What is the focus of Dr. Eunice Lee's presentation?

The presentation focuses on the regulatory perspective of molecular diagnostic devices, particularly companion diagnostics and next-generation sequencing (NGS) oncology panels.

What are companion diagnostics?

Companion diagnostics are tests that provide essential information for the safe and effective use of a corresponding therapeutic.

How are in vitro diagnostic devices classified?

IVDs are classified into three classes based on risk: Class 1 (low risk), Class 2 (moderate risk), and Class 3 (high risk), with varying levels of regulatory controls.

What is the significance of the FDA's review process for IVDs?

The FDA review process ensures that devices are safe and effective for their intended use, relying on valid scientific evidence.

What challenges are associated with validating NGS tests?

Challenges include the inability to evaluate every variant, limited clinical specimens, and lack of reference methods for accuracy.

What is the role of the IDE application in clinical trials?

An IDE application permits the lawful shipment of a device for investigation without complying with other requirements of the Food Drug and Cosmetic Act.

What are the three levels of biomarkers in NGS oncology panels?

Level 1 biomarkers have companion diagnostic claims, Level 2 biomarkers are clinically significant mutations, and Level 3 biomarkers have potential clinical significance.

What is the purpose of the FDA CMS parallel review program?

The program aims to reduce the time between FDA approval of a device and CMS Medicare coverage.

How does the FDA evaluate the performance of IVDs?

The FDA evaluates performance through analytical and clinical validation, ensuring reliability and accuracy of test results.

What resources are available for more information on the topics discussed?

Additional resources can be found on the FDA website and through the links provided in the presentation.

Keynote Presentation: A Regulatory Perspective on Molecular Diagnostic Devices

00:50:57

https://www.youtube.com/watch?v=En8C5VQs32g

Resumen

TLDRDr. Eunice Lee's presentation provides an overview of the regulatory landscape for molecular diagnostic devices, particularly focusing on companion diagnostics and next-generation sequencing (NGS) oncology panels. She explains the classification of in vitro diagnostic devices (IVDs) based on risk, the evaluation of their safety and effectiveness, and the regulatory pathways for different classes of devices. The presentation highlights the importance of companion diagnostics in relation to therapeutic products, the challenges of validating NGS tests, and recent FDA authorizations that have influenced the regulatory framework. Dr. Lee emphasizes the need for collaboration between diagnostic and drug sponsors and discusses the evolving regulatory models in personalized medicine, underscoring the significance of valid scientific evidence in the review process.

Para llevar

🔍 Overview of IVD regulation and classification
📊 Importance of analytical and clinical validation
💡 Companion diagnostics are essential for therapeutic use
⚖️ Regulatory pathways differ by device class
🧬 NGS tests present unique validation challenges
🤝 Collaboration is key between stakeholders
📅 Recent FDA authorizations shape regulatory landscape
📈 Parallel review program expedites coverage decisions
📚 Resources available for further information
🔗 Contact for follow-up questions

Cronología

00:00:00 - 00:05:00
The live broadcast introduces Dr. Eunice Lee from the FDA, who will discuss the regulatory perspective on molecular diagnostic devices, particularly companion diagnostics and next-generation sequencing (NGS). The event encourages audience interaction through questions and provides information on continuing education credits.
00:05:00 - 00:10:00
Dr. Lee outlines the FDA's role in reviewing in vitro diagnostic devices (IVDs), which include various tests and systems for diagnosing diseases. She emphasizes that the information shared is for discussion purposes and refers to FDA resources for specific inquiries.
00:10:00 - 00:15:00
The FDA evaluates IVDs based on valid scientific evidence to ensure safety and effectiveness. Devices are classified into three categories (Class 1, 2, and 3) based on risk, with Class 1 being low risk and Class 3 being high risk, requiring more stringent controls.
00:15:00 - 00:20:00
The intended use of a device is crucial for its classification, which determines the regulatory pathway. Class 1 devices may be exempt from premarket notification, while Class 2 devices typically require a 510(k) submission, and Class 3 devices require a premarket approval (PMA).
00:20:00 - 00:25:00
The FDA review process includes assessing intended use, performance, labeling, and compliance with quality assurance regulations. Analytical and clinical performance validations are essential for demonstrating reliability and accuracy of the tests.
00:25:00 - 00:30:00
Companion diagnostics are a specific subset of IVDs that provide essential information for the safe and effective use of corresponding therapeutics. Their approval is often tied to the approval of the therapeutic product, requiring close collaboration between regulatory bodies.
00:30:00 - 00:35:00
Key questions regarding companion diagnostics include the necessity of the test, the need for an investigational device exemption (IDE) for clinical trials, and how to handle changes in the assay used during trials. Collaboration between drug and device sponsors is critical.
00:35:00 - 00:40:00
The need for companion diagnostics arises when there is adequate evidence of clinical activity in the biomarker-selected population. An IDE may be required if the test poses significant risk during trials, and bridging studies may be necessary if the clinical trial assay differs from the final diagnostic.
00:40:00 - 00:45:00
Complementary diagnostics, unlike companion diagnostics, are not essential for drug use but help identify patient subsets that may benefit from specific therapies. Their development path is similar to companion diagnostics, but they do not require the same level of regulatory scrutiny.
00:45:00 - 00:50:57
Next-generation sequencing (NGS) oncology panels present unique challenges due to their ability to screen numerous biomarkers simultaneously. Validation for these tests is complex, and the FDA recommends representative approaches for validating variants, especially for those without companion diagnostic claims.

Mapa mental

Vídeo de preguntas y respuestas

What is the focus of Dr. Eunice Lee's presentation?
The presentation focuses on the regulatory perspective of molecular diagnostic devices, particularly companion diagnostics and next-generation sequencing (NGS) oncology panels.
What are companion diagnostics?
Companion diagnostics are tests that provide essential information for the safe and effective use of a corresponding therapeutic.
How are in vitro diagnostic devices classified?
IVDs are classified into three classes based on risk: Class 1 (low risk), Class 2 (moderate risk), and Class 3 (high risk), with varying levels of regulatory controls.
What is the significance of the FDA's review process for IVDs?
The FDA review process ensures that devices are safe and effective for their intended use, relying on valid scientific evidence.
What challenges are associated with validating NGS tests?
Challenges include the inability to evaluate every variant, limited clinical specimens, and lack of reference methods for accuracy.
What is the role of the IDE application in clinical trials?
An IDE application permits the lawful shipment of a device for investigation without complying with other requirements of the Food Drug and Cosmetic Act.
What are the three levels of biomarkers in NGS oncology panels?
Level 1 biomarkers have companion diagnostic claims, Level 2 biomarkers are clinically significant mutations, and Level 3 biomarkers have potential clinical significance.
What is the purpose of the FDA CMS parallel review program?
The program aims to reduce the time between FDA approval of a device and CMS Medicare coverage.
How does the FDA evaluate the performance of IVDs?
The FDA evaluates performance through analytical and clinical validation, ensuring reliability and accuracy of test results.
What resources are available for more information on the topics discussed?
Additional resources can be found on the FDA website and through the links provided in the presentation.

