Government-Owned Inventions; Availability for Licensing, 27818-27821 [E7-9541]
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Capital Costs, Operating Costs and/or
Maintenance Costs to report.
Average Burden Hours Per Response:
.0.3674; and
Estimated Total Annual Burden
Hours Requested: 91.85.
The annualized cost to respondents is
estimated at: $5,218. There are no
The annual reporting burden is as
follows:
Estimated Number of Respondents:
250;
Estimated Number of Responses per
Respondent: 1;
A.12–1.—ESTIMATES OF HOUR BURDEN
Type of
respondents
Number of
respondents
Average time
per
response
Frequency of
response
Annual hour
burden
Physicians (internists) ......................................................................................
250
1
0.3674
91.85
Total ..........................................................................................................
250
........................
........................
91.85
Request for Comments: Written
comments and/or suggestions from the
public and affected agencies are invited
on one or more of the following points:
(1) Whether the proposed collection of
information is necessary for the proper
performance of the function of the
agency, including whether the
information will have practical utility;
(2) The accuracy of the agency’s
estimate of the burden of the proposed
collection of information, including the
validity of the methodology and
assumptions used; (3) Ways to enhance
the quality, utility, and clarity of the
information to be collected; and (4)
Ways to minimize the burden of the
collection of information on those who
are to respond, including the use of
appropriate automated, electronic,
mechanical, or other technological
collection techniques or other forms of
information technology.
To
request more information on the
proposed project or to obtain a copy of
the data collection plans and
instruments, contact Dr. Marion Danis,
Department of Clinical Bioethics,
Building 10, room 1C118, National
Institutes of Health, Bethesda, MD
20892, or call non-toll-free number 301–
435–8727 or e-mail your request,
including your address to:
mdanis@cc.nih.gov.
Comments Due Date: Comments
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FOR FURTHER INFORMATION CONTACT:
David K. Henderson,
Deputy Director, Warren G. Magnuson
Clinical Center, National Institutes of Health.
Ezekiel J. Emanuel,
Director, Department of Clinical Bioethics,
Warren G. Magnuson Clinical Center,
National Institutes of Health.
[FR Doc. E7–9543 Filed 5–16–07; 8:45 am]
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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.
Humanized Anti-Carcinoma CC49
Monoclonal Antibodies
Description of Technology: The
technology describes the humanization
of a murine anti-carcinoma antibody
CC49 which has been shown to react
with Tumor Associated Glycoprotein 72
(TAG–72), an antigen which is
expressed on human breast, ovarian,
colorectal, and other carcinomas.
The invention includes a new method
of humanization of a rodent antibody
which is based on grafting all the
Complementarity Determining Residues
(CDRs) of a rodent antibody onto a
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human antibody framework.
Additionally, the method identifies
Specificity Determining Residues
(SDRs), the amino acid residues in the
hypervariable regions of an antibody
that are most critical for antigen binding
activity and of rendering any antibody
minimally immunogenic in humans by
transferring the SDRs of the antibody to
a human antibody framework. The
resulting humanized antibodies,
including CDR variants thereof
(including a CH2 deleted version), are
also embodied in the invention, as are
methods of using the antibodies for
therapeutic and diagnostic purposes.
Furthermore, these antibodies are
suitable for radiolabeling for the
application in radioimmunotherapy
(RIT) based treatment of several cancers.
Phase I results of radioimmunotherapy
for ovarian cancer using 90Yttrium-CC49
murine monoclonal antibodies have
shown promising results and confirms
feasibility of the use of these antibodies
for RIT. Promising pharmacokinetic data
for the radiolabeled humanized
antibodies in colon carcinoma xenograft
models were recently published.
Applications and Modality
1. A humanized anti-cancer CC49
monoclonal antibody has been
developed.
2. New methods of humanization of
rodent antibodies have been identified.
3. The antibody(s) has been shown to
react with Tumor Associated
Glycoprotein 72 (TAG–72), an antigen
which is expressed on human breast,
ovarian, colorectal, and other
carcinomas.
4. These antibodies are suitable for
radiolabeling for the application in
radioimmunotherapy (RIT) based
treatment of several cancers.
5. These antibodies can be useful in
diagnosis and treatment of several
cancers.
Development Status: The technology
is currently in the pre-clinical stage of
development. Phase I results of
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radioimmunotherapy for ovarian cancer
using 90Yttrium-CC49 murine
monoclonal antibodies have shown
promising results and confirms
feasibility of the use of these antibodies
for radioimmunotherapy (RIT).
Inventors: Syed V. Kashmiri (NCI),
Eduardo A. Padlan (NIDDK), Jeffrey
Schlom (NCI).
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Publications
1. RD Alvarez et al. A Phase I study
of combined modality 90Yttrium-CC49
intraperitoneal radioimmunotherapy for
ovarian cancer. Clin Cancer Res. 2002
Sep; 8(9):2806–2811.
2. A Forero et al. A novel monoclonal
antibody design for
radioimmunotherapy. Cancer Biother
Radiopharm. 2003 Oct;18(5):751–759.
3. PC Chinn et al. Pharmacokinetics
and tumor localization of (111) inlabeled HuCC49DeltaC(H)2 in BALB/c
mice and athymic murine colon
carcinoma xenograft. Cancer Biother
Radiopharm. 2006 Apr;21(2):106–116.
