Government-Owned Inventions; Availability for Licensing, 56475-56477 [05-19173]
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Federal Register / Vol. 70, No. 186 / Tuesday, September 27, 2005 / Notices
SNH and taxol are synergistic at
inhibiting breast cell cancer growth and
can potentiate the cytotoxicity of taxol
in an in vivo human xenograft breast
cancer mouse model.
Combination therapy using these
agents may therefore greatly enhance
the response rate of different cancers to
these drugs and may significantly
reduce side effects by permitting a lower
therapeutic dose to be administered.
Available for licensing are compositions
of matter and methods of use of VIP
receptor antagonists.
Dated: September 15, 2005.
Steven M. Ferguson,
Director, Division of Technology Development
and Transfer, Office of Technology Transfer,
National Institutes of Health.
[FR Doc. 05–19172 Filed 9–26–05; 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:
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.
HIV-Encoded siRNA, microRNA and
Suppressor of RNA Silencing
Yamina Bennasser et al. (NIAID)
U.S. Provisional Application No. 60/
677,839 filed 05 May 2005 (HHS
Reference No. E–203–2005/0–US–01).
Licensing Contact: Susan Ano; 301/435–
5515; anos@mail.nih.gov.
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The present invention relates to virusencoded siRNA and miRNA species and
the use of such RNAs in the diagnosis,
prevention and/or treatment of
retroviral infection, especially HIV or
SIV infection. This invention conveys
the first evidence that HIV–1 encodes
viral siRNA precursors in its genome
and that natural HIV–1 infection
provokes nucleic acid-based immunity
in human cells. To overcome this
cellular defense, the HIV–1 Tat protein
has evolved to include a suppressor of
RNA silencing (SRS) function.
Additionally, this invention identifies
five microRNA (miRNA) precursor
candidates that regulate cellular gene
expression at a post-transcriptional
level. The five miRNA precursors (21–
25 nucleotides in length) are encoded in
highly conserved regions of HIV such as
TAR sequence, gag, pol and nef genes.
These findings indicate that viruses
utilize RNA interference as a
mechanism to regulate cellular gene
expression.
This technology is further described
in: Bennasser et al., ‘‘HIV–1 encoded
candidate micro-RNAs and their cellular
targets,’’ Retrovirology 2004 Dec 15,
1(1):43, doi:10.1186/1742–4690–1–43;
and Bennasser et al., ‘‘Evidence that
HIV–1 encodes an siRNA and a
suppressor of RNA silencing,’’
Immunity 2005 May, 22(5):607–619,
doi:10.1016/j.immuni.2005.03.010.
In addition to licensing, the
technology is available for further
development through collaborative
research opportunities with the
inventors.
Miniature Laser-Induced Fluorescence
Detector
Paul Smith, Nicole Morgan, Edward
Wellner, Terry Phillips (ORS)
U.S. Provisional Application No. 60/
682,847 filed 20 May 2005 (HHS
Reference No. E–129–2005/0–US–01).
Licensing Contact: Michael Shmilovich;
301/435–5019;
shmilovm@mail.nih.gov.
Available for licensing and
commercial development is a miniature
laser-induced fluorescence detector
having an in-line microfluidic detection
cell. The detection cell finds application
in High Performance Liquid
Chromatography (HPLC), Capillary
Electrophoresis (CE) and Mass
Spectroscopy (MS) applications, among
others. The cell for fluorescence
measurements can have a measurement
volume of 1 nL or less and a sample can
be excited using two excitation
wavelengths. The detection cell can
include a 5 mm to 5 cm long capillary
tube and an excitation fiber proximate
to the capillary tube. A detection fiber
PO 00000
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56475
is also proximate to the capillary tube,
and the detection fiber has a diameter
the same size or larger than the external
diameter of the capillary tube. A
plurality of both excitation and
detection fibers can be used.
In addition to licensing, the
technology may be available for further
development through collaborative
research opportunities with the
inventors.
Cellular Receptor for Varicella-Zoster
Virus and Cell-to-Cell Spread of Virus
Jeffery Cohen et al. (NIAID)
U.S. Provisional Application No. 60/
684,526 filed 26 May 2005 (HHS
Reference No. E–289–2004/0–US–01).