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00:00:01
hello everyone and welcome to today's
00:00:03
live broadcasts and keynote presentation
00:00:05
a regulatory perspective on molecular
00:00:08
diagnostic devices presented by dr.
00:00:11
Eunice Lee chief of the molecular
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pathology and cytology branch in the
00:00:16
office of in vitro diagnostics and
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radiological health at the US Food and
00:00:21
Drug Administration
00:00:22
my name is Gary Stein and I'll be your
00:00:25
moderator for today's event we're
00:00:27
delighted to bring you this educational
00:00:28
web seminar presented by lab roots lab
00:00:32
roots is the leading scientific social
00:00:35
networking website and producer of
00:00:37
educational virtual events and webinars
00:00:40
before we begin I would like to remind
00:00:42
everyone that this event is interactive
00:00:45
we encourage you to participate by
00:00:47
submitting as many questions as you want
00:00:49
at any time you want during the
00:00:51
presentation just click on the ask a
00:00:54
question box located on the far left of
00:00:57
your screen and type your questions into
00:00:59
the drop-down box that appears on the
00:01:02
screen dr. Lee will be responding to
00:01:04
your questions via email if you have
00:01:07
trouble seeing or hearing the
00:01:08
presentation please click on the help
00:01:11
desk button located in the promotional
00:01:14
board at the bottom slash center of your
00:01:16
screen or use the ask a question box to
00:01:20
let us know that you're having a problem
00:01:22
this presentation is educational and
00:01:25
thus offers continuing education credits
00:01:27
please click on the continuing education
00:01:30
credits tab located in the top right
00:01:33
corner of the presentation window and
00:01:35
follow the process to obtain your
00:01:38
credits today's webcast will be
00:01:40
available for on-demand viewing through
00:01:43
July of 2018 so please join me in
00:01:47
welcoming dr. Eunice Lee I will now turn
00:01:49
the presentation over to her
00:01:56
thank you very much for that
00:01:57
introduction Gary and I'd like to extend
00:02:00
a thank you to the organizers of this
00:02:02
event as mentioned my group is the
00:02:07
molecular pathology and cytology branch
00:02:10
and it's within the division of
00:02:11
molecular genetics and pathology at the
00:02:14
FDA we review a variety of invitro
00:02:17
diagnostic devices ranging from whole
00:02:21
slide imaging systems to
00:02:22
immunohistochemistry tests or IHC tests
00:02:25
and nucleic acid-based tests for some
00:02:29
oncology indications so today I'll
00:02:32
provide a regulatory perspective on
00:02:34
molecular diagnostic devices with
00:02:37
particular focus on companion
00:02:39
diagnostics and next-generation
00:02:41
sequencing based on ecology panels
00:02:45
before I begin I would just like to note
00:02:47
that the information presented today are
00:02:51
only intended for summary and discussion
00:02:54
purposes if there are specific questions
00:02:56
about any of the examples that I talked
00:03:00
about today about the specific devices
00:03:01
please refer to the decision summaries
00:03:04
and the summaries of safety and
00:03:06
effectiveness data or SS EDS
00:03:08
which are publicly available documents
00:03:10
on the FDA website and at the last slide
00:03:14
I'll have some a link to the medical
00:03:16
device database where this information
00:03:18
can be accessed today I'll start by
00:03:24
providing an overview of the regulation
00:03:27
of in vitro diagnostic devices or IV DS
00:03:30
then I'll touch on some assay
00:03:32
performance considerations and discuss
00:03:34
how we evaluate IV D products then I'll
00:03:38
move to companion diagnostics providing
00:03:42
an overview and discussing some key
00:03:44
issues in Co development and then I'll
00:03:47
move beyond companion diagnostics and
00:03:49
briefly talk about follow-on companion
00:03:51
diagnostics and complementary
00:03:53
diagnostics and then I'll end by
00:03:56
discussing NGS or next-generation
00:03:58
sequencing oncology panels I'll talk
00:04:02
about the validation considerations for
00:04:04
these types of
00:04:04
tests and also provide some examples of
00:04:08
recent FDA authorizations that have
00:04:11
significantly impacted the current
00:04:13
regulatory paradigm for these types of
00:04:15
devices so what is an IV D in the Code
00:04:22
of Federal Regulations or the CFR which
00:04:25
is basically the set of rules and
00:04:26
regulations by which we abide an IV D is
00:04:30
defined as reagents instruments and
00:04:32
systems intended for use in diagnosis of
00:04:35
disease or other conditions including a
00:04:38
determination of the state of health in
00:04:40
order to cure mitigate treat or prevent
00:04:43
disease or it's equally such products
00:04:46
are intended for use in the collection
00:04:48
preparation and examination of specimens
00:04:51
taken from the human body and this
00:04:53
definition can be found in 21 CFR part
00:04:56
eight oh nine point three when the
00:05:01
agency reviews an IV D we rely on valid
00:05:06
scientific evidence in order to provide
00:05:08
reasonable assurance that the device is
00:05:11
safe and effective for its intended use
00:05:14
so with regard to safety the central
00:05:17
question is really are there reasonable
00:05:20
assurances based on valid scientific
00:05:22
evidence that the probable benefits to
00:05:25
health from use of the device will
00:05:27
outweigh any probable risks with regard
00:05:30
to effectiveness similar question is are
00:05:33
there reasonable assurances again based
00:05:36
on valid scientific evidence that the
00:05:38
use of the device in the target
00:05:40
population will provide clinically
00:05:42
significant results so within the
00:05:45
regulatory framework when evaluating the
00:05:49
safety and effectiveness of the devices
00:05:51
the devices are actually classified
00:05:54
based on a risk based classification
00:05:57
system so there are three regulatory
00:06:00
classes for devices class 1 class 2 and
00:06:04
class 3 and there are differing levels
00:06:07
of controls for each of these classes
00:06:09
where the current level of control will
00:06:12
increase from class 1 to class 3
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class 1 devices are considered to be low
00:06:18
risk these devices are subject to
00:06:21
general controls class two devices are
00:06:24
moderate risk and they are subject to
00:06:27
both general controls as well as special
00:06:29
controls and class 3 devices are the
00:06:32
highest risk category and for these both
00:06:35
