3D bioprinting of multi-cellular tumor microenvironment for prostate cancer metastasis

Xu, Kailei; Huang, Yuye; Wu, Miaoben; Yin, Jun; Wei, Peng

doi:10.1088/1758-5090/acd960

Cited by 10 publications

(4 citation statements)

References 59 publications

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“…68 Methacrylated gelatin (GelMA) has been successfully used for co-cultures of prostate cancer cells lines with cells from the TME, and for automated protocols with bioprinting. [69][70][71] Therefore, this approach holds great potential for tackling the next step of introducing patient-derived cells.…”

Section: Advanced Modelingmentioning

confidence: 99%

Defining the challenges and opportunities for using patient‐derived models in prostate cancer research

Brennen,

Le Magnen,

Karkampouna

et al. 2024

The Prostate

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BackgroundThere are relatively few widely used models of prostate cancer compared to other common malignancies. This impedes translational prostate cancer research because the range of models does not reflect the diversity of disease seen in clinical practice. In response to this challenge, research laboratories around the world have been developing new patient‐derived models of prostate cancer, including xenografts, organoids, and tumor explants.MethodsIn May 2023, we held a workshop at the Monash University Prato Campus for researchers with expertise in establishing and using a variety of patient‐derived models of prostate cancer. This review summarizes our collective ideas on how patient‐derived models are currently being used, the common challenges, and future opportunities for maximizing their usefulness in prostate cancer research.ResultsAn increasing number of patient‐derived models for prostate cancer are being developed. Despite their individual limitations and varying success rates, these models are valuable resources for exploring new concepts in prostate cancer biology and for preclinical testing of potential treatments. Here we focus on the need for larger collections of models that represent the changing treatment landscape of prostate cancer, robust readouts for preclinical testing, improved in vitro culture conditions, and integration of the tumor microenvironment. Additional priorities include ensuring model reproducibility, standardization, and replication, and streamlining the exchange of models and data sets among research groups.ConclusionsThere are several opportunities to maximize the impact of patient‐derived models on prostate cancer research. We must develop large, diverse and accessible cohorts of models and more sophisticated methods for emulating the intricacy of patient tumors. In this way, we can use the samples that are generously donated by patients to advance the outcomes of patients in the future.

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Section: Advanced Modelingmentioning

confidence: 99%

Defining the challenges and opportunities for using patient‐derived models in prostate cancer research

Brennen,

Le Magnen,

Karkampouna

et al. 2024

The Prostate

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“…Unlike traditional soft-lithography methods, 3D printers are used to fabricate the microfluidic devices using inorganic or polymer materials of varying chemical compositions, stiffnesses and densities [75]. In the context of prostate cancer, Xu et al (2023) [76], recently fabricated a co-culture system composed of a gelatin methacryloyl/chondroitin sulfate-based hydrogel to examine how hyaluronic acid and cancer-associated fibroblasts, two major components of the tumor microenvironment, influence prostate cancer behaviours. Both PC3 and C4-2b cells lines were used, which have been shown to represent castration-resistant tumors.…”

Section: D-printed Microfluidic Devicesmentioning

confidence: 99%

Microfluidics-Based Technologies for the Assessment of Castration-Resistant Prostate Cancer

Sassi,

You

2024

Cells

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Castration-resistant prostate cancer remains a significant clinical challenge, wherein patients display no response to existing hormone therapies. The standard of care often includes aggressive treatment options using chemotherapy, radiation therapy and various drugs to curb the growth of additional metastases. As such, there is a dire need for the development of innovative technologies for both its diagnosis and its management. Traditionally, scientific exploration of prostate cancer and its treatment options has been heavily reliant on animal models and two-dimensional (2D) in vitro technologies. However, both laboratory tools often fail to recapitulate the dynamic tumor microenvironment, which can lead to discrepancies in drug efficacy and side effects in a clinical setting. In light of the limitations of traditional animal models and 2D in vitro technologies, the emergence of microfluidics as a tool for prostate cancer research shows tremendous promise. Namely, microfluidics-based technologies have emerged as powerful tools for assessing prostate cancer cells, isolating circulating tumor cells, and examining their behaviour using tumor-on-a-chip models. As such, this review aims to highlight recent advancements in microfluidics-based technologies for the assessment of castration-resistant prostate cancer and its potential to advance current understanding and to improve therapeutic outcomes.

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“… Recent 3D bioprinted cancer models for preclinical testing using ( A – C ) breast cancer and osteoblast co-culture [ 162 ] and ( D – F ) prostate cancer and fibroblast co-culture [ 163 ]. ( A ) Schematic diagram of light-activated 3D bioprinting process using cell-laden osteoblast scaffolding seeded with breast cancer cells to model breast cancer metastasis.…”

Section: Figurementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

Preclinical Testing Techniques: Paving the Way for New Oncology Screening Approaches

van Rijt,

Stefanek,

Valente

2023

Cancers

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Prior to clinical trials, preclinical testing of oncology drug candidates is performed by evaluating drug candidates with in vitro and in vivo platforms. For in vivo testing, animal models are used to evaluate the toxicity and efficacy of drug candidates. However, animal models often display poor translational results as many drugs that pass preclinical testing fail when tested with humans, with oncology drugs exhibiting especially poor acceptance rates. The FDA Modernization Act 2.0 promotes alternative preclinical testing techniques, presenting the opportunity to use higher complexity in vitro models as an alternative to in vivo testing, including three-dimensional (3D) cell culture models. Three-dimensional tissue cultures address many of the shortcomings of 2D cultures by more closely replicating the tumour microenvironment through a combination of physiologically relevant drug diffusion, paracrine signalling, cellular phenotype, and vascularization that can better mimic native human tissue. This review will discuss the common forms of 3D cell culture, including cell spheroids, organoids, organs-on-a-chip, and 3D bioprinted tissues. Their advantages and limitations will be presented, aiming to discuss the use of these 3D models to accurately represent human tissue and as an alternative to animal testing. The use of 3D culture platforms for preclinical drug development is expected to accelerate as these platforms continue to improve in complexity, reliability, and translational predictivity.

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3D bioprinting of multi-cellular tumor microenvironment for prostate cancer metastasis

Cited by 10 publications

References 59 publications

Defining the challenges and opportunities for using patient‐derived models in prostate cancer research

Defining the challenges and opportunities for using patient‐derived models in prostate cancer research

Microfluidics-Based Technologies for the Assessment of Castration-Resistant Prostate Cancer

Preclinical Testing Techniques: Paving the Way for New Oncology Screening Approaches

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