Title: Nanotechnology commercialization at the Technion Israel Institute of Technology
1Nanotechnology commercialization at the Technion
- Israel Institute of Technology
Benjamin Soffer, Manager Technology Transfer
OfficeTechnion Research Development Foundation
Ltd.
December 2008
2Nanotechnology In Israel
2007 Israeli Nanotech Survey
Growth in National Capacity
The 2007 survey confirms Israel's potential as a
global nanotech RD hub, revealing strong
continuing growth in national research capacity.
Over 330 Nano Researchers Working in 7 Leading
Fields
- Led by the Technion - Israel Institute of
Technology, Israel's six universities have added
or assigned new researchers to nanotechnology
studies, and this strong growth trend will
continue. The number of researchers reporting
work in or related to nanotech has more than
doubled since the INNI's initial survey in 2002.
To support this growth, the INNI has directed a
large portion of government funding allocations
toward the improvement of laboratory
infrastructure, especially the upgrade or
purchase of institute equipment.
3Survey of Israeli academic and industrial
nanotech RD Ready or not, Israel is a key
global player.
4Technion Vision
Technion Today
- 18 Academic Departments
- 40 Research Institutes and Departments
- 49 Undergraduate Programs
- 63 Graduate Programs
- 13,291 Students
- 70,954 Graduates to date
- 588 Faculty Members
- 300 acre campus, 85 buildings (excluding
dormitories) - 4000 student dormitory beds
- A science and technology research university,
among the worlds top ten, dedicated to the
creation of knowledge and the development of
human capital and leadership, for the advancement
of the State of Israel and all humanity.
5Faculties for the Future
- Electrical Engineering
- Biotechnology and Food Engineering
- Humanities and Arts
- Industrial Engineering and Management
- Materials Engineering
- Mathematics
- Mechanical Engineering
- Medicine
- Physics
- Aerospace Engineering
- Architecture and Town Planning
- Biology
- Biomedical Engineering
- Chemical Engineering
- Chemistry
- Civil and Environmental Engineering
- Computer Science
- Education in Technology and Science
6Nanotechnology Research at Technion
- Researchers from 12 faculties
- Electrical Engineering
- Materials Engineering
- Mechanical Engineering
- Chemical Engineering
- Biomedical Engineering
- Aerospace Engineering
- Biotechnology and Food Engineering
- Biology
- Medicine
- Chemistry
- Physics
- Mathematics
- 115 faculty and 300 graduate students and
postdoctoral fellows conduct vigorous research in - Nanoelectronics
- Nanooptics
- Nanomaterials
- Nanomechanics
- and the interface between these fields and life
sciences.
7Main Lines of Activity
- Taking advantage of the unique combination of
medical school, engineering, and sciences to
develop and maintain cutting edge RD in
nanotechnology - Vigorous recruitment of bright new faculty from
research labs around the world - Extensive investment in infrastructure to serve
all Israeli researchers in academia and industry - New educational programs for training
next-generation scientists and engineers - Nurturing multidisciplinary collaborations within
campus - Collaborations with industry and other academic
institutions
8Selected Research Projects
Electronic Nose for Detecting Cancer via Breath
Samples
- Dr. Hossam Haick
- Department of Chemical Engineering
- Overall aim Develop an inexpensive,
non-invasive, breath-based electronic nose to
diagnose, detect, and screen cancer at different
stages of the disease. - Technology Arrays of nanomaterial-based
chemiresistors, chemicapacitors, and chemically
sensitive field effect transistors. - Hybrid structures of nanomaterials enable
combining, in the same crystalline framework, two
or more sensing properties that are difficult to
achieve in a one-phase material. - Breath based electronic nose can provide early
warning of the cancer, before it has the chance
to become life threatening.
9Nanofabricated HYBRID Biomaterials for Tissue Eng
Selected Research Projects
- Dr. Dror Seliktar
- Faculty of Biomedical Engineering
- Overall aim develop sophisticated biomaterials
for tissue regeneration and wound healing. - Technology A novel class of in-situ
polymerizable HYBRID biomaterials based on
protein-polymer conjugates. - HYBRID biomaterials provide biological and
physical advantages in treating tissue damage. - Implants can be injected into the body as a
liquid, formed into a gel in-situ, and stimulate
functional regeneration of damaged bone,
cartilage, nerve, and heart muscle.