Licensing Contact: Chekesha S.
Clingman; 301/435–5018;
clingmac@mail.nih.gov.
This technology relates to
identification of insulin degrading
enzyme (IDE) as a cellular receptor for
Varicella-Zoster-Virus (VZV), the
etiologic agent of varicella (chickenpox)
and zoster (shingles). Acute infection of
VZV is followed by cell-associated
viremia and the development of
varicella rash. The virus establishes lifelong latency in the nervous system and
can reactivate to cause zoster. The
mechanism of VZV entry into target
cells and spread from cell-to-cell is not
well understood. The inventors have
shown that antibodies to IDE and
recombinant IDE partially inhibit
infection with the virus in cell culture.
Reducing the level of IDE in the cell
(with siRNA), or blocking the ability of
IDE to bind with a VZV glycoprotein,
markedly diminishes cell-to-cell spread
of the virus in cell culture and partially
inhibits infection of cells with cell-free
virus. This invention further describes
molecules that may have a role in the
treatment or prevention of VZV
infections, including antibodies to IDE,
peptides that block IDE–VZV
interactions, and other molecules that
block binding activity of IDE.
In addition to licensing, the
technology is available for further
development through collaborative
research opportunities with the
inventors.
A Novel Amplification Method Permits
Pathogens To Be Detected With
Microarrays
Michael J. Brownstein, Charles Xiang,
and Zhi-Qing Qi (NIMH)
U.S. Provisional Application No. 60/
635,239 filed 09 Dec 2004 (DHHS
Reference No. E–184–2004/0–US–01).
Licensing Contact: Cristina
Thalhammer-Reyero; 301/435–4507;
thalhamc@mail.nih.gov.
E:\FR\FM\27SEN1.SGM
27SEN1
56476
Federal Register / Vol. 70, No. 186 / Tuesday, September 27, 2005 / Notices
Available for licensing and
commercial development is a high
throughput, microarray-based multiplex
method of detecting target nucleic acids
in a sample. In particular, PCR is
coupled with microarrays for the
qualitative identification of multiple
target nucleic acids, with primers
specific for a target sequence, and used
to detect genomic nucleic acids of
pathogens of interest, or transcripts
derived therefrom. Also claimed are
oligonucleotide microarrays for use in
such methods.
The present method is distinguished
from other multiplex PCR assays by the
additional steps to ensure specificity
and sensitivity, so that a larger number
of probes can be detected
simultaneously in each single reaction.
An important application of this
method, for which it was developed, is
the detection of multiple ‘‘Category A
List’’ agents for the purpose of
differential diagnosis in case of
bioterrorism attacks. The method
comprises: (a) screening the genomes of
the desired infectious agents to find
sequences specific for each of them and
distinct from human sequences; (b)
designing 60 base long oligonucleotide
targets, to print on microarrays; and (c)
including in the microarrays both sense
and antisense versions of each, as well
multiple targets per virus, to increase
reliability.
Other methods, such as PCR
amplification followed by separation
and characterization of DNA products
by gel electrophoresis, are simple and
sensitive, but they have a number of
inherent shortcomings. Highly sensitive
PCR amplification tends to generate
nonspecific DNA products, which
complicate interpretation of the results.
Additionally, in a typical method for
detecting pathogens in a sample, PCR
reactions for each pathogen must be run
separately from one another due to
differences in amplification conditions.
Furthermore, in cases where multiplex
PCR coupled with a microarray is used
for the qualitative detection of several
pathogens, the generation of nonspecific
DNA products can be a significant
problem. The current method is a rapid,
high-throughput method for qualitative
identification of multiple target nucleic
acids that is sensitive, highly
discriminating and robust.
Methods for Treating Viral-Associated
Tumors With LFA–1 Inhibiting Statins
Jeffrey Cohen et al. (NIAID)
U.S. Provisional Application No. 60/
515,013 filed 28 Oct 2003 (HHS
Reference No. E–312–2003/0–US–01);
PCT Application No. PCT/US2004/
035829 (publication WO2005/042710)
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filed 28 Oct 2004 (HHS Reference No.
E–312–2003/0–PCT–02).
