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Biopolymer-Based 3D Printing for Dental–Pulp Complex Tissue Regeneration: Innovations and Challenges

Submitted:

25 May 2026

Posted:

27 May 2026

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Abstract
The regeneration of the dentin-pulp complex remains a major challenge in regenerative endodontics. While conventional therapeutic approaches are effective in eliminating infection and preserving dental structure, they fail to restore the biological functionality of the pulp tissue. In recent years, three-dimensional (3D) printing and biopolymer-based bioprinting have opened unprecedented opportunities in dental tissue engineering, enabling the fabrication of biomimetic scaffolds with precisely controlled structural and bioactive properties. This review synthesizes current advances in bioprinting technolo-gies, the diversity of biomaterials and bioinks employed, and the various stem cell sources utilized in pulp regeneration. It further examines how the three-dimensional microenvironment modulates cell viability, odontogenic differentiation, and the pro-motion of angiogenesis and neurogenesis, emphasizing the role of scaffold composition, mechanical properties, and internal architecture in influencing regenerative outcomes. Additionally, persistent challenges are discussed, including the optimization of bioink formulations, the achievement of functional vascular integration, and long-term valida-tion of regenerated tissues, underscoring the need for multidisciplinary strategies to fa-cilitate clinical translation. By integrating recent evidence, this review establishes a conceptual framework for the development of personalized and predictable approaches to dentin-pulp complex reconstruction.
Keywords: 
biopolymers
;  
3D printing
;  
tissue engineering
;  
regenerative dentistry
;  
pulp regeneration
;  
scaffolds
;  
bioink
Subject: 
Chemistry and Materials Science  -   Medicinal Chemistry

1. Introduction

Although substantial advances have been achieved in endodontic therapy, the regeneration of a fully functional dentin–pulp complex remains one of the most challenging and unresolved goals in dental tissue engineering. Conventional endodontic treatments are highly effective in eliminating infection and preserving dental structure; however, they fail to restore the biological functionality of the dental pulp, including sensory perception, immune defense, vascularization, and physiological dentin formation. Consequently, regenerative strategies aimed at reconstructing a functional dentin–pulp unit have become a central focus of contemporary dental research [1,2,3]. Research in regenerative medicine has increasingly focused on the development of advanced biomaterials and fabrication strategies capable of restoring tissue architecture and functional integration, moving beyond the mere replacement of lost structures. In this context, biomimetic three-dimensional (3D) scaffolds have attracted growing attention due to their ability to provide not only structural support but also biochemical and biophysical cues that regulate cell proliferation, differentiation, and spatial organization [4,5,6]. Ideally, such constructs should combine high biocompatibility with controlled biodegradation kinetics, allowing the gradual replacement of the scaffold with newly formed tissue while maintaining mechanical stability throughout the regenerative process [7,8].
The fabrication of scaffolds for dental tissue engineering has evolved considerably over recent decades. Early approaches relied on conventional processing techniques such as electrospinning, freeze-casting, gas foaming, and solvent casting [9,10,11,12]. Although these methods have contributed to the development of scaffolds capable of supporting tissue regeneration, they generally offer limited control over internal scaffold architecture, particularly regarding spatial organization and pore uniformity. Moreover, these processes may pose challenges in removing residual compounds and do not consistently enable accurate reproduction of the complex geometries required to mimic native tissues [13]. To overcome these limitations, additive manufacturing technologies, particularly 3D printing and bioprinting [14], have emerged as transformative tools in dental tissue engineering (Figure 1).
These techniques enable the layer-by-layer fabrication of complex, patient-specific constructs with tunable porosity, geometry, and functional properties. Although bioprinting is an extension of conventional 3D printing, the two approaches differ fundamentally in their design philosophies. Traditional 3D printing primarily focuses on the fabrication of mechanically stable scaffolds that are subsequently seeded or functionalized with biological components, whereas bioprinting integrates living cells, growth factors, and bioactive materials directly during the fabrication process [15,16,17], enabling the creation of biologically active and spatially organized constructs (Figure 2).
Despite significant progress in scaffold design, biomaterial development, and stem cell-based therapies, achieving predictable regeneration of a fully functional dentin–pulp complex remains a major challenge. In particular, the coordinated regulation of multiple biological processes, including vascularization, innervation, and organized dentinogenesis within engineered three-dimensional environments, remains difficult to achieve. Furthermore, discrepancies between promising in vitro findings and the variable outcomes observed in vivo underscore the need for a comprehensive synthesis of current fabrication strategies and their biological performance. Emerging evidence suggests that regenerative success is determined less by the printing modality itself and more by the engineered three-dimensional microenvironment that governs stem cell fate, tissue integration, and long-term functional stability. Understanding how scaffold composition, mechanical properties, architectural organization, and cellular distribution collectively influence regenerative outcomes is therefore essential for advancing translational endodontic therapies. Accordingly, this review aims to critically evaluate recent advances in the application of 3D printing and bioprinting for dentin–pulp complex regeneration, with particular emphasis on scaffold fabrication techniques, biomaterial selection, stem cell sources, and the biological outcomes reported in both in vitro and in vivo studies. By synthesizing current evidence, identifying key challenges, and highlighting emerging opportunities, this review seeks to establish a robust conceptual framework for future progress in regenerative endodontics.