general and special controls alone are
00:06:37
not sufficient to mitigate the risks
00:06:40
that are associated with the devices for
00:06:42
their intended uses so the risk
00:06:45
classification is wholly dependent upon
00:06:49
the intended use of the device and this
00:06:51
is basically the manner in which the
00:06:53
device is intended to be used so the
00:06:56
intended use is a statement that will
00:06:58
specify the analytes that are being
00:07:00
measured the specimen type that's being
00:07:03
tested as well as providing the context
00:07:06
in which the device should be used so
00:07:08
for example if there's a clinical claim
00:07:10
for prognosis or diagnosis or monitoring
00:07:13
that will be included in the intended
00:07:15
use statement as mentioned this is a
00:07:18
risk based classification and so for IV
00:07:22
DS it's really the risk that is
00:07:24
associated with obtaining false results
00:07:26
from that test and it's the level of
00:07:30
risk that is posed to the patients and
00:07:33
the users of that device the
00:07:35
classification is not based on
00:07:38
technology so even if you have a very
00:07:40
complex technological assay this alone
00:07:43
will not automatically place the device
00:07:45
in the high-risk category however the
00:07:48
technology or the methodology will
00:07:50
influence the types of validation
00:07:52
studies that will be needed to
00:07:54
demonstrate the safety and effectiveness
00:07:56
of the product
00:08:01
so within the regulatory framework the
00:08:05
classification of the device will
00:08:08
determine the pre-market regulatory
00:08:10
pathway for that device although all
00:08:13
devices are subject to be labeled
00:08:17
properly to be manufactured under a
00:08:19
quality assurance program and to have
00:08:23
establishment registration and device
00:08:25
listing forms on file with the FDA but
00:08:29
each class here has a different
00:08:32
regulatory path for example most class 1
00:08:36
low-risk devices are exempt from
00:08:39
premarket notification that is a 510 K
00:08:42
application is not required for those
00:08:45
devices however as I mentioned those
00:08:47
class 1 devices are still subject to
00:08:50
registration and listing class 2 devices
00:08:54
most of them will require a 510 K
00:08:57
submission in order to obtain FDA
00:09:00
clearance and they obtain clearance by
00:09:04
demonstrating that the device is
00:09:06
substantially equivalent to a legally
00:09:09
marketed predicate device in some cases
00:09:13
the class 2 devices may be exempt from
00:09:18
premarket notification and in other
00:09:21
cases there may be an absence of a
00:09:24
predicate device where that device type
00:09:26
has not previously been classified and
00:09:29
in that case then a de novo request for
00:09:32
classification can be submitted for that
00:09:34
device and once authorized that device
00:09:37
can then serve as a predicate for
00:09:39
subsequent devices of the same device
00:09:41
type and then for class 3 high-risk
00:09:46
devices these are subject to a PMA
00:09:49
application to be submitted for FDA
00:09:51
approval so what do we look at when we
00:09:56
review of these medical devices listed
00:10:01
here are the elements of FDA review the
00:10:05
intended use
00:10:06
the indications for use as discussed in
00:10:08
the previous slide are very central to
00:10:11
our review we also look at the
00:10:13
performance of the device which is
00:10:15
comprised of the analytical validation
00:10:17
and the clinical validation when
00:10:21
applicable the instrument and the
00:10:23
software validation is also reviewed we
00:10:26
also look at the labeling and the
00:10:28
labeling for the device must be
00:10:30
compliant with CFR eight or nine point
00:10:33
ten and as I mentioned previously all
00:10:36
devices must be manufactured under a
00:10:38
quality assurance program and they must
00:10:41
meet the quality system regulation
00:10:43
however for PMA applications the quality
00:10:46
system regulation information is
00:10:49
reviewed in the pre market setting so
00:10:53
I'll delve a little bit further into the
00:10:55
scientific review as I mentioned this is
00:10:58
comprised of both the analytical and the
00:11:01
clinical performance the analytical
00:11:03
performance should really demonstrate
00:11:05
the reliability and the accuracy of the
00:11:08
analyte measurements detected by that
00:11:11
test the studies can be specific to that
00:11:15
assay methodology as well as the
00:11:18
intended use and an example of this is
00:11:21
for IHC or immunohistochemistry assays
00:11:25
reader studies are needed
00:11:27
however from molecular nucleic
00:11:29
acid-based tests reader studies aren't
00:11:31
needed but accuracy studies are required
00:11:35
with regard to clinical performance the
00:11:39
test should be correlated with a
00:11:41
clinically meaningful and clinically
00:11:43
significant outcome and some measures to
00:11:46
demonstrate this can be clinical
00:11:48
sensitivity and specificity or positive
00:11:52
and negative predictive values as
00:11:53
appropriate for a few considerations for
00:12:00
analytical performance the test is
00:12:02
really considered as the whole system so
00:12:05
the validation should encompass all the
00:12:07
way from specimen collection and
00:12:10
preparation all the way through to
00:12:13
result reporting and therefore this
00:12:15
includes the pre and a little
00:12:17
steps the validation studies should also
00:12:20
be conducted with the intended specimen
00:12:22
type by using clinical specimens from
00:12:25
the intended population it's also
00:12:27
important to evaluate the performance of
00:12:30
the device across the entire reportable
00:12:33
and measuring range for that device and
00:12:35
this includes around the clinical
00:12:38
cut-offs and importantly the studies
00:12:41
should follow the protocol that will be
00:12:43
in the final device labeling for
00:12:49
clinical performance it should be
00:12:51
determined how the device will be used
00:12:53
in the clinical setting and then the
00:12:56
study design should ensure that it is
00:12:58
appropriate in order to support the
00:13:00
intended use of the device the clinical
00:13:03
study as well as the statistical
00:13:06
analysis plan should be pre specified
00:13:08
and clinical performance should be
00:13:11
established by comparing to an endpoint
00:13:13
or an appropriate surrogate and
00:13:17
typically analytical validation will
00:13:20
precede clinical validation now we'll
00:13:25
move on to companion diagnostics
00:13:30
companion diagnostics are a subset of IV
00:13:33
DS the definition of a companion
00:13:36
diagnostic is that it's a test that
00:13:39
provides information that is essential