Patent Status
1. U.S. Patent No. 6,818,749 issued
November 16, 2004 and U.S. Patent
Application 10/927,433 filed August 25,
2004 as well as issued and pending
foreign counterparts [HHS Ref. No. E–
259–1998];
2. European Patent No. 00365997
issued September 14, 1994 and its
counterpart in Japan [HHS Ref. Nos. D–
003–1992/0–EP–07 and D–003–1992/0–
JP–05];
3. U.S. Patent No. 5,472,693 issued
December 5, 1995 [HHS Ref. No. D–003–
1992/2–US–01];
4. U.S. Patent No. 6,051,225 issued
April 18, 2000 [HHS Ref. No. D–003–
1992/3–US–01];
5. U.S. Patent No. 5,993,813 issued
November 30, 1999 [HHS Ref. No. D–
003–1992/2–US–02];
6. U.S. Patent No. 6,641,999 issued
November 4, 2003 [HHS Ref. No. D–
003–1992/2–US–04];
7. European Patent No. 628078 issued
December 8, 1999 and its counterparts
in Japan, Canada and Australia [HHS
Ref. Nos. D–004–1992/0–EP–06, D–004–
1992/0–JP–03, D–004–1992/0–CA–04
and D–004–1992/0–AU–05];
8. U.S. Patent No. 5,877,291 issued
March 2, 1999 [HHS Ref. No. D–004–
1992/1–US–01];
9. U.S. Patent No. 5,892,020 issued
April 6, 1999 [HHS Ref. No. D–004–
1992/1–US–01] and its foreign
counterparts;
10. Taiwanese Patent No. 173667
issued July 10, 2003 [HHS Ref. No. D–
001–1996/0–TW–03];
11. U.S. Patent No. 6,737,060 issued
May 18, 2004 [HHS Ref. No. D–001–
1996/1–US–03];
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12. U.S. Patent No. 6,737,061 issued
May 18, 2004 [HHS Ref. No. D–001–
1996/1–US–04];
13. U.S. Patent No. 6,753,152 issued
June 22, 2004 [HHS Ref. No. D–001–
1996/1–US–05];
14. U.S. Patent No. 6,752,990 issued
June 22, 2004 [HHS Ref. No. D–001–
1996/1–US–06];
15. U.S. Patent No. 6,329,507 issued
December 11, 2001 [HHS Ref. No. D–
001–2006/0–US–01] and
16. U.S. Patent No. 6,071,515 issued
June 6, 2000 [HHS Ref. No. D–001–
2006/0–US–03].
Licensing Availability: Available for
exclusive and non-exclusive licensing.
Licensing Contact: Michelle Booden,
PhD.; 301/451–7337;
boodenm@mail.nih.gov
Collaborative Research Opportunity:
The National Cancer Institute’s
Laboratory of Tumor Immunology and
Biology is seeking statements of
capability or interest from parties
interested in collaborative research to
further develop, evaluate, or
commercialize anti-carcinoma
antibodies. Please contact John D.
Hewes, Ph.D. at 301–435–3121 or
hewesj@mail.nih.gov for more
information.
Enhanced T-cell Activation by
Costimulation: an Effective
Immunotherapy for Cancer and
Infectious Diseases
Description of Technology: Cancer
immunotherapy is a recent approach
where tumor associated antigens
(TAAs), which are primarily expressed
in human tumor cells and not expressed
or minimally expressed in normal
tissues, are employed to generate a
tumor specific immune response.
Specifically, these antigens serve as
targets for the host immune system and
elicit responses that result in tumor
destruction. The initiation of an
effective T-cell immune response to
antigens requires two signals. The first
one is antigen specific via the peptide/
major histocompatibility complex and
the second or ‘‘costimulatory’’ signal is
required for cytokine production,
proliferation, and other aspects of T-cell
activation.
The present technology describes
recombinant poxvirus vectors encoding
at least three or more costimulatory
molecules and TAAs. The use of three
costimulatory molecules such as B7.1,
ICAM–1 and LFA–3 (TRICOM) has
been shown to act in synergy with
several tumor antigens and antigen
epitopes to activate T cells. The effects
with TRICOM were significantly
greater than with one or two
costimulatory molecules. Laboratory
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results support the greater effect of
TRICOM to activate both CD4+ and
CD8+ T cells. The invention also
describes the use of at least one target
antigen or immunological epitope as an
immunogen or vaccine in conjunction
with TRICOM. The antigens include
but are not limited to carcinoembryonic
antigen (CEA), prostate-specific antigen
(PSA), and MUC–1.
The combination of CEA, MUC–1, and
TRICOM is referred to as PANVAC
and the combination of PSA and
TRICOM is referred to as PROSTVAC.
Licensing Availability: The technology
is available for exclusive and nonexclusive licensing in combinations and
for different fields of use. Some
potential licensing opportunities are as
follows:
1. TRICOM (alone or with a
transgene for a tumor antigen and/or an
immunostimulatory molecule);
2. The antigens only, including but
not limited to CEA, PSA, and MUC–1;
3. PANVAC and/or PROSTVAC;
and
4. Recombinant fowlpox-GM–CSF.
Application(s) and Modality: Vectorbased TRICOM (alone or with a
transgene for a tumor antigen and/or an
immunostimulatory molecule),
PANVAC and PROSTVAC and
combinations thereof can be a potential
novel immunotherapeutic approach for
the treatment of cancer and infectious
diseases.
Advantages
1. The technology is beyond proof-ofconcept, supported by laboratory results
and publications.
2. Phase I and Phase II clinical data
available.
3. Fewer validation studies are
required compared to other
immunotherapy related technologies.