2. Fabrication Techniques for 3D Scaffolds with Regenerative Potential

The regenerative performance of 3D scaffolds is profoundly influenced by the fabrication strategy employed, as processing parameters directly determine internal architecture, cellular distribution, mechanical properties, and post-implantation biological behavior. In this context, the development of additive manufacturing technologies has enabled unprecedented control over construct geometry, facilitating the design of biomimetic structures capable of supporting cellular organization, vascular infiltration, and guided tissue regeneration [18,19]. In both 3D printing and bioprinting, the creation of a digital model is an essential prerequisite prior to fabrication. These models can be generated using computer-aided design (CAD) software or derived from medical imaging techniques such as computed tomography (CT), magnetic resonance imaging (MRI), or radiography, thereby enabling the precise reproduction of the desired three-dimensional morphology [20,21].
Current 3D printing technologies can be broadly classified into three main categories based on the material deposition mechanism: inkjet printing (IJP), extrusion-based printing (EBP), and light-assisted printing (LAP) (Figure 3). These systems have subsequently been adapted for bioprinting applications to enable the processing of biomaterials and living cells while maintaining the core operational principles of conventional printing platforms [19].

2.1. Inkjet-Based Bioprinting

Inkjet-based bioprinting (IJP) relies on the controlled generation of biomaterial droplets through thermal or piezoelectric actuation. In thermal systems, rapid heating induces bubble formation, facilitating the expulsion of material through the nozzle, whereas piezoelectric systems employ pressure waves to generate discrete droplets [22,23]. This technique offers high processing speed and superior spatial resolution compared to extrusion-based methods, making it particularly suitable for generating fine cellular patterns and replicating tissue microarchitecture. Additionally, it is characterized by high operational flexibility and relatively low cost. However, the requirement for low viscosity bioinks limits both achievable cell density and the mechanical stability of the resulting constructs [24]. Furthermore, exposure to thermal and mechanical stresses may negatively affect cell viability, droplet uniformity, and cell encapsulation efficiency [25]. Compared to LAP, IJP-based bioprinting exhibits lower scalability and limited capacity for generating volumetric structures, which represents a significant constraint for endodontic applications requiring complete root canal filling. Consequently, this method is best suited for the fabrication of functional microstructures or localized cell delivery systems, although its translation to large-scale clinical applications requires further optimization of bioink rheology and post-printing stability [17,26].

2.2. Extrusion-Based Bioprinting

Extrusion-based bioprinting (EBP) is one of the most widely used technologies in regenerative dental medicine due to its material versatility, scalability, and accessibility [27]. This approach utilizes either pneumatic systems driven by compressed air or mechanical systems based on pistons or screws, enabling continuous material deposition through a nozzle [28]. Printing platforms are typically equipped with thermally controlled dispensing systems and movable stages that allow positioning along the x, y, and z axes, facilitating the fabrication of complex three-dimensional constructs. Technologies such as fused deposition modeling (FDM) and direct ink writing (DIW) are based on this controlled extrusion principle [29].
A major advantage of EBP is its ability to process high-viscosity biomaterials and accommodate elevated cell densities, enabling the fabrication of large and scalable constructs compared to other methods limited by rheological constraints [23]. However, the resolution of extrusion-based constructs is generally lower than that of other techniques, and the extrusion of highly viscous materials may subject cells to shear stress, adversely affecting viability [30]. Consequently, bioink selection is critical for maintaining structural fidelity after deposition and ensuring overall construct integrity. Although low viscosity bioinks are more challenging to process using this method, support bath printing strategies have emerged as a promising solution to overcome these limitations [31,32]. This approach is particularly attractive for dental applications due to its scalability and flexibility in bioink design. Nevertheless, optimization of shear-thinning behavior remains essential to ensure both cell survival and geometric fidelity, especially in the context of complex dentin-pulp structures.