10Electrospinning of Nanofibers from Polymer
Solutions
Selected Research Projects
- Professors Eyal Zussman and Alexander Yarin
- Faculty of Mechanical Engineering
- Straightforward, inexpensive method for
producingnovel fibers with a 100 nm diameter or
less. - Polymer solutions containing suspensions of
solidparticles and emulsions are electrospun in
an lectric field of about 1 kV/cm. - As-spun fibers are of interest in development of
novel polymer-based light-emitting diodes,
transistors, photonic crystals and flexible
photocells, nanofiber-based filters, protective
clothing, biomedical applications including wound
dressings, light sails and mirrors for use in
space, artificial tissues, and reinforced
composites. - Core-shell nanofibers are spun by
co-electrospinning two materials that cannot be
electrospun alone. The shell polymer encapsulates
the core material resulting in compound
structures for use in microelectronics, optics
and medicine.
11Selected Research Projects
Manipulating Embryonic Stem Cell Differentiation
and 3D Organization
Dr. Shulamit LevenbergFaculty of Biomedical
Engineering
- Control of human embryonic stem cellinteractions
and differentiation is critical fortissue
engineering applications and forstudying human
development. Nano- andmicro-manipulations of the
cell micro-environmentare used to induce
specific differentiation of thecells and to
engineer 3D tissue-like structures. - Key research
- Cell interactions and formation of tissue
structures during differentiation of human
embryonic stem cells on defined biodegradable
matrices with controlled architecture and
composition. - Forces evolving during human embryonic stem cell
growth and proliferation on macro (whole
scaffold) and micro (single cell) levels of
scaffolds.
12Selected Research Projects
Nanoencapsulation Nanostructuring of Bioactive
Materials for Nutraceuticals and Functional Foods
Prof. Eyal Shimoni Faculty of Biomedical and
Food Engineering
- Overall aim tailor food grade delivery systems
an functional materials. - Technology controlling self assembly processes
of food components, edible biopolymers, mostly
polysaccharides - Molecular inclusion complexes host bioactive
nutrients and serve as a food grade molecularly
controlled release system for the
gastrointestinal system. - Nano-encapsulation protects the sensitive
bioactive through food processing, storage, and
the GI system.
13 Challenges in Commercializing Nano
Technologies
14- Difficulties in assessing cost or what market
might - bear.
- Buyer don't know what they are willing to pay.
- Dynamics of the market place is unknown.
- Difficulty assessing cost of goods.
- Difficulty assessing margins, or savings.
- competitive landscape mostly unknown.
- Financial forecast mostly unknown.
15- Impact in the market place mostly unknown
- Capital investment required to bring product to
- the market unclear.
- Many Nano technologies are manufacturing
- process related, and it is challenging to
estimate - the savings involved.
- Cost of human resources required is often
- unknown, so is their availability.
16- Difficulty in assessing the regulatory pathway of
- the product to the marketplace.
- Number of potential applications mostly
- unknown.
- Barriers to market entry mostly unknown.
- Difficulty in making assumptions regarding
- external factor affecting commercialization.
Back to main
17- Nature and extent of problems remaining to be
- solved mostly unknown.
-
- Most innovations are at a concept level of
- development.
Back to main
18- Period required to develop the IP and hence the
remaining life of the patents to be developed
unclear. - Number of potential applications mostly
unknown. - IP environment is unclear. Unclear whether it
will be possible to obtain adequate IP
protection.
19 Models of Academic Approaches to
Nano-technology Commercialization
Progressive Policies
Aid in Securing Funding
Flexible Terms
Business Development Assistance
Help Recruit Talent
Direct Investment
Business Operations Participation
Hands-in-Pockets Hands-Off Hands-On Up-to-Elbows
Form the Licensee
Operational Role
Licensing Practices
Technion chose up-to-elbows
Source MIT, AUTM, MRUN, U Michigan et al
20Flexible Practices
Flexible Practices
Pro Active approach Internal/External
- Our commercialization strategies, tailored
to the requirements of each venture, enhance the
market value and performance of Technion
discoveries and increase their success in the
global marketplace
Business Development Assistance
Help Recruit Talent
Business Operations Participation
Direct Investment
21Flexible Terms
Flexible Practices
TRDF Affiliated Companies - EXAMPLES
Pro Active approach Internal/External
Business Development Assistance
Help Recruit Talent
Business Operations Participation
Direct Investment
22Flexible Terms
Flexible Practices
Success Stories - Examples
Pro Active approach Internal/External
Business Development Assistance
Help Recruit Talent
Collateral Therapeutics
Business Operations Participation
Sanborn Research LLC
Direct Investment
23Case Study