Development Status: Phase I and
Phase II results available for poxvirus
recombinants containing transgenes for
TRICOM, CEA–TRICOM, PANVAC,
and PROSTVAC. Further clinical
studies are ongoing for other
combinations.
Inventors: Jeffrey Schlom (NCI) et al.
Publications
1. Kaufman HL, Cohen S, Cheung K,
DeRaffele, Mitcham J, Moroziewicz D,
Schlom J, and Hesdorffer C. Local
delivery of vaccinia virus expressing
multiple costimulatory molecules for
the treatment of established tumors.
Human Gene Ther. 17:239–244, 2006.
2. Kantoff PW GL, Tannenbaum SI,
Bilhartz DL, Pittman WG, Schuetz TJ.
Randomized, double-blind, vectorcontrolled study of targeted
immunotherapy in patients (pts) with
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hormone-refractory prostate cancer
(HRPC). 2006 ASCO Annual Meeting
Proceedings, Part I, abstract 2501. J Clin
Oncol.; 24.
3. Marshall J, Gulley JL, Arlen PM,
Beetham PK, Tsang KY, Slack R, Hodge
JW, Doren S, Grosenbach DW, Hwang J,
Fox E, Odogwa L, Park S, Panicali D,
Schlom J. A phase I study of sequential
vaccinations with fowlpox-CEA(6D)TRICOM (B7–1/ICAM–1/LFA–3) alone
and sequentially with vacciniaCEA(6D)-TRICOM, with and without
GM–CSF, in patients with CEAexpressing carcinomas. J Clin Oncol.
23:720–731, 2005.
4. Palena C, Foon KA, Panicali D,
Yafal AG, Chinsangaram J, Hodge JW,
Schlom J, and Tsang KY. A potential
approach to immunotherapy of chronic
lymphocytic leukemia (CLL): enhanced
immunogenicity of CLL cells via
infection with vectors encoding for
multiple costimulatory molecules.
Blood 106:3515–3523, 2005.
5. Gulley J, Todd N, Dahut W, Schlom
J, Arlen P. A phase II study of
PROSTVAC–VF vaccine, and the role of
GM–CSF, in patients (pts) with
metastatic androgen insensitive prostate
cancer (AIPC) [abstract]. J Clin Oncol.
2005; 23 (16S Pt 1): 2504.
6. Yang S, Hodge JW, Grosenbach DW,
and Schlom J. Vaccines with enhanced
costimulation maintain high avidity
memory CTL. J. Immunol. 175:3715–
3723, 2005.
7. Yang S, Tsang KY, and Schlom J.
Induction of higher avidity human CTL
by vector-mediated enhanced
costimulation of antigen-presenting
cells. Clin Cancer Res. 11:5603–5615,
2005.
8. Hodge JW, Chakraborty M, KudoSaito C, Garnett CT, Schlom J. Multiple
costimulatory modalities enhance CTL
avidity. J Immunol. 174:5994–6004,
2005.
9. Tsang K–Y, Palena C, Yokokawa J,
Arlen PM, Gulley JL, Mazzara GP, Gritz
´
L, Gomez Yafal A, Ogueta S, Greenhalgh
P, Manson K, Panicali D, and Schlom J.
Analyses of recombinant vaccinia and
fowlpox vaccine vectors expressing
transgenes for two human tumor
antigens and three human costimulatory
molecules. Clin Cancer Res. 11:1597–
1607, 2005.
10. Chakraborty M, Abrams SI,
Coleman CN, Camphausen K, Schlom J,
Hodge JW. External beam radiation of
tumors alters phenotype of tumor cells
to render them susceptible to vaccinemediated T-cell killing. Cancer Res.
64:4328–4337, 2004.
11. Zeytin HE, Patel AC, Rogers CJ, et
al. Combination of a poxvirus-based
vaccine with a cyclooxygenase-2
inhibitor (celecoxib) elicits antitumor
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immunity and long-term survival in
CEA.Tg/MIN mice. Cancer Res.
64:3668–3678, 2004.
12. Palena C, Zhu M–Z, Schlom J, and
Tsang K–Y. Human B cells that
hyperexpress a triad of costimulatory
molecules via avipoxvector infection: an
alternative source of efficient antigenpresenting cells. Blood 104:192–199,
2004.
13. Kudo-Saito C, Schlom J, and
Hodge JW. Intratumoral vaccination and
diversified subcutaneous/intratumoral
vaccination with recombinant
poxviruses encoding a tumor antigen
and multiple costimulatory molecules.
Clin Cancer Res. 10:1090–1099, 2004.
14. Hodge JW, Poole DJ, Aarts WM,
Gomez Yafal A, Gritz L, and Schlom J.
Modified vaccinia virus ankara
recombinants are as potent as vaccinia
recombinants in diversified prime and
boost vaccine regimens to elicit
therapeutic antitumor responses. Cancer
Res. 63:7942–7949, 2003.
15. Hodge JW, Grosenbach DW, Aarts
Wm, Poole DJ, and Schlom J. Vaccine
therapy of established tumors in the
absence of autoimmunity. Clin Cancer
Res. 9:1837–1849, 2003.
16. Aarts WM, Schlom J, and Hodge
JW. Vector-based vaccine/cytokine
combination therapy to enhance
induction of immune responses to a
self-antigen and anti-tumor activity.
Cancer Res. 62:5770–5777, 2002.
17. Hodge JW, Sabzevari H, Yafal AG,
Gritz L, Lorenz MG, Schlom J. A triad
of costimulatory molecules synergize to
amplify T-cell activation. Cancer Res.
59: 5800–5807, 1999.