2.3. Light-Assisted Bioprinting

Light-assisted bioprinting (LAP) is based on the photopolymerization of materials under laser or light exposure, enabling the fabrication of high-resolution three-dimensional constructs. This category includes several techniques, such as Laser-Induced Forward Transfer (LIFT), stereolithography (SLA), and Digital Light Processing (DLP). In LIFT, a laser pulse transfers biomaterial onto a target substrate; SLA uses a laser or ultraviolet (UV) light to selectively solidify a photosensitive polymer; and DLP builds upon SLA by projecting digital light patterns to polymerize entire layers simultaneously [6,19]. As these methods do not rely on nozzles, issues related to clogging are eliminated, allowing the processing of a broader range of bioink viscosities. Light-assisted techniques offer exceptionally high resolution, precise spatial control over cell placement, and the ability to fabricate constructs with high cell densities (up to 1 × 10⁸ cells/mL), resulting in excellent structural fidelity [26]. These approaches have shown considerable promise in dental applications, including dental pulp and tooth germ regeneration, by supporting epithelial–mesenchymal interactions and promoting pulp revascularization [19].
Despite these advantages, several limitations remain. Material selection is restricted to photosensitive polymers, often requiring chemical modification to ensure compatibility with photopolymerization processes. Additionally, photopolymers are distributed throughout the entire resin reservoir, including non-target regions, potentially leading to material waste and increased costs. The presence of photoinitiators and free radicals may also adversely affect cell viability, while exposure to UV light can induce cellular stress [6,26]. Overall, LAP represents a powerful approach for the fabrication of high-precision, high-cell-density scaffolds, particularly in the context of dental pulp regeneration. Continued optimization of bioink composition and the development of biocompatible photopolymerization systems are essential for successful clinical translation.

3. Materials Used in the Fabrication of 3D Scaffolds with Regenerative Potential for the Dentin-Pulp Complex

Within 3D printing technologies applied to dental tissue regeneration, a broad range of biomaterials can be utilized, including synthetic polymers, ceramic materials, hydrogels, and various composite systems [19]. Given that these scaffolds are frequently seeded with stem cells or loaded with bioactive molecules, they must exhibit adequate biocompatibility, controlled biodegradability, and structural properties that support three-dimensional cellular organization, vascularization, and nutrient diffusion. Porosity represents a critical parameter for facilitating cell adhesion and proliferation, while the incorporation of growth factors or other bioactive agents can accelerate differentiation and tissue maturation. Furthermore, material selection enables the tuning of mechanical properties and degradation kinetics, allowing scaffolds to provide temporary structural support while being gradually resorbed and replaced by host tissue. In this context, both biodegradable synthetic polymers and extracellular matrix (ECM)-derived materials, as well as composite systems [33,34], have demonstrated significant potential for the development of functional constructs for pulp–dentin tissue engineering (Figure 4).

