Application of 3D bioprinting in cancer research and tissue engineering

doi:10.19401/j.cnki.1007-3639.2024.09.002

Abstract

Abstract:

In recent years, 3D bioprinting technology has developed rapidly, becoming an essential tool in the fields of cancer research, tissue engineering, disease modeling and mechanistic studies. This paper reviewed the fundamental principles of bioprinting technology and its current applications in cancer research and tissue engineering. Bioprinting is an additive manufacturing technology that constructs complex three-dimensional tissue structures by digitally controlling the layer-by-layer deposition of biomaterials and living cells. The core steps of bioprinting include designing a 3D model, selecting appropriate bioprinting techniques and materials, printing layer by layer, followed by post-processing involving cell culture and functionalization. In cancer research, 3D bioprinting can create complex tumor models that simulate the tumor microenvironment, revealing new mechanisms of tumor initiation and progression. Traditional in vitro models, such as 2D cell cultures or animal models, often fail to accurately replicate the complexity of human tumors. However, 3D bioprinted tumor models, which mimic the dynamic interactions between tumor cells and their environment such as immune cells, stroma and blood vessels, offer a more biomimetic platform for studying tumor growth, invasion and metastasis. These models provide a research platform that closely mirrors actual tumor behavior. Additionally, Bioprinted models and scaffolds can be leveraged in personalized precision therapies by efficiently constructing patient-specific 3D models from their own cells. These models enable the prediction of patient’s sensitivity to drugs and radiotherapy. Additionally, localized scaffolds can be developed to meet individual patient needs, allowing for the formulation of appropriate drug types and dosages. Furthermore, 3D-printed scaffolds can support drug delivery by targeting specific areas, reducing drug-related side effects. They can also be used to facilitate local immunotherapy, cytokine therapy, cancer vaccines, and chimeric antigen receptor cell therapy, enhancing therapeutic outcomes. In tissue engineering, traditional tissue repair methods often struggle to address the complex requirements of constructing intricate tissue structures. 3D bioprinting offers a novel solution by enabling the creation of complex tissue architectures and promoting tissue regeneration. Basic tissues, such as bone, cartilage and skin, which have higher regenerative capacities, are gradually being incorporated into clinical practice. Significant progress has also been made in the repair and reconstruction of more complex organs like the liver and heart, though considerable challenges remain before these advancements can be fully translated into clinical applications. Finally, this paper discussed the current challenges and future directions of 3D bioprinting in these fields, aiming to provide reference for researchers.

Key words: 3D bioprinting, Cancer research, Tissue engineering, Tumor microenvironment, Drug screening

CLC Number:

R73-33

WANG Zifei, DING Yahui, LI Yan, LUAN Xin, TANG Min. Application of 3D bioprinting in cancer research and tissue engineering[J]. China Oncology, 2024, 34(9): 814-826.

Figures/Tables 2

Tab. 1

3D bioprinted cancer model"

Cancer type	Primary focus	Bioprinting technique	Bioink or substrate	Cell type	Key outcome
Glioblastoma	Immunity	DLP	GelMA, GMHA	NSCs, astrocytes, GSCs, macrophages	The model simulated the cellular composition, cell density, and matrix stiffness of TME, investigating genetic and morphological changes in the presence and absence of macrophages^[12]
Cholangiocarcinoma	Immunity	EBB	GelMA	RBE, TECs, TAFs, TAMs	A CCA model was established using 3D bioprinting to explore the potential applications of the immune microenvironment in pathological and drug research^[13]
Neuroblastoma	Vascularized	EBB	GelMA	NB, HUVECs	Perusable blood vessels were printed using a support bath, simulating a vascularized tumor model^[14]
Skin squamous cell carcinoma	Vascularized	micro-EBB	Fibrin-collagen hydrogel blend	GFP-HUVECs, fibroblasts, mesenchymal stem cells	The study developed a vascularized 3D-printed bioreactor. First, the PEEK bioreactor was coated with bioink, and vascular structures were bioprinted on top. Spheroids of cancer cells and stromal cells were then placed within the branched vascular structures, allowing for dynamic cultivation^[15]
Melanoma	Metastasis	EBB	VdECM	HDMECs, HDLECs, HDF, SK-MEL-28	The system recapitulated hallmark events of metastatic melanoma, such as tumor-stroma interactions, melanoma invasion and intravasation^[16]
Glioblastoma	Stroma	EBB	BdECM,	GBM, HUVECs	The model recapitulated the structural, biochemical, and biophysical properties of the tumor, exploring the impact of mechanical properties of TME on the tumor^[17]
Breast cancer	Stroma	EBB	Pronova UP LVG Sodium Alginate, gelatin	Breast cancer cell (MCF-7, SKBR3, HCC1143, MDA-MB-231), HMFs, MSCs/SPA, HUVECs	3D bioprinted tumor models of breast cancer cells with different phenotypes exhibit distinct microenvironmental characteristics, and the different stromal cells have varying impacts on the tumors^[18]
Liver cancer	Highthroughput screening	EBB	Pluronic F127 and sodium alginate	HepG2/C3A	Provide an effective in vitro model for hepatotoxicity testing^[19]
Lung cancer	Drug screening	PDL	PEO/GelMA	LL/2, A549, NCI-H1975	Compared with 2D cultured lung cancer cells, cells in porous microgel are more similar to those extracted from the existing gold standard: mouse transplanted tumors, in terms of the ROCK-actin pathway^[20]
Colorectal cancer	Drug screening	EBB	Gelatin	SW480, THP-1, HUVECs	Compared with 3D bioprinted single-cell model (3D printing-S), 3D bioprinted multicellular models (3D printing-M) showed significantly improved expression of tumor-related genes, 3D printing-M group was significantly more resistant to chemotherapy^[21]