Patent Status
1. U.S. Patent No. 6,969,609 issued
November 29, 2005 as well as issued
and pending foreign counterparts [HHS
Ref. No. E–256–1998/0];
2. U.S. Patent Application No. 11/
321,868 filed December 30, 2005 [HHS
Ref. No. E–256–1998/1]; and
3. U.S. Patent No. 6,756,038 issued
June 29, 2004 as well as issued and
pending foreign counterparts [HHS Ref.
No. E–099–1996/0];
4. U.S. Patent No. 6,001,349 issued
December 14, 1999 as well as issued and
pending foreign counterparts [HHS Ref.
No E–200–1990/3–US–01];
5. U.S. Patent No. 6,165,460 issued
December 26, 2000; as well as issued
and pending foreign counterparts [HHS
Ref. No E–200–1990/4–US–01];
6. U.S. Patent No. 7,118,738 issued
October 10, 2006 as well as issued and
pending foreign counterparts [HHS Ref.
No E–154–1998/0–US–07];
7. PCT Application No. PCT/US97/
12203 filed July 15, 1997 [HHS Ref. No
E–259–1994/3–PCT–02];
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8. U.S. Patent Application Nos. 10/
197,127 and 08/686,280 filed July 17,
2002 and July 25, 1996 [HHS Ref. No E–
259–1994/3–US–08 and /4–US–01];
9. U.S. Patent No. 6,946,133 issued
September 20, 2005 as well as issued
and pending foreign counterparts [HHS
Ref. No E–062–1996/0–US–01];
10. U.S. Patent Application No. 11/
606,929 filed December 1, 2006 [E–062–
1996/0–US–11];
11. U.S. Patent Nos. 6,893,869,
6,548,068 and 6,045,802 issued May 17,
2005, April 15, 2003 and April 4, 2000
respectively, as well as issued and
pending foreign counterparts [HHS Ref.
Nos. E–260–1994/1–US–03, US–02, US–
01]; and
12. U.S. Patent. Application No. 11/
090,686 filed March 8, 2005 [HHS Ref.
No E–260–1994/1–US–04].
Licensing Contact: Michelle Booden,
PhD, 301/451–7337;
boodenm@mail.nih.gov.
Cooperative Research and
Development Agreement (CRADA)
Opportunity: A CRADA partner for the
further co-development of this
technology is currently being sought by
the Laboratory of Tumor Immunology
and Biology, Center for Cancer
Research, NCI.
The CRADA partner will:
1. Generate and characterize
recombinant poxviruses expressing
specific tumor-associated antigens,
cytokines, and/or T-cell costimulatory
factors,
2. Analyze the recombinant
poxviruses containing these genes with
respect to appropriate expression of the
encoded gene product(s),
3. Supply adequate amounts of
recombinant virus stocks for preclinical
testing,
4. Manufacture and test selected
recombinant viruses for use in human
clinical trials,
5. Submit Drug Master Files detailing
the development, manufacture, and
testing of live recombinant vaccines to
support the NCI-sponsored INDs,
6. Supply adequate amounts of
clinical grade recombinant poxvirus
vaccines for clinical trials conducted at
the NCI Center for Cancer Research
(CCR), and
7. Provide adequate amounts of
vaccines for extramural clinical trials
through a clinical agreement with the
Division of Cancer Treatment and
Diagnosis, NCI.
NCI will:
1. Provide genes of tumor-associated
antigens, cytokines and other
immunostimulatory molecules for
incorporation into poxvirus vectors,
2. Evaluate recombinant vectors in
preclinical models alone and in
combination therapies,
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3. Conduct clinical trials of
recombinant vaccines alone and in
combination therapies, and
4. Provide Drug Master Files currently
supporting the clinical use of the
recombinant poxvirus vaccines.
If interested in the above described
CRADA, please submit a statement of
interest and capability to Kevin Chang,
PhD, in the NCI Technology Transfer
Center at changke@mail.nih.gov or 301–
496–0477.
Time: 8 a.m. to 5 p.m.
Agenda: To review and evaluate grant
applications.
Place: Bethesda Marriott, 5151 Pooks Hill
Road, Bethesda, MD 20814.
Contact Person: Martina Schmidt, Ph.D,
Scientific Review Administrator, Office of
Scientific Review, National Center for
Complementary, and Alternative Medicine,
NIH, 6707 Democracy Blvd., Suite 401,
Bethesda, MD 20892, (301) 594–3456.
schmidma@mail.nih.gov.
Dated: May 11, 2007.
Steven M. Ferguson,
Director, Division of Technology Development
and Transfer, Office of Technology Transfer,
National Institutes of Health.
[FR Doc. E7–9541 Filed 5–16–07; 8:45 am]
Dated: May 8, 2007.
Jennifer Spaeth,
Director, Office of Federal Advisory
Committee Policy.
[FR Doc. 07–2427 Filed 5–16–07; 8:45 am]
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DEPARTMENT OF HEALTH AND
HUMAN SERVICES
DEPARTMENT OF HEALTH AND
HUMAN SERVICES
National Institutes of Health
National Institutes of Health
National Center for Complementary
and Alternative Medicine; Notice of
Closed Meeting
National Eye Institute; Notice of Open
Meeting
pwalker on PROD1PC71 with NOTICES
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
meetings.
The meetings 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
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 Center for
Complementary and Alternative Medicine
Special Emphasis Panel; Basic Science.
Date: June 11–12, 2007.
Time: 8 a.m. to 5 p.m.
Agenda: To review and evaluate grant
applications.