00:13:42
for the safe and effective use of a
00:13:44
corresponding therapeutic because the
00:13:48
use of the companion diagnostic and the
00:13:52
corresponding therapeutic are
00:13:53
interdependent the use of the companion
00:13:56
along with the drug is specified in the
00:14:00
labeling of both the diagnostic as well
00:14:03
as the corresponding therapeutic it's
00:14:07
expected that there is contemporaneous
00:14:10
regulatory approvals for both the device
00:14:12
and the corresponding therapeutic
00:14:16
therefore when we review an IV D
00:14:19
application for a companion diagnostic
00:14:21
the review timeline is tied to the
00:14:24
corresponding application for the
00:14:26
therapeutic
00:14:27
product there are however exceptions
00:14:30
when contemporary knees approval may not
00:14:33
be possible and this may happen if there
00:14:37
is an unmet need or if it's in the best
00:14:40
interest of Public Health to approve a
00:14:42
drug prior to approval of the device in
00:14:45
such cases then the companion diagnostic
00:14:49
approval will be included as a post
00:14:52
marketing commitment on the therapeutic
00:14:55
side so for more information about FDA
00:15:01
expectations for companion diagnostics
00:15:03
you can refer to the final draft
00:15:05
guidance which is titled in-vitro
00:15:08
companion diagnostic devices the final
00:15:11
guidance was issued in August of 2014 in
00:15:14
there the definition of a companion is
00:15:16
provided and various scenarios for use
00:15:20
are described in addition FDA policies
00:15:23
for approval and labeling are outlined
00:15:30
to date there are more than 40 approved
00:15:33
companion diagnostic and therapeutic
00:15:35
combinations all of them except for one
00:15:38
are for oncology indications for 18
00:15:42
approved cancer therapeutics there are
00:15:45
33 approved unique IVD companion
00:15:49
diagnostics and all of them except for
00:15:51
one went through the PMA pathway and
00:15:55
these tests cover a total of 18
00:15:58
different biomarkers for a complete and
00:16:01
up-to-date listing of the cleared and
00:16:04
approved companion diagnostic devices
00:16:07
you can refer to the website shown on
00:16:10
this slide so as I mentioned the use of
00:16:16
a device
00:16:16
the use of a companion diagnostic is
00:16:19
tied to the use of a corresponding
00:16:22
therapeutic product and so there are
00:16:25
several key questions that will arise
00:16:27
regarding Co development first how do
00:16:31
you know that a companion diagnostic
00:16:33
device is needed second when you use a
00:16:36
test to identify a biomarker in
00:16:40
the clinical trial for the therapeutic
00:16:42
product will an investigational device
00:16:45
exemption or IDE application be needed
00:16:48
and third what if the final device was
00:16:52
not used in the therapeutic clinical
00:16:55
trial and finally how can a test receive
00:16:59
the same companion diagnostic claim as
00:17:01
the originally approved companion
00:17:04
diagnostic so I'll answer each one of
00:17:07
these questions in the subsequent slides
00:17:10
so first about the need for a companion
00:17:13
diagnostic typically both the
00:17:16
therapeutic and the device are studied
00:17:18
in the same clinical trial
00:17:20
therefore the clinical validation of the
00:17:23
device is supported by the results of
00:17:25
the therapeutic trial in other words the
00:17:28
results from the primary efficacy
00:17:29
population that are used to support
00:17:32
approval of the drug that is the
00:17:35
population that will also be used to
00:17:37
support device approval so when you use
00:17:41
a device in a clinical trial it's very
00:17:43
important that that assay is fully
00:17:46
specified and is locked down prior to
00:17:49
its use in that trial and what I mean by
00:17:52
that is that a specific assays should be
00:17:55
identified for detecting the marker in
00:17:57
that trial the specific protocol should
00:18:00
be identified and the clinical decision
00:18:05
points that will be used to define
00:18:06
biomarker positivity versus biomarker
00:18:09
negativity should be specified in
00:18:11
addition the specific specimen type
00:18:14
should be identified it's also important
00:18:18
that the assay is adequately validated
00:18:21
prior to its use in the trial so
00:18:25
ultimately the decision about the need
00:18:28
for a companion diagnostic is made by
00:18:31
the therapeutic review division but they
00:18:35
make this decision in consultation with
00:18:37
the device center so for these companion
00:18:40
diagnostics they really take a great
00:18:42
deal of collaboration and coordination
00:18:44
between the respective review centers as
00:18:47
well as between the respective device
00:18:49
and drug sponsors
00:18:51
so when thinking about whether companion
00:18:55
diagnostic is needed the central
00:18:57
questions are really is there adequate
00:18:59
evidence of clinical activity of the
00:19:01
therapeutic in the biomarker selected
00:19:04
population as identified by the
00:19:06
companion diagnostic and most
00:19:09
importantly is the test essential for
00:19:13
the safe and effective use of the
00:19:15
corresponding therapeutic product if the
00:19:17
answer to this is yes then undoubtedly
00:19:19
a companion diagnostic will be needed so
00:19:24
what about the need for an IDE
00:19:27
application an approved IDE permits the
00:19:32
device to be shipped lawfully in order
00:19:34
to conduct investigations of the device
00:19:36
without complying with other
00:19:38
requirements of the Food Drug and
00:19:40
Cosmetic Act that would apply to devices
00:19:42
in commercial distribution so typically
00:19:45
when a device is used in a clinical
00:19:48
trial its be it has not been approved
00:19:51
for that indication to be legally
00:19:54
marketed and so an IDE provides for an
00:19:57
exemption for use of that device and the
00:19:59
trial so when we look at all device
00:20:04
investigations some of them may be
00:20:06
subject to the IDE regulation while
00:20:09
others may be exempt from the IDE
00:20:11
regulation of those that are subject to
00:20:13
the IDE regulation some are considered
00:20:17
to be significant risk and therefore
00:20:19
subject to the full IDE requirements
00:20:21
while others may be non significant risk
00:20:24
and although an IDE application does not
00:20:27
need to be submitted to the agency for
00:20:29
these NSR studies they are subject to
00:20:32
the abbreviated IDE requirements which
00:20:35
can be found in 21 CFR part 812 so the
00:20:42
determination about the need for an IDE
00:20:44
is not a benefit risk decision it's
00:20:48
really an assessment of risk that is
00:20:50
posed to the patients who are enrolled
