Cancer remains a global challenge, demanding innovative solutions.
Traditional in vivo animal models and 2D in vitro models often fail to replicate the complexities of the human tumor microenvironment (TME), leading to high attrition rates of novel drugs tested in clinical trials.
This whitepaper explores advanced organ-on-a-chip technology and 3D tissue modeling that is closing the translational gap in cancer drug discovery.
Download this whitepaper to uncover:
- Insights from six oncology applications of 3D tumor models, including immune cell migration and CAR T cell therapy development
- How to gain quantifiable results for informed decision-making
- The benefits of a strategic partnership in accelerating new cancer treatment discoveries
Cancer remains a leading cause of death
globally, signaling a critical need for
innovative and effective treatments. This
whitepaper presents MIMETAS, a frontrunner
in organ-on-a-chip technology, as a key player
in advancing comprehensive cancer modeling
to address this need.
The document explores the current landscape
of cancer drug discovery, characterized by
significant advancements in treatments such as
immunotherapies, yet plagued by the challenge
of translating preclinical success into clinical
benefits. The high attrition rates in clinical trials,
especially in oncology, underscore the necessity
for more predictive models that can bridge the
gap between laboratory research and patient
outcomes.
The imperative for predictive models is clear,
with traditional in vivo animal models and 2D in
vitro models falling short in accurately replicating
the human tumor microenvironment (TME).
MIMETAS’ organ-on-a-chip technology presents
a paradigm shift, offering advanced 3D disease
tissue models that mimic the complexity of the
TME, thus facilitating the development of cancer
therapies with higher translational potential.
The whitepaper details MIMETAS’ capabilities
through various oncology applications,
showcasing their success in modeling immune
cell migration, CAR T cell efficacy, and the complex
interactions within the TME. These case studies
illustrate the platform’s ability to replicate human
physiology in vitro, providing a robust platform
for drug discovery, safety testing, and regulatory
approval processes.
Further, the document highlights MIMETAS’
commitment to advancing cancer drug discovery
through partnerships and tailored fee-forservice solutions, leveraging their OrganoCore™
Discovery Platform. A notable collaboration with
Astellas Pharma Inc. is cited as an example of
strategic partnership aimed at driving forward the
next generation of immuno-oncology therapies.
In conclusion, MIMETAS stands at the forefront
of bridging the translational gap in cancer drug
discovery, offering innovative solutions through
its organ-on-a-chip technology. By developing
more predictive models and fostering strategic
partnerships, MIMETAS aims to accelerate the
delivery of effective cancer treatments, ultimately
benefiting patients worldwide.
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Introduction
This whitepaper explores human 3D tissue
and disease models as revolutionary tools
for cancer research and drug discovery. The
focus is on MIMETAS, a leading company in the
organ-on-a-chip field, continuously driving
progress in comprehensive tumor modeling.
Challenges & Advances in
Cancer Drug Discovery
As the second leading cause of death worldwide,
cancer accounted for nearly 10 million deaths in
20201 underscoring the widespread impact of the
disease and the urgent need for new, effective,
and targeted treatments.
The current landscape of cancer drug discovery is
characterized by both significant advancements
and persistent challenges. Recent years have
seen the approval of several groundbreaking
cancer therapies that have significantly improved
the outlook for patients. One notable example
is the development of immunotherapies,
including immune checkpoint inhibitors like
anti-PD1 (Pembrolizumab and Nivolumab), antiPDL1 (Atezolizumab), anti-CTLA4 (Ipilimumab),
T-cell engagers, and chimeric antigen receptor
T-cell (CAR-T) therapies. These therapies work
by enhancing the immune system's ability to
recognize and target cancer cells, representing
a paradigm shift in the treatment of cancer.
Despite these breakthroughs, cancer remains a
global health challenge and a leading cause of
death, most notably for solid tumors.
The translational gap between preclinical studies
and successful clinical trials is a major hurdle in
cancer drug discovery. Clinical trials, particularly
in oncology, face alarmingly low success rates.
While the general approval rates for drugs
hover between 10-20%, the rate for oncology
drugs is even lower, at just 5%, underscoring
the difficulty of developing effective treatments
in this field2,3. This is largely due to the difficulty
of translating preclinical success into clinical
benefits. The cost of drug development in the
pharmaceutical industry is staggering, with
estimates now reaching more than $2.6 billion
per approved drug4. The high attrition rates in
late-stage trials contribute to the substantial
financial burden on the biopharmaceutical
industry, with approximately 70% of research
and development expenses associated with
failed projects5. Successfully overcoming these
challenges is crucial for establishing a strong drug
discovery pipeline and fulfilling the increasing
demand for innovative medications, particularly
in the face of high cancer prevalence rates. This
effort not only accelerates the pace of medical
breakthroughs but also directly impacts the lives
of cancer patients.