Place: Courtyard Marriott, Washingtonian
Center, 240 Boardwalk Place (Rio),
Gaithersburg, MD 20878.
Contact Person: Dale L. Birkle, Ph.D,
Scientific Review Administrator, Office of
Scientific Review, National Center for
Complementary, and Alternative Medicine,
NIH, 6707 Democracy Blvd., Suite 401,
Bethesda, MD 20892, (301) 451–6570.
birkled@mail.nih.gov.
Name of Committee: National Center for
Complementary and Alternative Medicine
Special Emphasis Panel; Centers of
Excellence for Research on Complementary
and Alternative Medicine.
Date: June 20–22, 2007.
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The National Eye Institute will host
an Ocular Epidemiology Program
Planning Panel Meeting to discuss
research needs and opportunities in
ocular epidemiology. The meeting will
be open to the public.
The thoughts and input from this
meeting will be given by the panel
members individually and incorporated
into a report that will be given to the
National Eye Institute.
Name of Panel: Ocular Epidemiology
Panel.
Date: May 24–25, 2007.
Time: 8 a.m.–5 p.m.
Agenda: To discuss the Ocular
Epidemiology Research.
Place: Hyatt Regency Bethesda, One
Bethesda Metro Center, (7400 Wisconsin
Avenue), Bethesda, MD 20814.
Contact Person: Mr. Michael Davis,
Associate Director for Science Policy and
Legislation, National Eye Institute, Bldg. 31;
Room 6A25, 31 Center Drive MSC 2510,
Bethesda, MD 20892, (301) 496–4308.
This notice is being published less than 15
days prior to the meeting due to the timing
limitations imposed by the review and
funding cycle.
Any interested person may file written
comments with the panel by forwarding the
statement to the Contact Person listed on this
notice. The statement should include the
name, address, telephone number and when
applicable, the business or professional
affiliation of the interested person.
(Catalogue of Federal Domestic Assistance
Program Nos. 93.867, Vision Research,
National Institutes of Health, HHS)
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Dated: May 8, 2007.
Jennifer Spaeth,
Director, Office of Federal Advisory
Committee Policy.
[FR Doc. 07–2425 Filed 5–16–07; 8:45 am]
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DEPARTMENT OF HEALTH AND
HUMAN SERVICES
National Institutes of Health
National Eye 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 a meeting of the
National Advisory Eye Council.
The meeting will be open to the
public 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.
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
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 Advisory
Eye Council.
Date: June 7, 2007.
Closed: 8:30 a.m. to 10:30 a.m.
Agenda: To review and evaluate grant
applications.
Place: National Institutes of Health,
Natcher Building, 45 Center Drive,
Conference Room D, Bethesda, MD 20892.
Open: 10:30 a.m. to Adjournment.
Agenda: Following opening remarks by the
Director, NEI there will be presentations by
the staff of the Institute and discussions
concerning Institute programs.
Place: National Institutes of Health,
Natcher Building, 45 Center Drive,
Conference Room D, Bethesda, MD 20892.
Contact Person: Lore Anne McNicol, PhD,
Director, Division of Extramural Research,
National Eye Institute, National Institutes of
Health, Bethesda, MD 20892, (301) 451–2020.
Any interested person may file written
comments with the committee by forwarding
the statement to the Contact Person listed on
this notice. The statement should include the
name, address, telephone number and when
applicable, the business or professional
affiliation of the interested person.
E:\FR\FM\17MYN1.SGM
17MYN1
]]>Agencies
[Federal Register Volume 72, Number 95 (Thursday, May 17, 2007)]
[Notices]
[Pages 27818-27821]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: E7-9541]
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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.
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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.
Humanized Anti-Carcinoma CC49 Monoclonal Antibodies
Description of Technology: The technology describes the
humanization of a murine anti-carcinoma antibody CC49 which has been
shown to react with Tumor Associated Glycoprotein 72 (TAG-72), an
antigen which is expressed on human breast, ovarian, colorectal, and
other carcinomas.
The invention includes a new method of humanization of a rodent
antibody which is based on grafting all the Complementarity Determining
Residues (CDRs) of a rodent antibody onto a human antibody framework.
Additionally, the method identifies Specificity Determining Residues
(SDRs), the amino acid residues in the hypervariable regions of an
antibody that are most critical for antigen binding activity and of
rendering any antibody minimally immunogenic in humans by transferring
the SDRs of the antibody to a human antibody framework. The resulting
humanized antibodies, including CDR variants thereof (including a CH2
deleted version), are also embodied in the invention, as are methods of
using the antibodies for therapeutic and diagnostic purposes.
Furthermore, these antibodies are suitable for radiolabeling for
the application in radioimmunotherapy (RIT) based treatment of several
cancers. Phase I results of radioimmunotherapy for ovarian cancer using
\90\Yttrium-CC49 murine monoclonal antibodies have shown promising
results and confirms feasibility of the use of these antibodies for
RIT. Promising pharmacokinetic data for the radiolabeled humanized
antibodies in colon carcinoma xenograft models were recently published.
Applications and Modality
1. A humanized anti-cancer CC49 monoclonal antibody has been
developed.
2. New methods of humanization of rodent antibodies have been
identified.
3. The antibody(s) has been shown to react with Tumor Associated
Glycoprotein 72 (TAG-72), an antigen which is expressed on human
breast, ovarian, colorectal, and other carcinomas.
4. These antibodies are suitable for radiolabeling for the
application in radioimmunotherapy (RIT) based treatment of several
cancers.