00:20:54
into that trial so the question is does
00:20:57
use of the test result pose a
00:21:00
significant risk if the answer is yes
00:21:02
and most likely that trial will be
00:21:05
use of the device in that trial will be
00:21:08
considered to be significant risk and an
00:21:10
IDE application will be needed in order
00:21:14
to determine if an IDE is needed for a
00:21:16
specific trial we recommend that a study
00:21:19
risk determination pre submission is
00:21:21
submitted to the Center for Devices so
00:21:28
the third question was about what
00:21:32
happens if the clinical trial assay or
00:21:34
CTA differs from the companion
00:21:37
diagnostic so one example of when this
00:21:40
might happen is if a prototype of an
00:21:43
assay is used to enroll patients in the
00:21:45
trial and then the assay goes through
00:21:47
some optimization or some changes and
00:21:51
then a different assay will come forward
00:21:53
for marketing authorization in such a
00:21:56
case changing the test can lead to
00:21:59
changes in the assay performance and
00:22:01
this in turn can change the patient
00:22:04
population from what was selected in the
00:22:06
therapeutic clinical trial when this
00:22:09
happens
00:22:10
bridging studies are required in order
00:22:13
to perform a bridging study patient
00:22:16
specimens that tested both CTA negative
00:22:19
and CTA positive should be retained and
00:22:22
banked so that they can be retested with
00:22:24
the final companion diagnostic device in
00:22:28
such a case there should be no
00:22:30
collection or selection bias and
00:22:32
therefore you should ensure that the
00:22:35
samples that are stored there and their
00:22:38
integrity is maintained and one way to
00:22:41
do this is through demonstration of the
00:22:43
stability of the analytes in those
00:22:46
stored specimens in order to ensure that
00:22:50
the storage duration was acceptable and
00:22:52
the quality of the assay is acceptable
00:22:56
when performing bridging study
00:22:58
statistical analysis plan should
00:23:01
consider potential discordance 'as and
00:23:03
also should account for any missing
00:23:06
samples importantly bridging studies are
00:23:10
not just a method comparison study
00:23:12
bridging studies should evaluate the
00:23:15
concordance between the CTA test results
00:23:18
and the companion diagnostic test
00:23:19
results but it should also demonstrate
00:23:23
that the clinical outcomes that were
00:23:25
correlated with the CTA are maintained
00:23:28
with the test results from the companion
00:23:30
diagnostic device the last question was
00:23:37
about the possibility for the same
00:23:40
companion diagnostic claim as the
00:23:43
original companion diagnostic claim for
00:23:46
a new test it's recognized that often
00:23:51
times samples from the original clinical
00:23:54
trial that's used to support the
00:23:56
approval of the original companion
00:23:58
diagnostic may not exist any longer or
00:24:01
they just may not be available for
00:24:03
retesting in such a case there are two
00:24:08
potential pathways that could be
00:24:10
followed in order to gain the same
00:24:13
companion diagnostic claim the first is
00:24:17
that they can follow the path of the
00:24:19
original companion diagnostic they could
00:24:21
perform a new clinical trial in order to
00:24:24
obtain clinical outcome data that's
00:24:27
correlated with the new test we
00:24:30
recognize that it can be extremely
00:24:32
burdensome and costly to perform a new
00:24:35
clinical trial and so an alternative
00:24:38
path is to get a follow-on companion
00:24:41
diagnostic claim a follow-on companion
00:24:45
diagnostic should consistently and
00:24:47
accurately select the same intended use
00:24:49
patient population as the originally
00:24:52
approved companion diagnostic device and
00:24:55
therefore the can follow on companion
00:25:01
diagnostic should demonstrate the same
00:25:04
or the comparable level of analytical
00:25:07
and clinical performance for the
00:25:08
specific mutations or the specific
00:25:11
analytes that are being tested in the
00:25:14
originally approved companion diagnostic
00:25:18
so in order to demonstrate this
00:25:21
performance it's important that a
00:25:23
clinical concordance study which is
00:25:26
essentially a method comparison
00:25:28
study is performed to compare the new
00:25:32
test with the previously approved
00:25:35
companion diagnostic so a term that has
00:25:43
emerged in the recent past is
00:25:49
complementary Diagnostics and these are
00:25:53
tests that in contrast to companion
00:25:56
diagnostics these are not essential for
00:26:00
the safe and effective use of the
00:26:02
therapeutic product complementary
00:26:05
Diagnostics identify a biomarker to find
00:26:08
subsets of patients who respond
00:26:10
particularly well to a drug and aid in
00:26:14
the benefit risk assessment for
00:26:16
individual patients therefore it is not
00:26:19
a prerequisite for receiving the drug an
00:26:22
example of a situation in which a
00:26:26
complementary diagnostic would arise is
00:26:28
when a drug is approved for an
00:26:30
all-comers however there may be
00:26:34
differential clinical outcomes based on
00:26:37
biomarker status as defined by this
00:26:39
complementary diagnostic and so in such
00:26:42
cases then a complementary diagnostic
00:26:45
may be needed because the complementary
00:26:48
Diagnostics are also studied in the
00:26:51
clinical trial that's used to evaluate
00:26:53
the performance of the therapeutic
00:26:54
product the development path for
00:26:57
complementary Diagnostics is similar to
00:27:00
that for companion diagnostics so now
00:27:07
I'll move on to NGS oncology panels
00:27:11
these next-generation sequencing based
00:27:14
on ecology panels are increasingly being
00:27:17
employed in the clinical setting part of
00:27:21
their advantage is that they have the
00:27:24
ability to screen a very large number of
00:27:27
biomarkers which can be up to thousands
00:27:30
of biomarkers that can be screened
00:27:32
simultaneously therefore the tests
00:27:36
have broad intended uses due to the
00:27:40
sheer volume of the number of sequences
00:27:43
that can be obtained from a single run
00:27:46
validation for such a test on a per
00:27:49
variant or per market basis is not
00:27:51
feasible and therefore these types of
00:27:54
tests have introduced challenges to the
00:27:57
companion diagnostic paradigm which
00:28:00
traditionally has been one test for one
00:28:03
drug as I mentioned previously the
00:28:10
validation studies for a device should
00:28:13
be designed to support the performance
00:28:15
characteristics of that device for its
00:28:17
intended use but as I mentioned there
00:28:21