Licensing Contact: Susan Ano; 301/435–
5515; anos@mail.nih.gov.
This technology describes the use of
certain natural and synthetic statins,
including simvastatin, other leukocyte
function antigen-1 (LFA–1) inhibiting
statins, and compounds derived from
LFA–1 inhibiting statins and statin-like
compounds, for treatment or prevention
of Epstein-Barr Virus (EBV) associated
tumors, including lymphomas that
express LFA–1 and transforming
proteins. Such compounds could also be
used to treat tumors associated with
other viruses that express LFA–1.
Cancers associated with EBV that could
be treated with the statins by methods
described herein include gastric
carcinoma (the second leading cause of
cancer deaths worldwide),
nasopharyngeal carcinoma, Hodgkin’s
disease, lymphoproliferative disease, Tcell lymphoma, and non-Hodgkin’s
lymphoma. These compounds could
potentially be used as
chemotherapeutics with possibly less
severe side effects than currently
employed chemotherapies.
This technology is further described
in: Katano et al., ‘‘Simvastatin induces
apoptosis of Epstein-Barr virus (EBV)transformed lymphoblastoid cell lines
and delays development of EBV
lymphomas,’’ PNAS, 2004 Apr 6,
101(14):4966–4971, doi 10.1073/
pnas.0401064101.
In addition to licensing, the
technology is available for further
development through collaborative
research opportunities with the
inventors.
Attenuated Human Parainfluenza Virus
(PIV) for Use as Live, Attenuated
Vaccines and as Vector Vaccines
U.S. Provisional Application No. 60/
643,310 filed 12 Jan 2005 (HHS
Reference No. E–295–2004/0–US–01)
Sheila M. Nolan et al. (NIAID)
and
U.S. Provisional Application No. 60/
412,053 filed 18 Sep 2002 (HHS
Reference No. E–092–2002/0–US–01);
U.S. Patent Application No. 10/
667,141 filed 18 Sep 2003 (HHS
Reference No. E–092–2002/0–US–02;
PCT Application No. PCT/US03/
29685 filed 18 Sep 2003, which
published as WO2004/027037 on 01
Apr 2004 (HHS Reference No. E–092–
2002/0–PCT–03), and National Stage
filed in Canada, Europe, Japan,
Australia, and India
Mario H. Skiadopoulos et al. (NIAID)
Licensing Contact: Susan Ano; 301/435–
5515; anos@mail.nih.gov.
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The identified technologies describe
self-replicating infectious recombinant
paramyxoviruses with one or more
attenuating mutations, such as a
separate variant polynucleotide
encoding a P protein and a separate
monocistronic polynucleotide encoding
a V protein, or at least one temperature
sensitive mutation and one nontemperature sensitive mutation.
Compositions and methods for
recovering, making and using the
infectious, recombinant
paramyxoviruses as described are also
included (e.g. recombinant human
parainfluenza virus type 2 (HPIV2)). In
addition, these inventions provide novel
tools and methods for introducing
defined, predetermined structural and
phenotypic changes into an infectious
HPIV2 candidate for use in
immunogenic compositions, including
live attenuated virus vaccines.
Furthermore, these inventions describe
the recombinant HPIV2 P+V can be used
to introduce attenuating mutations to
develop live attenuated virus vaccines.
The paramyxoviruses of the invention
are also useful as vectors for expressing
heterologous antigens (e.g. RSV, HMPV,
measles or mumps viruses) in an
immunogenic composition. As members
of the paramyxoviruses, HPIVs are
important pathogens causing severe
lower respiratory tract infections in
infants and young children. Despite
considerable efforts, there are currently
no parainfluenza virus vaccines
available.
Advantages of the subject
technologies to generate live attenuated
viruses or vectored vaccine candidates
via multiple mutations are the design of
safe and stable viral vaccine candidates.
Since two common vaccine
development approaches (viral subunit
vaccines and inactivated whole virus
preparations) elicited either short-lived,
inadequate immunity or unfavorable
immune responses, the identified
technologies provide a promising means
to develop vaccines against HPIVs and
other human pathogens. In addition,
live attenuated viruses are the most
promising candidate vaccines because
they induce both local and systemic
immunity and are efficacious even in
the presence of passively transferred
serum antibodies, the very situation
found in the target population of infants
with maternally derived antibodies.