5. These antibodies can be useful in diagnosis and treatment of
several cancers.
Development Status: The technology is currently in the pre-clinical
stage of development. Phase I results of
[[Page 27819]]
radioimmunotherapy for ovarian cancer using \90\Yttrium-CC49 murine
monoclonal antibodies have shown promising results and confirms
feasibility of the use of these antibodies for radioimmunotherapy
(RIT).
Inventors: Syed V. Kashmiri (NCI), Eduardo A. Padlan (NIDDK),
Jeffrey Schlom (NCI).
Publications
1. RD Alvarez et al. A Phase I study of combined modality
\90\Yttrium-CC49 intraperitoneal radioimmunotherapy for ovarian cancer.
Clin Cancer Res. 2002 Sep; 8(9):2806-2811.
2. A Forero et al. A novel monoclonal antibody design for
radioimmunotherapy. Cancer Biother Radiopharm. 2003 Oct;18(5):751-759.
3. PC Chinn et al. Pharmacokinetics and tumor localization of (111)
in-labeled HuCC49DeltaC(H)2 in BALB/c mice and athymic murine colon
carcinoma xenograft. Cancer Biother Radiopharm. 2006 Apr;21(2):106-116.
Patent Status
1. U.S. Patent No. 6,818,749 issued November 16, 2004 and U.S.
Patent Application 10/927,433 filed August 25, 2004 as well as issued
and pending foreign counterparts [HHS Ref. No. E-259-1998];
2. European Patent No. 00365997 issued September 14, 1994 and its
counterpart in Japan [HHS Ref. Nos. D-003-1992/0-EP-07 and D-003-1992/
0-JP-05];
3. U.S. Patent No. 5,472,693 issued December 5, 1995 [HHS Ref. No.
D-003-1992/2-US-01];
4. U.S. Patent No. 6,051,225 issued April 18, 2000 [HHS Ref. No. D-
003-1992/3-US-01];
5. U.S. Patent No. 5,993,813 issued November 30, 1999 [HHS Ref. No.
D-003-1992/2-US-02];
6. U.S. Patent No. 6,641,999 issued November 4, 2003 [HHS Ref. No.
D-003-1992/2-US-04];
7. European Patent No. 628078 issued December 8, 1999 and its
counterparts in Japan, Canada and Australia [HHS Ref. Nos. D-004-1992/
0-EP-06, D-004-1992/0-JP-03, D-004-1992/0-CA-04 and D-004-1992/0-AU-
05];
8. U.S. Patent No. 5,877,291 issued March 2, 1999 [HHS Ref. No. D-
004-1992/1-US-01];
9. U.S. Patent No. 5,892,020 issued April 6, 1999 [HHS Ref. No. D-
004-1992/1-US-01] and its foreign counterparts;
10. Taiwanese Patent No. 173667 issued July 10, 2003 [HHS Ref. No.
D-001-1996/0-TW-03];
11. U.S. Patent No. 6,737,060 issued May 18, 2004 [HHS Ref. No. D-
001-1996/1-US-03];
12. U.S. Patent No. 6,737,061 issued May 18, 2004 [HHS Ref. No. D-
001-1996/1-US-04];
13. U.S. Patent No. 6,753,152 issued June 22, 2004 [HHS Ref. No. D-
001-1996/1-US-05];
14. U.S. Patent No. 6,752,990 issued June 22, 2004 [HHS Ref. No. D-
001-1996/1-US-06];
15. U.S. Patent No. 6,329,507 issued December 11, 2001 [HHS Ref.
No. D-001-2006/0-US-01] and
16. U.S. Patent No. 6,071,515 issued June 6, 2000 [HHS Ref. No. D-
001-2006/0-US-03].
Licensing Availability: Available for exclusive and non-exclusive
licensing.
Licensing Contact: Michelle Booden, PhD.; 301/451-7337;
boodenm@mail.nih.gov
Collaborative Research Opportunity: The National Cancer Institute's
Laboratory of Tumor Immunology and Biology is seeking statements of
capability or interest from parties interested in collaborative
research to further develop, evaluate, or commercialize anti-carcinoma
antibodies. Please contact John D. Hewes, Ph.D. at 301-435-3121 or
hewesj@mail.nih.gov for more information.
Enhanced T-cell Activation by Costimulation: an Effective Immunotherapy
for Cancer and Infectious Diseases
Description of Technology: Cancer immunotherapy is a recent
approach where tumor associated antigens (TAAs), which are primarily
expressed in human tumor cells and not expressed or minimally expressed
in normal tissues, are employed to generate a tumor specific immune
response. Specifically, these antigens serve as targets for the host
immune system and elicit responses that result in tumor destruction.
The initiation of an effective T-cell immune response to antigens
requires two signals. The first one is antigen specific via the
peptide/major histocompatibility complex and the second or
``costimulatory'' signal is required for cytokine production,
proliferation, and other aspects of T-cell activation.
The present technology describes recombinant poxvirus vectors
encoding at least three or more costimulatory molecules and TAAs. The
use of three costimulatory molecules such as B7.1, ICAM-1 and LFA-3
(TRICOM[supreg]) has been shown to act in synergy with several tumor
antigens and antigen epitopes to activate T cells. The effects with
TRICOM[supreg] were significantly greater than with one or two
costimulatory molecules. Laboratory results support the greater effect
of TRICOM[supreg] to activate both CD4+ and CD8+ T cells. The invention
also describes the use of at least one target antigen or immunological
epitope as an immunogen or vaccine in conjunction with TRICOM[supreg].