are challenges one is that it is not
00:28:25
feasible to validate all possible
00:28:28
alterations that may be detected by an
00:28:31
NGS test a second clinical specimens for
00:28:37
analytical validation may be limiting
00:28:41
particularly for rare tumor types or for
00:28:44
tumors in which there are low prevalence
00:28:46
biomarkers and third there is a lack of
00:28:51
reference methods and standards that can
00:28:53
be used in order to demonstrate the
00:28:56
accuracy of these NGS uncle panels so in
00:29:00
the next few slides I'll address each of
00:29:03
these challenges by presenting
00:29:05
strategies that have been implemented by
00:29:08
some of the tests that we've reviewed
00:29:11
first with regard to the inability to
00:29:15
evaluate every single variant that could
00:29:19
be detected by an NGS test it's
00:29:24
recognized that this is terribly
00:29:26
burdensome and therefore we recommend
00:29:28
that all variants with clinical
00:29:31
companion diagnostic claims should be
00:29:34
included in the validation studies
00:29:36
however these NGS tests include can
00:29:40
include many more genes or biomarkers
00:29:44
that extend beyond the markers so
00:29:48
with a companion diagnostic claim so in
00:29:52
such cases we then recommend that a
00:29:54
representative approach can be taken in
00:29:57
order to support the validation of those
00:30:00
other single nucleotide variants and
00:30:03
insertions and deletions or in Dells
00:30:06
when taking a representative approach
00:30:08
it's important that a range of variant
00:30:11
types are included which represent or
00:30:14
give consideration to the sizes of the
00:30:17
different variants as well as the
00:30:19
contexts the genomic context that those
00:30:22
variants can be detected in on the other
00:30:29
hand a representative variant approach
00:30:32
is not acceptable for fusions or gene
00:30:35
rearrangements because the performance
00:30:37
of the device for one gene fusion may
00:30:41
not be able to be extrapolated to
00:30:44
fusions detected in other genes so what
00:30:49
I really mean by this is that if fusions
00:30:52
in the AL gene are used in the
00:30:54
validation studies this cannot be used
00:30:57
in order to gain claims that the test
00:31:00
can detect fusions in other genes such
00:31:03
as rosslyn however within the AL gene we
00:31:09
recommend that the most common the two
00:31:11
or three most common out confusions are
00:31:14
represented in the validation studies in
00:31:18
order to obtain the claim that a test
00:31:21
can detect alkanes and so therefore
00:31:24
every single out fusion that has been
00:31:26
identified does not need to be included
00:31:29
in the validation studies there are also
00:31:34
can be some post-market considerations
00:31:37
in order to obtain a pre market post
00:31:40
market balance and so there may be
00:31:42
circumstances under which post market
00:31:45
data can be provided for some analytical
00:31:48
studies in order to further demonstrate
00:31:50
the performance of the device
00:31:57
regarding the potential lack of clinical
00:32:00
specimens the test performance should be
00:32:03
established with the intended clinical
00:32:06
specimens however in certain analytical
00:32:09
studies it may be appropriate to use
00:32:12
contrived samples provided at an
00:32:15
appropriately designed functional
00:32:17
characterization study is performed so a
00:32:20
contrived sample functional
00:32:22
characterization study basically should
00:32:25
demonstrate that the contrived samples
00:32:28
are able to appropriately mimic the
00:32:30
clinical specimens and therefore can be
00:32:33
used as surrogates in the validation
00:32:35
studies another consideration for pan
00:32:40
tumor claims in which it is not possible
00:32:42
to test every single tumor type that has
00:32:47
been identified in these cases we
00:32:50
recommend that comparability across a
00:32:53
variety of common and challenging tumors
00:32:55
is demonstrated and we typically
00:32:58
recommend that at least 10 tumor types
00:33:00
are represented also because different
00:33:04
tumor types can have different potential
00:33:06
interference it's important to assess
00:33:09
interference effects
00:33:10
an example is melanin in melanoma and
00:33:14
then finally we also recommend that data
00:33:17
is provided regarding the invalid rates
00:33:20
and the performance metrics across tumor
00:33:23
types and this information can be based
00:33:25
on historical data or a retrospective
00:33:28
analysis of data that already exists
00:33:35
regarding the lack of reference methods
00:33:38
in order to demonstrate accuracy a
00:33:41
validated orthogonal method may be used
00:33:44
as a comparator if the method is not an
00:33:48
fda-approved
00:33:49
or an FDA cleared test then minimal
00:33:52
level of validation data is needed for
00:33:55
the comparator and we generally
00:33:57
recommend that at a minimum limit of
00:34:01
and sensitivity studies as well as DNA
00:34:03
input and precision studies are
00:34:05
performed to support the performance of
00:34:08
that other test as a comparator method
00:34:12
to demonstrate accuracy of the test
00:34:17
additional validation considerations are
00:34:21
that the validation should evaluate how
00:34:24
different source errors can affect
00:34:27
device performance
00:34:30
NGS tests are a complex process that
00:34:34
involves numerous steps in the workflow
00:34:37
this encompasses sample preparation
00:34:41
library construction sequencing and data
00:34:44
analysis and even result reporting in
00:34:48
such cases for these types of tests
00:34:51
different error profiles are associated
00:34:54
with different analytes which can range
00:34:56
from parameters including variant type
00:34:59
genomic context and allele frequency so
00:35:03
therefore we recommend that quality
00:35:05
metrics are established at both the
00:35:07
sample and the variant levels and that
00:35:10
these quality metrics should really look
00:35:12
beyond exon level coverage and so some
00:35:16
of the quality metrics that we request
00:35:20
are listed here the reportable range
00:35:23
should be clearly defined and this is
00:35:25
with respect to genomic regions variant
00:35:28
types that will be detected by the assay
00:35:29
as well as the variant allele
00:35:31
frequencies that are detected and all of
00:35:35
the quality control metrics and the
00:35:37
validations should be developed in order
00:35:39
to ensure the performance of the device
00:35:42
within the claimed reportable range in
00:35:46
addition sequencing metrics should be
00:35:49
provided such as the run in the sample
00:35:51
QC mapping metrics which will include
00:35:54
coverage and coverage should cover depth