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Introduction The Imperative for Predictive Models
A key contributing factor to the high attrition rates seen in cancer drugs is the lack of predictive models.
In vivo animal models, such as patient-derived xenografts (PDXs), while providing important insights, fail
to recapitulate the tumor microenvironment (TME) and suffer from limited translational value to human
conditions12,13 (figure 1). Moreover, animal models in general face increasing ethical debates. On the
other hand, the limitations of traditional 2D in vitro models have become apparent, including a lack of
critical components including vasculature, extracellular matrix (ECM) and neighboring cells, resulting in
less effective research models. While the field has also seen developments in 3D tissue models such
as cell line spheroids and organoids, most 3D in vitro models also lack a comprehensive TME such as
immune components or vascularization14,15. As such, these models fail to accurately reflect the complexity
of solid tumors16 and fail to translate safety and efficacy of novel therapeutics to human trials17-20.
This discrepancy underscores the urgent need for more advanced and representative models in the early
stages of drug development that can accurately predict human responses. Bridging this gap will not only
improve success rates in clinical trials but also expedite the delivery of innovative treatments to patients
in need.
Figure 1. Efficacy of models in cancer drug discovery hampers the success of novel cancer drugs 6-11.
Advances in Organ-on-a-Chip Models
Recent strides in organ-on-a-chip technology indicate promising potential to revolutionize cancer
research, with the pharmaceutical industry seeing an increased adoption of organ-on-a-chip models to
impact pipeline decision-making21. Organ-on-a-chip models mimic complex interactions between cancer
cells, stromal components, and the immune system, bridging the gap between simplistic 2D cultures and
complex animal studies by recapitulating a realistic TME (figure 2). This allows for better assessment
of drug penetration, efficacy, and toxicity. Furthermore, patient-derived tissues in these models bridge
the gap between preclinical studies and actual patient responses, offering a personalized approach to
cancer treatment. This is crucial, given the heterogeneity of cancer and the need for treatments that are
effective across diverse patient populations.
The increased adoption of organ-on-a-chip models was further emphasized by the FDA Modernization
Act 2.022. The recent legislative changes brought about by this act, explicitly permitting companies to
submit non-animal data, including results from organ-on-a-chip technologies, seeking approval of new
therapies, underscore a pivotal shift away from traditional animal-based testing in recognition of the
value of novel technologies.
Translational gap widens
• Species difference
• Immune component
• Micro-environment
Chemo- • Cancer heterogeneity therapy
+Targeted
therapy
(Errb2, TKI)
2d cell lines, xenosgrafts
+Immuno-therapy
(CPI, TCE, CAR-T)
Humanized mice,
organoids
Cancer therapeutics
model requirements
Drug discovery
models
...1960 1980 2000 2020
Advancement in Cancer
Treatments & Models
Year
Phase 1 to approval of cancer drugs remains below 10%
100
90
80
70
60
50
40
30
20
10
0
2005 2010 2015 2020
The main cause
of attrition in
clinical trials is
lack of efficacy
Percentage (%)
Year
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Stromal
shielding
Inflammation Vascularization Metastasis
Tumor
growth
By enabling the study of human physiology in an in vitro setting, organ-on-a-chip models allows for
a deeper understanding of tumor progression mechanisms and provide robust and representative
platforms for drug discovery, safety testing, and seeking regulatory approval for effective cancer
therapeutics.
Figure 2. MIMETAS' proprietary microfluidic platform, the OrganoPlate®, uniquely recapitulates human tissues
by combining relevant cell types to reconstruct the functional niche of native tissues with a fit-for-purpose
throughput, capabilities rarely found across the organ-on-a-chip industry. MIMETAS’ platform enables diverse
and unique in vitro tissue cultures and applications and is distinctively devoid of artificial membranes, allowing
cells to interact and migrate freely under flow conditions in real-time.
Cancer-associated
fibroblasts
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Whitepaper overview
This whitepaper showcases MIMETAS’ capabilities in leveraging their advanced Organ-on-a-Chip
technology to develop 3D disease tissue models, offering an innovative approach to cancer drug discovery
(figure 3). It includes case studies that tackle the primary challenges encountered in models used in
cancer drug discovery: modeling the TME, overcoming the lack of immune competence, and addressing
cancer cell heterogeneity. Through their cutting-edge technology and deep expertise, MIMETAS aims to
revolutionize the discovery of novel cancer treatments, bridging the translational g