The antigens include but are not limited to carcinoembryonic antigen
(CEA), prostate-specific antigen (PSA), and MUC-1.
The combination of CEA, MUC-1, and TRICOM[supreg] is referred to as
PANVAC[supreg] and the combination of PSA and TRICOM[supreg] is
referred to as PROSTVAC[supreg].
Licensing Availability: The technology is available for exclusive
and non-exclusive licensing in combinations and for different fields of
use. Some potential licensing opportunities are as follows:
1. TRICOM[supreg] (alone or with a transgene for a tumor antigen
and/or an immunostimulatory molecule);
2. The antigens only, including but not limited to CEA, PSA, and
MUC-1;
3. PANVAC[supreg] and/or PROSTVAC[supreg]; and
4. Recombinant fowlpox-GM-CSF.
Application(s) and Modality: Vector-based TRICOM[supreg] (alone or
with a transgene for a tumor antigen and/or an immunostimulatory
molecule), PANVAC[supreg] and PROSTVAC[supreg] and combinations thereof
can be a potential novel immunotherapeutic approach for the treatment
of cancer and infectious diseases.
Advantages
1. The technology is beyond proof-of-concept, supported by
laboratory results and publications.
2. Phase I and Phase II clinical data available.
3. Fewer validation studies are required compared to other
immunotherapy related technologies.
Development Status: Phase I and Phase II results available for
poxvirus recombinants containing transgenes for TRICOM[supreg], CEA-
TRICOM[supreg], PANVAC[supreg], and PROSTVAC[supreg]. Further clinical
studies are ongoing for other combinations.
Inventors: Jeffrey Schlom (NCI) et al.
Publications
1. Kaufman HL, Cohen S, Cheung K, DeRaffele, Mitcham J, Moroziewicz
D, Schlom J, and Hesdorffer C. Local delivery of vaccinia virus
expressing multiple costimulatory molecules for the treatment of
established tumors. Human Gene Ther. 17:239-244, 2006.
2. Kantoff PW GL, Tannenbaum SI, Bilhartz DL, Pittman WG, Schuetz
TJ. Randomized, double-blind, vector-controlled study of targeted
immunotherapy in patients (pts) with
[[Page 27820]]
hormone-refractory prostate cancer (HRPC). 2006 ASCO Annual Meeting
Proceedings, Part I, abstract 2501. J Clin Oncol.; 24.
3. Marshall J, Gulley JL, Arlen PM, Beetham PK, Tsang KY, Slack R,
Hodge JW, Doren S, Grosenbach DW, Hwang J, Fox E, Odogwa L, Park S,
Panicali D, Schlom J. A phase I study of sequential vaccinations with
fowlpox-CEA(6D)-TRICOM (B7-1/ICAM-1/LFA-3) alone and sequentially with
vaccinia-CEA(6D)-TRICOM, with and without GM-CSF, in patients with CEA-
expressing carcinomas. J Clin Oncol. 23:720-731, 2005.
4. Palena C, Foon KA, Panicali D, Yafal AG, Chinsangaram J, Hodge
JW, Schlom J, and Tsang KY. A potential approach to immunotherapy of
chronic lymphocytic leukemia (CLL): enhanced immunogenicity of CLL
cells via infection with vectors encoding for multiple costimulatory
molecules. Blood 106:3515-3523, 2005.
5. Gulley J, Todd N, Dahut W, Schlom J, Arlen P. A phase II study
of PROSTVAC-VF vaccine, and the role of GM-CSF, in patients (pts) with
metastatic androgen insensitive prostate cancer (AIPC) [abstract]. J
Clin Oncol. 2005; 23 (16S Pt 1): 2504.
6. Yang S, Hodge JW, Grosenbach DW, and Schlom J. Vaccines with
enhanced costimulation maintain high avidity memory CTL. J. Immunol.
175:3715-3723, 2005.
7. Yang S, Tsang KY, and Schlom J. Induction of higher avidity
human CTL by vector-mediated enhanced costimulation of antigen-
presenting cells. Clin Cancer Res. 11:5603-5615, 2005.
8. Hodge JW, Chakraborty M, Kudo-Saito C, Garnett CT, Schlom J.
Multiple costimulatory modalities enhance CTL avidity. J Immunol.
174:5994-6004, 2005.
9. Tsang K-Y, Palena C, Yokokawa J, Arlen PM, Gulley JL, Mazzara
GP, Gritz L, G[oacute]mez Yafal A, Ogueta S, Greenhalgh P, Manson K,
Panicali D, and Schlom J. Analyses of recombinant vaccinia and fowlpox
vaccine vectors expressing transgenes for two human tumor antigens and
three human costimulatory molecules. Clin Cancer Res. 11:1597-1607,
2005.
10. Chakraborty M, Abrams SI, Coleman CN, Camphausen K, Schlom J,
Hodge JW. External beam radiation of tumors alters phenotype of tumor
cells to render them susceptible to vaccine-mediated T-cell killing.
Cancer Res. 64:4328-4337, 2004.
11. Zeytin HE, Patel AC, Rogers CJ, et al. Combination of a
poxvirus-based vaccine with a cyclooxygenase-2 inhibitor (celecoxib)
elicits antitumor immunity and long-term survival in CEA.Tg/MIN mice.
Cancer Res. 64:3668-3678, 2004.
12. Palena C, Zhu M-Z, Schlom J, and Tsang K-Y. Human B cells that
hyperexpress a triad of costimulatory molecules via avipoxvector
infection: an alternative source of efficient antigen-presenting cells.