00:35:57
completeness and uniformity and
00:36:00
additional metrics can be variant
00:36:03
calling as well as reporting metrics so
00:36:07
the validation considerations that I
00:36:09
discussed were implemented
00:36:12
and stemmed from our experiences with
00:36:16
NGS tests that we've reviewed so listed
00:36:19
here are some of the NGS tests actually
00:36:22
all of the NGS tests that we have
00:36:24
reviewed and cleared or approved the
00:36:28
first NGS tests were actually not
00:36:32
companion diagnostic devices those were
00:36:37
approved in November of 2013 and those
00:36:41
were two Illumina tests that were
00:36:44
intended to detect cystic fibrosis
00:36:46
variants that are intended to aid in the
00:36:49
diagnosis of cystic fibrosis as they're
00:36:52
not companion diagnostics and they were
00:36:54
for an aid and diagnosis for cystic
00:36:56
fibrosis those went through the 510 k
00:36:58
pathway the first NGS based companion
00:37:03
diagnostic test was approved in December
00:37:07
of 2016 and that was the foundation
00:37:10
focus CDX bracha test from from
00:37:14
foundation medicine that tests detected
00:37:18
variance in the Braco one and the
00:37:20
bracket two genes and more recently in
00:37:24
June and November of last year for
00:37:27
next-generation sequencing tests were
00:37:30
approved three of these were considered
00:37:33
next-generation sequencing oncology
00:37:36
panels and they're listed here so
00:37:38
basically these tests included genes
00:37:41
beyond those that have companion
00:37:44
diagnostic claims so the first test that
00:37:48
was approved in June of 2017 went
00:37:51
through the PMA pathway and it was for
00:37:54
the angka mine DX target test from
00:37:56
thermo Fisher Scientific the next was
00:37:59
approved in note was cleared in November
00:38:02
of 2017 and that was for the msk impact
00:38:06
test from Memorial sloan-kettering and
00:38:08
this went through the Genova pathway and
00:38:11
therefore it did not have any specific
00:38:13
companion diagnostic claims associated
00:38:16
with it and then finally later in that
00:38:20
same month on November 30th the
00:38:22
foundation 1c DX test was approved the
00:38:25
p.m. a pathway and that test is from
00:38:27
Foundation medicine so these three FDA
00:38:31
authorizations have really shaped the
00:38:34
current regulatory paradigm for NGS
00:38:37
uncle panels and that's shown here so in
00:38:41
the classical companion diagnostic model
00:38:44
where it was one test for one drug
00:38:47
you only had biomarkers with companion
00:38:52
diagnostic claims but with the recent
00:38:56
clearance of the msk impact panel this
00:39:00
really created some additional levels of
00:39:04
biomarkers that are associated with
00:39:06
different levels of evidence and so you
00:39:11
can see that the while I'll refer to
00:39:13
level 1 biomarkers as those with
00:39:16
companion diagnostic claims level 2
00:39:19
biomarkers are those that are considered
00:39:21
to be cancer mutations with evidence of
00:39:24
clinical significance and level 3
00:39:27
biomarkers are the cancer mutations with
00:39:30
potential clinical significance and I'll
00:39:33
talk about the examples here the uncle
00:39:36
mine test and the foundation one CDX
00:39:39
tests all fit into the level 1 category
00:39:43
but they actually had both level 1 2 & 3
00:39:49
biomarkers while the msk impact test
00:39:52
went through a class-2 pathway and had
00:39:56
only level 2 and level 3 biomarkers but
00:39:59
it's important to note that a test
00:40:01
cannot be cleared with only level 3
00:40:05
biomarkers and so level 3 biomarkers are
00:40:08
obtained along with level 2 and/or level
00:40:12
1 biomarker claims so to talk a little
00:40:16
bit more about each of these three tests
00:40:19
the angka my index target test is a lung
00:40:22
cancer panel the tested text single
00:40:26
nucleotide variants and deletions in 23
00:40:29
dreams from DNA as well as fusions in
00:40:33
the Ross 1 gene from RNA that has been
00:40:35
isolated from FFPE tumor tissue samples
00:40:38
from non-small-cell lung cancer patients
00:40:42
it was the first approved test that
00:40:45
simultaneously assesses variants in
00:40:47
different genes in order to determine
00:40:50
patient eligibility for treatment with
00:40:52
multiple non-small cell lung cancer
00:40:54
targeted therapies and therefore it had
00:40:57
multiple companion diagnostic claims
00:40:59
which are listed here
00:41:01
the first is that the test was approved
00:41:03
to detect b-raf v600 mutations for
00:41:07
treatment with depravity and tremendum
00:41:09
it was approved for the detection of
00:41:12
Ross one fusions for treatment with
00:41:14
crizotinib and it also was approved with
00:41:17
a follow-up companion diagnostic claim
00:41:20
to detect EGFR exon 19 deletions and l85
00:41:24
8 our substitution mutations for
00:41:26
treatment which a fitting in and
00:41:28
therefore this test had both level 1
00:41:32
level 2 and level 3 claims for the msk
00:41:38
impact test the intended use is shown
00:41:41
here the assay is a qualitative in vitro
00:41:46
diagnostic test that uses targeted
00:41:49
sequencing of FFPE tumor tissue matched
00:41:53
with normal specimens from patients with
00:41:55
solid malignant neoplasms in order to
00:41:59
detect tumor gene alterations the test
00:42:02
is intended to detect mutations that
00:42:05
include point mutations and small indels
00:42:07
as well as microsatellite instability
00:42:09
and its intended for use by qualified
00:42:13
healthcare professionals in accordance
00:42:15
with professional guidelines importantly
00:42:18
the test is not conclusive or
00:42:20
prescriptive for labeled use of any
00:42:23
specific therapeutic product and
00:42:25
therefore it does not have the level 1
00:42:28
biomarker or companion diagnostic claims
00:42:34
the msk impact test is a solid tumor
00:42:38
panel it identifies mutations in 468
00:42:43
genes as well as microsatellite
00:42:46
as I mentioned this went through the de
00:42:49
novo pathway and it really established a
00:42:52
class-2 pathway for these NGS uncle
00:42:55
panels that have only level 2 and level
00:42:57
3 claims so these are considered to be
00:43:02
class 2 tumor profiling tests and they
00:43:06
are eligible for third party review
00:43:10
third party review is a program that was
00:43:14
implemented in order to approve the
00:43:16
efficiency and the timeliness of the
00:43:18
510k review process for certain device
00:43:22
types under this program there are
00:43:24
accredited third parties who can conduct
00:43:27
the 510k review and they will provide
00:43:29
the review package as well as their
00:43:32
recommendation to the FDA after they
00:43:35
have reviewed the information and so