3.1. Biodegradable Synthetic Polymers

Polycaprolactone (PCL) is one of the most widely used synthetic polymers in three-dimensional bioprinting, including dental regenerative applications, due to its favorable mechanical properties, biocompatibility, and relatively low melting temperature (approximately 60 °C), which enables controlled extrusion through fine nozzles. Additionally, its long-term structural stability makes it suitable as an implantable material capable of maintaining scaffold integrity throughout tissue remodeling [35]. However, the use of PCL as a standalone material is limited by its hydrophobic nature and slow degradation rate, both of which are associated with reduced cell adhesion and bioactivity. To address these limitations, numerous studies have explored hybrid systems combining PCL with bioactive materials such as calcium-based bioceramics, bioactive glasses (BG), ECM-derived components, and hydrogels, as well as surface functionalization strategies using molecules such as hyaluronic acid (HyA). These approaches enhance mechanical performance, modulate degradation behavior, and promote cellular infiltration and vascularization, thereby supporting more effective tissue regeneration [36]. Nejad et al. (2021) fabricated PCL-based scaffolds in an in vitro study aimed at promoting dentin–pulp complex regeneration. Two scaffold types were developed: PCL incorporated with bioactive glass (BG) and PCL functionalized with HyA. Human dental pulp stem cells (hDPSCs) were used to evaluate cellular behavior and differentiation potential. The results demonstrated that BG improved mechanical properties, surface roughness, and scaffold bioactivity, while HyA increased hydrophilicity and enhanced cell adhesion. Moreover, the expression of odontogenic markers—dentin sialophosphoprotein (DSPP), osteocalcin (OCN), and dentin matrix protein 1 (DMP-1)—was significantly upregulated in these systems [13]. Huang et al. (2018) developed a PCL-based scaffold loaded with bone morphogenetic protein-2 (BMP-2) incorporated into mesoporous calcium silicate (MesoCS). Using hDPSCs, the study demonstrated that PCL combined with calcium-based compounds exhibits significant odontogenic inductive potential. Enhanced cell adhesion, proliferation, and alkaline phosphatase (ALP) activity were observed in mesoporous scaffolds. Although primarily applicable to hard tissue regeneration, this system may also facilitate blood clot stabilization and promote odontogenesis in reparative endodontic therapies [37].
Polylactic acid (PLA) represents another class of thermoplastic polymers extensively investigated in tissue engineering. It is widely used in 3D printing for regenerative endodontics due to its excellent biocompatibility and biodegradability. Although PLA exhibits a controllable degradation rate, it may induce non-bacterial local inflammatory responses due to the release of acidic degradation byproducts [38,39]. Hsiao et al. (2019) demonstrated that PLA-based scaffolds, both alcohol-treated and coated with poly-L-lysine (PLL), improved hDPSC adhesion and did not induce significant local inflammatory responses, suggesting partial neutralization of acidic degradation products in vivo [39]. Chen et al. (2021) applied hydroxyapatite (HA) coatings to PLA scaffolds in an in vivo canine model. The results revealed significantly enhanced mineralization in the experimental group, where scaffolds were seeded with dental pulp stem cells, compared to acellular controls. These findings highlight the capacity of dental pulp stem cells to undergo lineage-specific differentiation on HA/PLA substrates. However, a key limitation was the slow degradation rate, as scaffolds were not fully resorbed even after nine months [40].

3.2. Biomimetic Bioinks

In contrast to conventional 3D printing, which primarily employs synthetic materials for structural purposes with subsequent biological functionalization, bioprinting relies on specially designed materials known as bioinks. These materials enable the direct incorporation of living cells and bioactive factors during the layer-by-layer fabrication process. Bioinks may consist of natural polymers such as collagen, gelatin, alginate, hyaluronic acid (HyA), chitosan, and fibrin, as well as synthetic polymers such as polyethylene glycol dimethacrylate (PEGDMA) or copolymers based on polyethylene glycol (PEG) and polypropylene glycol (PPG). To optimize rheological and biological performance, chemically modified biopolymers are frequently employed, including gelatin methacryloyl (GelMA) and methacrylated hyaluronic acid (HAMA). In many formulations, these components are combined with bioactive bioceramics, contributing to the formation of stable three-dimensional constructs and enhancing cell–material interactions that mimic the native extracellular matrix [41,42]. Natural polymer-based bioinks represent the most widely used class in bioprinting due to their similarity to the native extracellular matrix and biological microenvironment. Among these, type I collagen is one of the most extensively used materials in regenerative endodontics, as it promotes dental pulp stem cell proliferation and upregulates genes associated with odontogenic differentiation, making it highly suitable for pulp regeneration applications [43,44,45]. Duarte Campos et al. (2019) developed a bioink composed of type I collagen and agarose in an in vitro study. The results confirmed the biocompatibility of hydrogel-based constructs with dental pulp stem cells and demonstrated the formation of functional vascular networks, highlighting the potential of bioprinting approaches for in situ dental applications [46].
Despite their excellent biocompatibility, natural polymers often exhibit limited mechanical strength. Therefore, their combination with synthetic polymers provides improved mechanical stability and tunable physical properties [41]. Recent research has focused on hybrid hydrogels that integrate the biological advantages of natural polymers with the controllable characteristics of synthetic materials. Gelatin methacryloyl (GelMA) is one of the most extensively studied biomaterials in regenerative dentistry. At the molecular level, gelatin contains arginine–glycine–aspartic acid (RGD) sequences that promote cell adhesion, as well as sequences susceptible to matrix metalloproteinases (MMPs), enabling matrix remodeling and facilitating cell migration. Chemical modification of gelatin through the introduction of methacrylate groups allows the formation of stable crosslinked hydrogels suitable for bioprinting applications [47]. Monteiro et al. (2016) developed a biomimetic 3D tooth bud model consisting of epithelial and mesenchymal cell layers combined with enamel organ- and pulp organ-like structures fabricated from GelMA hydrogels. In vitro analyses demonstrated the expression of key developmental markers, including Sonic Hedgehog (SHH), BMP2, and Runt-related transcription factor 2 (RUNX2), indicating active epithelial–mesenchymal interactions. Subsequent in vivo studies, involving subcutaneous implantation in a rat model, revealed the formation of mineralized tissues and sustained expression of differentiation markers, reflecting processes relevant to dentin formation and pulp regeneration [48]. In another in vivo study, Cunha et al. (2023) applied GelMA hydrogels in direct contact with dental pulp tissue. The results demonstrated the formation of organized pulp-like tissue, tertiary dentin, tubular and atubular dentin, and neovascularization, suggesting that GelMA represents a promising material for regenerative pulp therapies and dentin formation [49].