Tab. 1

Tab. 2

Application of 3D bioprinting tissue engineering"

Organ/tissue type	Function	Bioprinting technique	Bioink or substrate	Cell type	Key outcome
Full-thickness skin model	Skin regeneration	EBB	Fibrinogen	keratinocytes, melenocytes, fibroblasts, FDPCs, DMECs, adipocytes	This study simulated a three-layered skin structure composed of the epidermis, dermis, and subcutaneous tissue. This approach promotes skin regeneration at the injury site and achieves non-fibrotic wound healing^[47]
Osteochondral tissue	Osteochondral tissue repair	DLP	HAMA, GelMA	hADSCs	The bilayer structure design combines the characteristics of osteogenesis and chondrogenesis, effectively mimicking the natural bilayer structure of bone and cartilage tissues, thereby promising better tissue repair outcomes^[48]
Bone organoids	Bone tissue generation	DLP	GelMA/AlgMA/HAP	BMSCs	This study conducted large-scale 3D bioprinting of bone organoids. In vivo, these bioprinted bone organoids effectively guided osteogenesis, mineralization, cell layer formation, plasticity, and remodeling^[49]
Human cardiac models	Engineer components of the human heart at various scales	FRESH	Collagen	C2C12, VEGFs	The study presents a method to 3D-bioprint collagen using FRESH to engineer components of the human heart at various scales, from capillaries to the full organ^[50]
Vascularized mini-liver	Liver regeneration and increases in cell proliferation	EBB	External ink (sodium alginate, gelatin fibrinogen) and an internal ink (gelatin, hyaluronic acid sodium salt, thrombin)	hASCs, HUVECs	The 3D bioprinted vascularized mini-liver, after inducing hepatocyte differentiation in vitro, shows enhanced liver function. Upon subcutaneous implantation, this mini-liver effectively improves liver regeneration in two ALF animal models^[51]
Alveolar model	Simulating a vascularized alveolar model	SLATE	Photocurable hydrogels, food dyes	RBCs, HUVECs, Hepatocytes, hMSCs, Lung Fibroblasts, Epithelial-like Cells	Creating three-dimensional biomaterials with complex vascular networks capable of simulating the fluid transport and biochemical properties of real organs. Mathematical space-filling and fractal topology algorithms were used to design a 3D model that mimics alveolar morphology and oxygen delivery^[52]
Cerebral cortical tissue	Personalized implantation treatments	DBB	Matrigel	hiPSCs	The study induces hiPSCs to DNs and UNs, using a droplet printing technique to fabricate tissues comprising simplified cerebral cortical columns and implanting the printed single-layer cortical tissue into brain explants^[53]
Intestinal model	Simulating an intestinal model with a finger-like villus structure	EBB	Collagen, SIS	HUVECs, Caco-2	In vitro cellular activities demonstrated that the proposed cell-laden collagen/dECM villus structure generates a more meaningful epithelium layer mimicking the intestinal structure, compared with the pure cell-laden collagen villus structure having similar villus geometry. This dECM-based 3D villus model will be helpful in obtaining a more realistic physiological small-intestine model^[54]
Kidney organoid	Evaluation of nephrotoxicity of new drugs	EBB	Cell paste	iPSC	3D bioprinted kidney organoids exhibit morphological and structural similarities to manually prepared kidney organoids. Drug response tests were conducted, and the impact of the initial cell micro-aggregates used in 3D bioprinting on the final organoids was investigated^[55]

Tab. 2

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