In addition to licensing, the
technology is available for further
development through collaborative
research opportunities with the
inventors.
E:\FR\FM\27SEN1.SGM
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Federal Register / Vol. 70, No. 186 / Tuesday, September 27, 2005 / Notices
Imaging With Positron-Emitting
Taxanes as a Guide to Antitumor
Therapy
Jerry M. Collins, Raymond W. Klecker,
Lawrence Anderson (FDA)
U.S. Provisional Application No. 60/
155,061 filed 21 Sep 1999 (HHS
Reference No. E–263–1998/0–US–01);
U.S. Patent Application Nos. 10/
088,561 filed 19 Mar 2002 (HHS
Reference No. E–263–1998/0–US–03)
and 10/319,812 filed 16 Dec 2002
(HHS Reference No. E–263–1998/1–
US–01) are pending.
Licensing Contact: Michael Shmilovich;
(301) 435–5019;
shmilovm@mail.nih.gov.
Available for licensing and
commercial development is a method
for using positron-emitting compounds
to label taxane type drugs. This
invention also describes methods of
synthesizing these taxane type
compounds. Further, methods to guide
treatment of solid tumors, with labeled
taxanes, are also disclosed in the
present application. Advantages of
using this technology include: (1)
Avoidance of exposing patients to toxic
drugs that have no potential for benefit;
(2) ability to rapidly determine whether
a given tumor will be likely to respond
to a particular drug; and (3) the ability
to monitor the impact of various
dosages, schedules, and modulators for
delivery, in situ, at the actual tumor
under treatment conditions.
Additional information may be found
in: Ravert et al., ‘‘Radiosynthesis of
[ 11C]paclitaxel,’’ J Label Compd and
Radiopharm, 2002, 45(6):471–477.
Dated: September 15, 2005.
Steven M. Ferguson,
Director, Division of Technology Development
and Transfer, Office of Technology Transfer,
National Institutes of Health.
[FR Doc. 05–19173 Filed 9–26–05; 8:45 am]
BILLING CODE 4140–01–P
DEPARTMENT OF HEALTH AND
HUMAN SERVICES
National Institutes of Health
National Cancer Institute; Notice of
Closed Meeting
Pursuant to section 10(d) of the
Federal Advisory Committee Act, as
amended (5 U.S.C. Appendix 2), notice
is hereby given of the following
meeting.
The meeting will be closed to the
public in accordance with the
provisions set forth in sections
552b(c)(4) and 552b(c)(6), Title 5 U.S.C.,
as amended. The grant applications and
the discussions could disclose
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14:52 Sep 26, 2005
Jkt 205001
confidential trade secrets or commercial
property such as patentable material,
and personal information concerning
individuals associated with the grant
applications, the disclosure of which
would constitute a clearly unwarranted
invasion of personal privacy.
Name of Committee: National Cancer
Institute Special Emphasis Panel, Small
Grants Program for Cancer Epidemiology and
Cancer Research Small Grant Program.
Date: November 8–10, 2005.
Time: 8 a.m. to 5 p.m.
Agenda: To review and evaluate grant
applications.
Place: Doubletree Hotel & Executive
Meeting Center, 1750 Rockville Pike,
Regency Meeting Room, Rockville, MD
20852.
Contact Person: Mary Jane Slesinski, PhD,
Scientific Review Administrator, Special
Review and Resources Branch, DEA/NCI/
NIH, 6116 Executive Boulevard, Room 8045,
Bethesda, MD 20892, 301/594–1566,
slesinsm@mail.nih.gov
(Catalogue of Federal Domestic Assistance
Program Nos. 93.392, Cancer Construction;
93.393, Cancer Cause and Prevention
Research; 93.394, Cancer Detection and
Diagnosis Research; 93.395, Cancer
Treatment Research; 93.396, Cancer Biology
Research; 93.397, Cancer Centers Support;
93.398, Cancer Research Manpower; 93.399,
Cancer Control, National Institutes of Health,
HHS)
Dated: September 16, 2005.
