3D Printing for Cancer Diagnosis: What Unique Advantages Are Gained?

Zhang, Yu

doi:10.1021/acsmaterialsau.3c00046

Cited by 6 publications

(2 citation statements)

References 147 publications

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“…3D bioprinting technology, one of the recent tissue engineering applications, allows researchers to make progress in cancer tissue modeling with the encapsulation of cells in biomaterials that mimic matrix characteristics and maintain cell viability. This technology enables scalable and relatively rapid manufacture, excellent versatility in cell positioning, and layer-by-layer deposition of biological and chemical components with reproducibility. , While, in 2D models, cells can only attach and proliferate on flat surfaces, which does not recapitulate in vivo cell morphology resulting in poor cell communication, in 3D models, cells can grow in any direction without contacting the surface, leading to better cell–cell and cell–ECM interactions; thus, these models better reflect an in vivo environment . Furthermore, it is possible to fabricate a complex vascular network that delivers nutrients, oxygen, and signaling components to malignant cells using the 3D bioprinting approach .…”

Section: Introductionmentioning

confidence: 99%

Applications of 3D Bioprinting Technology to Brain Cells and Brain Tumor Models: Special Emphasis to Glioblastoma

Ozbek,

Saybasili,

Ulgen

2024

ACS Biomater. Sci. Eng.

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Primary brain tumor is one of the most fatal diseases. The most malignant type among them, glioblastoma (GBM), has low survival rates. Standard treatments reduce the life quality of patients due to serious side effects. Tumor aggressiveness and the unique structure of the brain render the removal of tumors and the development of new therapies challenging. To elucidate the characteristics of brain tumors and examine their response to drugs, realistic systems that mimic the tumor environment and cellular crosstalk are desperately needed. In the past decade, 3D GBM models have been presented as excellent platforms as they allowed the investigation of the phenotypes of GBM and testing innovative therapeutic strategies. In that scope, 3D bioprinting technology offers utilities such as fabricating realistic 3D bioprinted structures in a layer-by-layer manner and precisely controlled deposition of materials and cells, and they can be integrated with other technologies like the microfluidics approach. This Review covers studies that investigated 3D bioprinted brain tumor models, especially GBM using 3D bioprinting techniques and essential parameters that affect the result and quality of the study like frequently used cells, the type and physical characteristics of hydrogel, bioprinting conditions, cross-linking methods, and characterization techniques.

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Section: Introductionmentioning

confidence: 99%

Applications of 3D Bioprinting Technology to Brain Cells and Brain Tumor Models: Special Emphasis to Glioblastoma

Ozbek,

Saybasili,

Ulgen

2024

ACS Biomater. Sci. Eng.

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“…Even by combining patient-derived cells into 3D bioprinted tumor models, researchers can customize diagnostic tests for the unique genetic markers of different cancers. With the significant potential to clarify individual therapeutic reactions and direct treatment decisions, this personalized approach may eventually lead to enhanced patient outcomes [73][74][75].…”

Section: Introductionmentioning

confidence: 99%

Advancement in Cancer Vasculogenesis Modeling through 3D Bioprinting Technology

Shukla,

Yoon,

et al. 2024

Biomimetics

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Cancer vasculogenesis is a pivotal focus of cancer research and treatment given its critical role in tumor development, metastasis, and the formation of vasculogenic microenvironments. Traditional approaches to investigating cancer vasculogenesis face significant challenges in accurately modeling intricate microenvironments. Recent advancements in three-dimensional (3D) bioprinting technology present promising solutions to these challenges. This review provides an overview of cancer vasculogenesis and underscores the importance of precise modeling. It juxtaposes traditional techniques with 3D bioprinting technologies, elucidating the advantages of the latter in developing cancer vasculogenesis models. Furthermore, it explores applications in pathological investigations, preclinical medication screening for personalized treatment and cancer diagnostics, and envisages future prospects for 3D bioprinted cancer vasculogenesis models. Despite notable advancements, current 3D bioprinting techniques for cancer vasculogenesis modeling have several limitations. Nonetheless, by overcoming these challenges and with technological advances, 3D bioprinting exhibits immense potential for revolutionizing the understanding of cancer vasculogenesis and augmenting treatment modalities.

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