Blood 104:192-199, 2004.
13. Kudo-Saito C, Schlom J, and Hodge JW. Intratumoral vaccination
and diversified subcutaneous/intratumoral vaccination with recombinant
poxviruses encoding a tumor antigen and multiple costimulatory
molecules. Clin Cancer Res. 10:1090-1099, 2004.
14. Hodge JW, Poole DJ, Aarts WM, Gomez Yafal A, Gritz L, and
Schlom J. Modified vaccinia virus ankara recombinants are as potent as
vaccinia recombinants in diversified prime and boost vaccine regimens
to elicit therapeutic antitumor responses. Cancer Res. 63:7942-7949,
2003.
15. Hodge JW, Grosenbach DW, Aarts Wm, Poole DJ, and Schlom J.
Vaccine therapy of established tumors in the absence of autoimmunity.
Clin Cancer Res. 9:1837-1849, 2003.
16. Aarts WM, Schlom J, and Hodge JW. Vector-based vaccine/cytokine
combination therapy to enhance induction of immune responses to a self-
antigen and anti-tumor activity. Cancer Res. 62:5770-5777, 2002.
17. Hodge JW, Sabzevari H, Yafal AG, Gritz L, Lorenz MG, Schlom J.
A triad of costimulatory molecules synergize to amplify T-cell
activation. Cancer Res. 59: 5800-5807, 1999.
Patent Status
1. U.S. Patent No. 6,969,609 issued November 29, 2005 as well as
issued and pending foreign counterparts [HHS Ref. No. E-256-1998/0];
2. U.S. Patent Application No. 11/321,868 filed December 30, 2005
[HHS Ref. No. E-256-1998/1]; and
3. U.S. Patent No. 6,756,038 issued June 29, 2004 as well as issued
and pending foreign counterparts [HHS Ref. No. E-099-1996/0];
4. U.S. Patent No. 6,001,349 issued December 14, 1999 as well as
issued and pending foreign counterparts [HHS Ref. No E-200-1990/3-US-
01];
5. U.S. Patent No. 6,165,460 issued December 26, 2000; as well as
issued and pending foreign counterparts [HHS Ref. No E-200-1990/4-US-
01];
6. U.S. Patent No. 7,118,738 issued October 10, 2006 as well as
issued and pending foreign counterparts [HHS Ref. No E-154-1998/0-US-
07];
7. PCT Application No. PCT/US97/12203 filed July 15, 1997 [HHS Ref.
No E-259-1994/3-PCT-02];
8. U.S. Patent Application Nos. 10/197,127 and 08/686,280 filed
July 17, 2002 and July 25, 1996 [HHS Ref. No E-259-1994/3-US-08 and /4-
US-01];
9. U.S. Patent No. 6,946,133 issued September 20, 2005 as well as
issued and pending foreign counterparts [HHS Ref. No E-062-1996/0-US-
01];
10. U.S. Patent Application No. 11/606,929 filed December 1, 2006
[E-062-1996/0-US-11];
11. U.S. Patent Nos. 6,893,869, 6,548,068 and 6,045,802 issued May
17, 2005, April 15, 2003 and April 4, 2000 respectively, as well as
issued and pending foreign counterparts [HHS Ref. Nos. E-260-1994/1-US-
03, US-02, US-01]; and
12. U.S. Patent. Application No. 11/090,686 filed March 8, 2005
[HHS Ref. No E-260-1994/1-US-04].
Licensing Contact: Michelle Booden, PhD, 301/451-7337;
boodenm@mail.nih.gov.
Cooperative Research and Development Agreement (CRADA) Opportunity:
A CRADA partner for the further co-development of this technology is
currently being sought by the Laboratory of Tumor Immunology and
Biology, Center for Cancer Research, NCI.
The CRADA partner will:
1. Generate and characterize recombinant poxviruses expressing
specific tumor-associated antigens, cytokines, and/or T-cell
costimulatory factors,
2. Analyze the recombinant poxviruses containing these genes with
respect to appropriate expression of the encoded gene product(s),
3. Supply adequate amounts of recombinant virus stocks for
preclinical testing,
4. Manufacture and test selected recombinant viruses for use in
human clinical trials,
5. Submit Drug Master Files detailing the development, manufacture,
and testing of live recombinant vaccines to support the NCI-sponsored
INDs,
6. Supply adequate amounts of clinical grade recombinant poxvirus
vaccines for clinical trials conducted at the NCI Center for Cancer
Research (CCR), and
7. Provide adequate amounts of vaccines for extramural clinical
trials through a clinical agreement with the Division of Cancer
Treatment and Diagnosis, NCI.
NCI will:
1. Provide genes of tumor-associated antigens, cytokines and other
immunostimulatory molecules for incorporation into poxvirus vectors,
2. Evaluate recombinant vectors in preclinical models alone and in
combination therapies,
[[Page 27821]]
3. Conduct clinical trials of recombinant vaccines alone and in
combination therapies, and
4. Provide Drug Master Files currently supporting the clinical use
of the recombinant poxvirus vaccines.
If interested in the above described CRADA, please submit a
statement of interest and capability to Kevin Chang, PhD, in the NCI
Technology Transfer Center at changke@mail.nih.gov or 301-496-0477.
Dated: May 11, 2007.
Steven M. Ferguson,
Director, Division of Technology Development and Transfer, Office of
Technology Transfer, National Institutes of Health.
[FR Doc. E7-9541 Filed 5-16-07; 8:45 am]
BILLING CODE 4140-01-P