Anthony M. Coelho, Jr.,
Acting Director, Office of Federal Advisory
Committee Policy.
[FR Doc. 05–19178 Filed 9–26–05; 8:45 am]
BILLING CODE 4140–01–M
DEPARTMENT OF HEALTH AND
HUMAN SERVICES
National Institutes of Health
National Cancer Institute; Notice of
Meeting
Pursuant to section 10(d) of the
Federal Advisory Committee Act, as
amended (5 U.S.C. Appendix 2), notice
is hereby given of the meeting of the
President’s Cancer Panel.
The meeting will be open to the pubic
as indicated below, with attendance
limited to space available. Individuals
who plan to attend and need special
assistance, such as sign language
interpretation or other reasonable
accommodations, should notify the
Contact Person listed below in advance
of the meeting.
Name of Committee: President’s Cancer
Panel.
Date: October 24, 2005.
Open: October 24, 2005, 8 a.m. to 5 p.m.
Agenda: Strategic Planning-Translating
Research Team Science/Clinical Research/
Infrastructure Needs.
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Place: Hotel Washington, 15th and
Pennsylvania Ave., NW., Washington, DC
20004.
Contact Person: Abby Sandler, PhD,
Executive Secretary, National Cancer
Institute, National Institutes of Health,
Building 6116, Room 212, 6116 Executive
Boulevard, Bethesda, MD 20892, 301–451–
9399.
Any interested person may file written
comments with the committee by forwarding
the comments to the Contact Person listed on
this notice. The comments should include
the name, address, telephone number and,
when applicable, the business or professional
affiliation of the interested person.
Information is also available on the
Institute’s/Center’s home page:
deainfo.nci.nih.gov/advisory/pcp/pcp.htm,
where an agenda and any additional
information for the meeting will be posted
when available.
(Catalogue of Federal Domestic Assistance
Program Nos. 93.392, Cancer Construction;
93.393, Cancer Cause and Prevention
Research; 93.394, Cancer Detection and
Diagnosis Research; 93.395, Cancer
Treatment Research; 93.396, Cancer Biology
Research; 93.397, Cancer Centers Support;
93.398, Cancer Research Manpower; 93.399,
Cancer Control, National Institutes of Health,
HHS)
Dated: September 16, 2005.
Anthony M. Coelho, Jr.,
Acting Director, Office of Federal Advisory
Committee Policy.
[FR Doc. 05–19179 Filed 9–26–05; 8:45am]
BILLING CODE 4140–01–M
DEPARTMENT OF HEALTH AND
SERVICES
National Institutes of Health
National Cancer Institute; Notice of
Closed Meeting
Pursuant to section 10(d) of the
Federal Advisory Committee Act, as
amended (5 U.S.C. Appendix 2), notice
is hereby given of the following
meeting.
The meeting will be closed to the
public in accordance with the public in
accordance with the provisions set forth
in sections 552b(c)(4) and 552b(c)(6),
Title 5 U.S.C., as amended. The contract
proposals and the discussions could
disclose confidential trade secrets or
commercial property such as patentable
material, and personal information
concerning individuals associated with
the contract proposals, the disclosure of
which would constitute a clearly
unwarranted invasion of personal
privacy.
Name of Committee: National Cancer
Institute Special Emphasis Panel, Clinical
Trial Data Collection Using Handheld
Technology.
Date: October 12, 2005.
E:\FR\FM\27SEN1.SGM
27SEN1
]]>Agencies
[Federal Register Volume 70, Number 186 (Tuesday, September 27, 2005)]
[Notices]
[Pages 56475-56477]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: 05-19173]
-----------------------------------------------------------------------
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.
HIV-Encoded siRNA, microRNA and Suppressor of RNA Silencing
Yamina Bennasser et al. (NIAID)
U.S. Provisional Application No. 60/677,839 filed 05 May 2005 (HHS
Reference No. E-203-2005/0-US-01).
Licensing Contact: Susan Ano; 301/435-5515; anos@mail.nih.gov.
The present invention relates to virus-encoded siRNA and miRNA
species and the use of such RNAs in the diagnosis, prevention and/or
treatment of retroviral infection, especially HIV or SIV infection.