Flexible Practices
Azilect/ Agilect (Rasagiline) An
anti-Parkinson's disease drug
Pro Active approach Internal/External
- Developed by Teva Pharmaceuticals in cooperation
with Prof. Moussa Youdim and Prof. John
Feinberg - Parkinson disease is a progressive condition
that involves a gradual loss of nerve cell
function in the brain. The nerve cells that are
specifically affected are those that control body
movement. - 4 million people worldwide suffer from
Parkinson's disease - Affecting approximately 1 of the population over
the age of 65 - Agilect/Azilect- Azilect was launched in
Israel in March 2005 - 4 royalties of net sales
Business Development Assistance
Help Recruit Talent
Business Operations Participation
Direct Investment
24Pro Active approach Internal/External
Flexible Practices
Pro Active approach Internal/External
Business Development Assistance
Help Recruit Talent
Business Operations Participation
Direct Investment
25New Inventions (2007)
- 92 new invention disclosures
- 85 filed
- 4 in examination
- 2 released
- 1 abandoned
26Pro Active approach Internal/External
Flexible Terms
Flexible Practices
The Technion Entrepreneurial Centre and the
Technology Transfer Office
Pro Active approach Internal/External
Business Development Assistance
Help Recruit Talent
Help Recruit Talent
Business Operations Participation
Business Operations Participation
Direct Investment
Direct Investment
27Pro Active approach Internal/External
Flexible Practices
Pro Active approach Internal/External
Business Development Assistance
Help Recruit Talent
Business Operations Participation
Direct Investment
28Pro Active approach Internal/External
Flexible Practices
July , 2006 MR. YEHIEL TAL Co-Founder CEO
Regentis Biomaterials Ltd.DR. DROR SELIKTAR
Co-Founder Department of Biomedical Engineering
December, 2005 PROFESSOR KARL SKORECKI
Bruce Rappaport Faculty Of Medicine
Pro Active approach Internal/External
Business Development Assistance
February, 2006 PROFESSOR ASSAF SCHUSTER Faculty
of Computer Sciences
November, 2006 PROFESSOR RON KIMMELFaculty of
Computer Sciences
Technion Webinar Innovation Series
Help Recruit Talent
Business Operations Participation
April, 2007MR. ARIK ARAD CEO, EORD MR.
AVNER ESHED General Manager, EORD (E.E-B.Sc,
MBA)
April, 2006 PROFESSOR DOV DORI William Davidson
Faculty of IndustrialEngineering and Management
.
Direct Investment
29Business Development Assistance
Flexible Practices
Developing with MBA Students Technology Transfer
Strategies for Inventions based on Faculty
members disclosures
Pro Active approach Internal/External
Business Development Assistance
Help Recruit Talent
www.technionseed.co.il
Business Operations Participation
A Technion-based institute aimed at supporting
development and commercialization of biomedical
innovations from the Technion.
Direct Investment
30Help Recruit Talent
Flexible Practices
Dynamic but UniformProcess
Founders Instead of Finders
Market Looking for Technology
Pro Active approach Internal/External
EIR Program
Business Development Assistance
Community Building
Global Local Market
Help Recruit Talent
IP Generation
Licensing and New Company Formation
Business Operations Participation
Multi Disciplinary
Direct Investment
31- Business Operations Participation
Flexible Practices
Pro Active approach Internal/External
- Participation in the board of directors of
affiliated companies - Negotiation and approval of the IP and
business aspects of agreements with industry
Business Development Assistance
Help Recruit Talent
Business Operations Participation
Direct Investment
32Direct Investment
Flexible Practices
TTT - Fund
Pro Active approach Internal/External
- Investments in Technion Affiliated
Companies - A disbursement of an amount up to 50,000
USD for a specific project of TRDF and/or
DIMOTECH and/or TEIC.
Business Development Assistance
Help Recruit Talent
Business Operations Participation
Direct Investment
33Direct Investment
Flexible Practices
Pro Active approach Internal/External
Business Development Assistance
Help Recruit Talent
Business Operations Participation
Direct Investment
34THANK YOU Benjamin Soffer sofferb_at_technion.ac.il
T3 Technion Technology Transfer T3.technion.ac.
il
35Selected Research Projects
Nanoparticles for Controlled Drug Delivery
- Dr. Marcelle MachlufFaculty of Biotechnology and
Food Engineering - Nanoparticles for the delivery of anti-cancer
drugs. - Angiogenesis, the formation of new blood vessels
from preexisting ones, is critical for growth and
metastases of solid tumors. - There is need for a controlled delivery system
enabling local administration of anti-angiogenic
drugs in small quantities. - Nanoparticles facilitating controlled release of
drugs over weeks or months have been developed.
They can be injected into organs and particularly
into the brain. The nanoparticles are
biodegradable and composed from materials that
are approved for clinical applications. First
application therapy for glioblastomas, the most
malignant form of brain tumor. - Gene therapy using nano-delivery systems.