00:43:37
really devices under this class can go
00:43:41
through the class to pathway either
00:43:43
through the third party review pathway
00:43:46
or they can directly submit a 510k
00:43:48
submission to the FDA and I'd also like
00:43:52
to note that one of the accredited third
00:43:54
party reviewers for this type of test is
00:43:57
New York State Department of Health so
00:44:03
going back to the regulatory paradigm we
00:44:07
have the three levels of review and we
00:44:10
saw based on the uncle mind test that it
00:44:13
had claims for both level for all of the
00:44:16
levels level 1 level 2 and level 3
00:44:19
importantly the validation for level 1
00:44:22
biomarkers which have companion
00:44:26
diagnostic claims require that
00:44:29
analytical validation is performed for
00:44:32
each marker associated with such a
00:44:35
companion diagnostic acclaim the
00:44:38
clinical claims are established through
00:44:42
a clinical study or for follow-on
00:44:46
companion diagnostics through clinical
00:44:48
concordance results
00:44:52
for level two claims analytical
00:44:56
validation can be conducted per marker
00:44:58
or through representative approach for
00:45:01
SMBs and indels in contrast to the level
00:45:07
one the level of evidence for clinical
00:45:10
validation is that it can be established
00:45:13
in professional guidelines but it does
00:45:16
not have to be demonstrated directly
00:45:18
with the test of interest and then for
00:45:21
level three biomarkers and a little cook
00:45:24
validation is supported through the
00:45:26
representative approach while clinical
00:45:29
validation is not demonstrated either in
00:45:32
professional guidelines or with the test
00:45:34
but rather it's suggestive based on
00:45:37
available evidence and that available
00:45:39
available evidence can include mecca's
00:45:42
mechanistic rationale as well as
00:45:45
published literature so for the last NGS
00:45:51
uncle panel that has recently been
00:45:53
approved this was the foundation once
00:45:55
EDX it's a solid tumor panel and the
00:45:59
test was approved to detect
00:46:01
substitutions in der indels which are
00:46:04
insertions and deletions as well as copy
00:46:07
number alterations in 324 genes as well
00:46:10
as select gene rearrangements it was
00:46:14
also approved to detect two genomic
00:46:16
signatures microsatellite instability
00:46:18
and tumor mutation burden the test was
00:46:23
approved for use with 15 targeted
00:46:26
therapies in five different cancer types
00:46:28
and therefore it had companion
00:46:30
diagnostic claims and it's also intended
00:46:33
to provide tumor mutation profiling in
00:46:36
accordance with professional guidelines
00:46:38
and these are level 2 biomarker claims
00:46:41
importantly this test was the first
00:46:44
breakthrough device to complete the PMA
00:46:46
process and it was the second device to
00:46:49
be reviewed and approved under the fda
00:46:52
CMS parallel review program here's an
00:46:58
excerpt a quick snapshot of the intended
00:47:02
use from the device shown here is table
00:47:05
with all of the companion diagnostic
00:47:08
claims for which the device is approved
00:47:10
you can see here the five different
00:47:13
tumor types are not small cell lung
00:47:16
cancer melanoma breast cancer colorectal
00:47:19
cancer and ovarian cancer along with the
00:47:22
associated biomarkers and therapeutics
00:47:29
so as I mentioned this was the second
00:47:32
IVD that was reviewed and approved under
00:47:35
the fda CMS parallel review program this
00:47:39
parallel review program was piloted in
00:47:42
2011 and fully implemented in 2016 and
00:47:46
it's aimed at reducing the time between
00:47:50
FDA approval of a device and CMS
00:47:53
Medicare coverage so on November 30th
00:47:57
when the FDA approved this device on the
00:48:00
same day CMS issued a proposed national
00:48:03
coverage determination or an NC d for
00:48:06
NGS cancer diagnostics for Medicare
00:48:09
beneficiaries after the public comment
00:48:12
period
00:48:14
CMS finalized the NCD on March 16th of
00:48:18
this year for NGS for Medicare
00:48:21
beneficiaries with advanced cancer the
00:48:26
coverage is for diagnostic laboratories
00:48:29
using NGS tests for patients with
00:48:32
advanced cancer and that's defined as
00:48:35
being recurrent metastatic
00:48:37
relapsed/refractory
00:48:39
or advanced cancer as stages 3 & 4 in
00:48:44
order to get coverage the test must have
00:48:47
FDA approval or clearance as a companion
00:48:49
diagnostic it also must have an
00:48:52
fda-approved or cleared indication for
00:48:55
use in the patient's cancer and the
00:48:58
results should be provided to the
00:49:00
treating physician using a report
00:49:02
template to specify the treatment
00:49:05
options the coverage decision also noted
00:49:08
that coverage for other NGS lab tests
00:49:11
for Medicare patients with cancer are
00:49:14
made by local Medicare administrative
00:49:17
ders and for more information about the
00:49:19
decision memorandum on CMS's NCD the
00:49:23
link is provided at the bottom of this
00:49:25
slide so in conclusion I think the
00:49:31
regulatory models for companion
00:49:34
diagnostics and NGS oncology panels have
00:49:38
really evolved over time due to
00:49:40
increasing efforts and personalized
00:49:42
medicine and a lot of these efforts have
00:49:45
really been driven by device innovation
00:49:48
and device advancements and a couple of
00:49:52
takeaways are that these type to bring
00:49:57
these products to market it takes a lot
00:49:59
of collaboration and coordination
00:50:00
between all of the stakeholders for
00:50:04
example for companion diagnostics it
00:50:06
takes coordination communication between
00:50:09
the diagnostic and the drug sponsors as
00:50:11
well as within the agency between the
00:50:15
review centers the respective review
00:50:17
centers also through programs like third
00:50:20
party review and parallel review it
00:50:23
takes a lot of coordination between
00:50:25
agencies as well as with the device
00:50:28
sponsors as well so with that I'd like
00:50:32
to end here and listed here are a few
00:50:35
additional resources to get some
00:50:37
additional information on some of the
00:50:39
topics that I've discussed today and
00:50:41
also if after this session any questions
00:50:45
arise about specific devices or anything
00:50:47
I've talked about today you can please
00:50:49
feel free to send me any questions at
00:50:52
the email address here thank you very
00:50:54
much

Etiquetas

Molecular Diagnostics
Companion Diagnostics
Next-Generation Sequencing
FDA
In Vitro Diagnostics
Regulatory Framework
Clinical Trials
Biomarkers
Personalized Medicine
Device Innovation