This invention conveys the first evidence that HIV-1 encodes viral
siRNA precursors in its genome and that natural HIV-1 infection
provokes nucleic acid-based immunity in human cells. To overcome this
cellular defense, the HIV-1 Tat protein has evolved to include a
suppressor of RNA silencing (SRS) function. Additionally, this
invention identifies five microRNA (miRNA) precursor candidates that
regulate cellular gene expression at a post-transcriptional level. The
five miRNA precursors (21-25 nucleotides in length) are encoded in
highly conserved regions of HIV such as TAR sequence, gag, pol and nef
genes. These findings indicate that viruses utilize RNA interference as
a mechanism to regulate cellular gene expression.
This technology is further described in: Bennasser et al., ``HIV-1
encoded candidate micro-RNAs and their cellular targets,''
Retrovirology 2004 Dec 15, 1(1):43, doi:10.1186/1742-4690-1-43; and
Bennasser et al., ``Evidence that HIV-1 encodes an siRNA and a
suppressor of RNA silencing,'' Immunity 2005 May, 22(5):607-619,
doi:10.1016/j.immuni.2005.03.010.
In addition to licensing, the technology is available for further
development through collaborative research opportunities with the
inventors.
Miniature Laser-Induced Fluorescence Detector
Paul Smith, Nicole Morgan, Edward Wellner, Terry Phillips (ORS)
U.S. Provisional Application No. 60/682,847 filed 20 May 2005 (HHS
Reference No. E-129-2005/0-US-01).
Licensing Contact: Michael Shmilovich; 301/435-5019;
shmilovm@mail.nih.gov.
Available for licensing and commercial development is a miniature
laser-induced fluorescence detector having an in-line microfluidic
detection cell. The detection cell finds application in High
Performance Liquid Chromatography (HPLC), Capillary Electrophoresis
(CE) and Mass Spectroscopy (MS) applications, among others. The cell
for fluorescence measurements can have a measurement volume of 1 nL or
less and a sample can be excited using two excitation wavelengths. The
detection cell can include a 5 mm to 5 cm long capillary tube and an
excitation fiber proximate to the capillary tube. A detection fiber is
also proximate to the capillary tube, and the detection fiber has a
diameter the same size or larger than the external diameter of the
capillary tube. A plurality of both excitation and detection fibers can
be used.
In addition to licensing, the technology may be available for
further development through collaborative research opportunities with
the inventors.
Cellular Receptor for Varicella-Zoster Virus and Cell-to-Cell Spread of
Virus
Jeffery Cohen et al. (NIAID)
U.S. Provisional Application No. 60/684,526 filed 26 May 2005 (HHS
Reference No. E-289-2004/0-US-01).
Licensing Contact: Chekesha S. Clingman; 301/435-5018;
clingmac@mail.nih.gov.
This technology relates to identification of insulin degrading
enzyme (IDE) as a cellular receptor for Varicella-Zoster-Virus (VZV),
the etiologic agent of varicella (chickenpox) and zoster (shingles).
Acute infection of VZV is followed by cell-associated viremia and the
development of varicella rash. The virus establishes life-long latency
in the nervous system and can reactivate to cause zoster. The mechanism
of VZV entry into target cells and spread from cell-to-cell is not well
understood. The inventors have shown that antibodies to IDE and
recombinant IDE partially inhibit infection with the virus in cell
culture. Reducing the level of IDE in the cell (with siRNA), or
blocking the ability of IDE to bind with a VZV glycoprotein, markedly
diminishes cell-to-cell spread of the virus in cell culture and
partially inhibits infection of cells with cell-free virus. This
invention further describes molecules that may have a role in the
treatment or prevention of VZV infections, including antibodies to IDE,
peptides that block IDE-VZV interactions, and other molecules that
block binding activity of IDE.
In addition to licensing, the technology is available for further
development through collaborative research opportunities with the
inventors.
A Novel Amplification Method Permits Pathogens To Be Detected With
Microarrays
Michael J. Brownstein, Charles Xiang, and Zhi-Qing Qi (NIMH)
U.S. Provisional Application No. 60/635,239 filed 09 Dec 2004 (DHHS
Reference No. E-184-2004/0-US-01).
