMed: 21339324]
Patent Status: U.S. Provisional Application No. 61/416,619 filed
November 23, 2010 (HHS Reference No. E-019-2011/0-US-01)
Licensing Status: Available for licensing.
Licensing Contact: Patrick P. McCue, PhD; 301-435-5560;
mccuepat@mail.nih.gov
Collaborative Research Opportunity: The National Institute on
Aging, Immunotherapeutics Unit, is seeking statements of capability or
interest from parties interested in collaborative research to further
develop, evaluate, or commercialize clinical application of TSLP in
cancers. Please contact Nicole Guyton, PhD at 301-435-3101 or
darackn@mail.nih.gov for more information.
System and Method for Producing Nondiffracting Light Sheets That
Improves the Performance of Selective Plane Illumination Microscopy
(SPIM)
Description of Technology: The technology offered for licensing
relates to a system and method of producing nondiffracting beams of
light that spatially overlap, but do not interfere with each other when
intersecting the detection plane of an optical arrangement. The system
includes an illumination source (i.e., ultrafast laser) for
transmitting a beam of light through the optical arrangement that
includes a diffraction grating for diffracting the light beam to
produce beams of light having different wavelengths, which are then
passed through an annular aperture that transforms the beams of light
into nondiffracting beams having different wavelengths. The method can
be readily utilized in Selective Plane Illumination Microscopy (SPIM),
a system that provides optical sectioning of a sample that is labeled
with fluorescent dyes. SPIM can provide quantitative three-dimensional
maps of the distribution of a flurophore within the sample with high
spatiotemporal resolution and an excellent signal-to-noise ratio. The
standard SPIM technique however produces nonuniform axial resolution,
which is caused by the diffraction of the laser beam through the
sample, causing degradation in the optical sectioning, and forcing a
compromise between field of view and axial resolution. Techniques for
decoupling field of view and axial resolution have previously utilized
nondiffracting beams (e.g., Bessel beams) for sample illumination. The
resulting interference from multiple nondiffracting beams degrades the
quality of optical sectioning and the quality of the image. The present
technology utilizing nondiffracting noninterfering beams is intended to
alleviate the problems associated with the currently used SPIM
techniques.
Applications: In Selective Plane Illumination Microscopy (SPIM)
used for optical sectioning and imaging of biological samples.
Development Status: Proof of concept has been demonstrated.
Inventors: Andrew York, Yicong Wu, Hari Shroff (NIBIB)
Relevant Publications:
1. Durnin J, Micheli J Jr, Eberly JH. Diffraction-free beams. Phys
Rev Lett. 1987 Apr 13;58(15):1499-1501.
2. Greger K, Swoger J, Stelzer EH. Basic building units and
properties of a fluorescence single plane illumination microscope.
Rev Sci Instrum. 2007 Feb;78(2):023705. [PubMed: 17578115]
3. Fahrbach F, Rohrbach A. Microscopy with Non-diffracting Beams.
Abstract at 2009 Focus on Microscopy Conference, https://www.focusonmicroscopy.org/2009/PDF/28l_Fahrbach.pdf.
4. Rohrbach A. Artifacts resulting from imaging in scattering media:
a theoretical prediction. Opt Lett. 2009 Oct 1;34(19):3041-3043.
[PubMed: 19794809]
Patent Status: U.S. Provisional Application No. 61/360,352 filed 30
Jun 2010, entitled ``System and Method of Producing Nondiffracting
Light Sheets by a Multiplicity of Spatially Overlapping, Minimally
Interfering Nondiffracting Optical Beams'' (HHS Reference No. E-118-
2010/0-US-01)
Licensing Status: Available for licensing.
Licensing Contacts:
Uri Reichman, PhD, MBA; 301-435-4616; UR7a@nih.gov
Michael Shmilovich, Esq.; 301-435-5019;
shmilovm@mail.nih.gov
Collaborative Research Opportunity: The NIBIB Section on High
Resolution Optical Imaging is seeking statements of capability or
interest from parties interested in collaborative research to further
develop, evaluate, or commercialize the nondiffracting Light Sheets for
SPIM. Please contact Hari Shroff at 301-435-1995 or hari.shroff@nih.gov
for more information.
Dated: April 14, 2011.
Richard U. Rodriguez,
Director, Division of Technology Development and Transfer, Office of
Technology Transfer, National Institutes of Health.
[FR Doc. 2011-9571 Filed 4-19-11; 8:45 am]
BILLING CODE 4140-01-P