Licensing Contact: Cristina Thalhammer-Reyero; 301/435-4507;
thalhamc@mail.nih.gov.
[[Page 56476]]
Available for licensing and commercial development is a high
throughput, microarray-based multiplex method of detecting target
nucleic acids in a sample. In particular, PCR is coupled with
microarrays for the qualitative identification of multiple target
nucleic acids, with primers specific for a target sequence, and used to
detect genomic nucleic acids of pathogens of interest, or transcripts
derived therefrom. Also claimed are oligonucleotide microarrays for use
in such methods.
The present method is distinguished from other multiplex PCR assays
by the additional steps to ensure specificity and sensitivity, so that
a larger number of probes can be detected simultaneously in each single
reaction. An important application of this method, for which it was
developed, is the detection of multiple ``Category A List'' agents for
the purpose of differential diagnosis in case of bioterrorism attacks.
The method comprises: (a) screening the genomes of the desired
infectious agents to find sequences specific for each of them and
distinct from human sequences; (b) designing 60 base long
oligonucleotide targets, to print on microarrays; and (c) including in
the microarrays both sense and antisense versions of each, as well
multiple targets per virus, to increase reliability.
Other methods, such as PCR amplification followed by separation and
characterization of DNA products by gel electrophoresis, are simple and
sensitive, but they have a number of inherent shortcomings. Highly
sensitive PCR amplification tends to generate nonspecific DNA products,
which complicate interpretation of the results. Additionally, in a
typical method for detecting pathogens in a sample, PCR reactions for
each pathogen must be run separately from one another due to
differences in amplification conditions. Furthermore, in cases where
multiplex PCR coupled with a microarray is used for the qualitative
detection of several pathogens, the generation of nonspecific DNA
products can be a significant problem. The current method is a rapid,
high-throughput method for qualitative identification of multiple
target nucleic acids that is sensitive, highly discriminating and
robust.
Methods for Treating Viral-Associated Tumors With LFA-1 Inhibiting
Statins
Jeffrey Cohen et al. (NIAID)
U.S. Provisional Application No. 60/515,013 filed 28 Oct 2003 (HHS
Reference No. E-312-2003/0-US-01); PCT Application No. PCT/US2004/
035829 (publication WO2005/042710) filed 28 Oct 2004 (HHS Reference No.
E-312-2003/0-PCT-02).
Licensing Contact: Susan Ano; 301/435-5515; anos@mail.nih.gov.
This technology describes the use of certain natural and synthetic
statins, including simvastatin, other leukocyte function antigen-1
(LFA-1) inhibiting statins, and compounds derived from LFA-1 inhibiting
statins and statin-like compounds, for treatment or prevention of
Epstein-Barr Virus (EBV) associated tumors, including lymphomas that
express LFA-1 and transforming proteins. Such compounds could also be
used to treat tumors associated with other viruses that express LFA-1.
Cancers associated with EBV that could be treated with the statins by
methods described herein include gastric carcinoma (the second leading
cause of cancer deaths worldwide), nasopharyngeal carcinoma, Hodgkin's
disease, lymphoproliferative disease, T-cell lymphoma, and non-
Hodgkin's lymphoma. These compounds could potentially be used as
chemotherapeutics with possibly less severe side effects than currently
employed chemotherapies.
This technology is further described in: Katano et al.,
``Simvastatin induces apoptosis of Epstein-Barr virus (EBV)-transformed
lymphoblastoid cell lines and delays development of EBV lymphomas,''
PNAS, 2004 Apr 6, 101(14):4966-4971, doi 10.1073/pnas.0401064101.
In addition to licensing, the technology is available for further
development through collaborative research opportunities with the
inventors.
Attenuated Human Parainfluenza Virus (PIV) for Use as Live, Attenuated
Vaccines and as Vector Vaccines
U.S. Provisional Application No. 60/643,310 filed 12 Jan 2005 (HHS
Reference No. E-295-2004/0-US-01)
Sheila M. Nolan et al. (NIAID)
and
U.S. Provisional Application No. 60/412,053 filed 18 Sep 2002 (HHS
Reference No. E-092-2002/0-US-01); U.S. Patent Application No. 10/
667,141 filed 18 Sep 2003 (HHS Reference No. E-092-2002/0-US-02; PCT
Application No. PCT/US03/29685 filed 18 Sep 2003, which published as
WO2004/027037 on 01 Apr 2004 (HHS Reference No. E-092-2002/0-PCT-03),
and National Stage filed in Canada, Europe, Japan, Australia, and India
Mario H. Skiadopoulos et al. (NIAID)
Licensing Contact: Susan Ano; 301/435-5515; anos@mail.nih.gov.
The identified technologies describe self-replicating infectious
recombinant paramyxoviruses with one or more attenuating mutations,
such as a separate variant polynucleotide encoding a P protein and a
separate monocistronic polynucleotide encoding a V protein, or at least
one temperature sensitive mutation and one non-temperature sensitive
mutation. Compositions and methods for recovering, making and using the
infectious, recombinant paramyxoviruses as described are also included
(e.g. recombinant human parainfluenza virus type 2 (HPIV2)). In
addition, these inventions provide novel tools and methods for
introducing defined, predetermined structural and phenotypic changes
into an infectious HPIV2 candidate for use in immunogenic compositions,
including live attenuated virus vaccines. Furthermore, these inventions
describe the recombinant HPIV2 P+V can be used to introduce attenuating
mutations to develop live attenuated virus vaccines. The
paramyxoviruses of the invention are also useful as vectors for
expressing heterologous antigens (e.g. RSV, HMPV, measles or mumps
viruses) in an immunogenic composition. As members of the
paramyxoviruses, HPIVs are important pathogens causing severe lower
respiratory tract infections in infants and young children. Despite
considerable efforts, there are currently no parainfluenza virus
vaccines available.
Advantages of the subject technologies to generate live attenuated
viruses or vectored vaccine candidates via multiple mutations are the
design of safe and stable viral vaccine candidates. Since two common
vaccine development approaches (viral subunit vaccines and inactivated
whole virus preparations) elicited either short-lived, inadequate
immunity or unfavorable immune responses, the identified technologies
provide a promising means to develop vaccines against HPIVs and other
human pathogens. In addition, live attenuated viruses are the most
promising candidate vaccines because they induce both local and
systemic immunity and are efficacious even in the presence of passively
transferred serum antibodies, the very situation found in the target
population of infants with maternally derived antibodies.
In addition to licensing, the technology is available for further
development through collaborative research opportunities with the
inventors.
[[Page 56477]]
Imaging With Positron-Emitting Taxanes as a Guide to Antitumor Therapy
Jerry M. Collins, Raymond W. Klecker, Lawrence Anderson (FDA)
U.S. Provisional Application No. 60/155,061 filed 21 Sep 1999 (HHS
Reference No. E-263-1998/0-US-01); U.S. Patent Application Nos. 10/
088,561 filed 19 Mar 2002 (HHS Reference No. E-263-1998/0-US-03) and
10/319,812 filed 16 Dec 2002 (HHS Reference No. E-263-1998/1-US-01) are
pending.
Licensing Contact: Michael Shmilovich; (301) 435-5019;
shmilovm@mail.nih.gov.
Available for licensing and commercial development is a method for
using positron-emitting compounds to label taxane type drugs. This
invention also describes methods of synthesizing these taxane type
compounds. Further, methods to guide treatment of solid tumors, with
labeled taxanes, are also disclosed in the present application.
Advantages of using this technology include: (1) Avoidance of exposing
patients to toxic drugs that have no potential for benefit; (2) ability
to rapidly determine whether a given tumor will be likely to respond to
a particular drug; and (3) the ability to monitor the impact of various
dosages, schedules, and modulators for delivery, in situ, at the actual
tumor under treatment conditions.
Additional information may be found in: Ravert et al.,
``Radiosynthesis of [ 11C]paclitaxel,'' J Label Compd and
Radiopharm, 2002, 45(6):471-477.
Dated: September 15, 2005.
Steven M. Ferguson,
Director, Division of Technology Development and Transfer, Office of
Technology Transfer, National Institutes of Health.
[FR Doc. 05-19173 Filed 9-26-05; 8:45 am]
BILLING CODE 4140-01-P