4. Stem Cell Types for 3D Biofabrication of Dental Tissues

A fundamental component of modern tissue regeneration strategies is the use of stem cells, characterized by their capacity for self-renewal and to generate progenitor cells that can differentiate into multiple specialized cell types. In the context of dental tissue reconstruction, the selection of an appropriate cell population, compatible with the biological characteristics of the target tissue, represents a critical determinant for achieving a predictable regenerative response, given the variability in differentiation potential among different stem cell types [50,51].

4.1. Origin and Types of Dental and Non-Dental Stem Cells

From the perspective of origin, the literature describes multiple populations of mesenchymal stem cells (MSCs) of dental origin, including dental pulp stem cells (DPSCs), stem cells from human exfoliated deciduous teeth (SHED), dental follicle progenitor cells (DFPCs), tooth germ progenitor cells (TGPCs), stem cells from the apical papilla (SCAP), periodontal ligament stem cells (PDLSCs), alveolar bone marrow stromal cells (ABMSCs), and gingiva-derived mesenchymal stem cells (GMSCs) [52,53]. In parallel, dental tissue engineering research has explored the use of non-dental stem cell sources, such as bone marrow-derived mesenchymal stem cells (BMSCs), human umbilical vein endothelial cells (HUVECs), amniotic fluid stem cells (AFSCs), and adipose-derived stem cells (ADSCs), due to their regenerative and angiogenic potential [27]. Stem cells of oral origin are considered particularly promising for pulp regeneration due to their enhanced capacity to differentiate into cell types specific to the dental microenvironment. Among these, dental pulp stem cells have been extensively investigated, owing to their shared origin with the target tissue, which facilitates functional integration and promotes differentiation toward appropriate cellular phenotypes [54,55]. Nevertheless, the survival, proliferation, and controlled differentiation of stem cells remain major challenges in dentin–pulp complex regeneration, given the structural complexity and cellular heterogeneity of this tissue. Although the formation of vascularized tissue is frequently reported in experimental studies, the predictable regeneration of a fully functional pulp—characterized by proper innervation and organized tubular dentinogenesis—remains difficult to achieve [56].

4.2. Cell Viability, Microenvironment, and Growth Factors

The success of regenerative processes is strongly influenced by the biological properties of the stem cell populations used, including their source-dependent differentiation potential, which underscores the importance of appropriate cell selection for functional tissue regeneration [57]. In this regard, dental mesenchymal stem cells exhibit multipotent differentiation capacity, being able to generate osteogenic/odontogenic and neurogenic lineages, thereby contributing to the regeneration of both structural and functional components of the dental pulp [58]. A major advantage of autologous stem cells is their high immunological compatibility and reduced risk of immune rejection, attributable to their inherent immunomodulatory properties [59]. To maintain stem cell viability and regenerative potential, the presence of a favorable pulp microenvironment is essential. This includes appropriate biochemical, physical, and mechanical conditions, such as controlled oxygen levels, interactions with the extracellular matrix, and biomechanical stimuli that support cell proliferation and differentiation [60,61]. In addition to the supportive microenvironment, growth factors play a crucial role in regulating stem cell behavior. They stimulate cell proliferation, migration, and differentiation, thereby enhancing the efficiency of regenerative processes [62]. Numerous growth factors have been identified as key regulators of dental pulp stem cell activity. For example, Yang et al. (2015) demonstrated that basic fibroblast growth factor (bFGF) promotes dentinogenesis, angiogenesis, and neurogenesis [63]. Furthermore, factors such as vascular endothelial growth factor (VEGF), bone morphogenetic proteins (BMP-2, BMP-4, BMP-7), transforming growth factor beta-1 (TGF-β1), fibroblast growth factor-2 (FGF-2), and platelet-derived growth factor (PDGF) are frequently incorporated into regenerative strategies to stimulate proliferation, induce odontogenic differentiation, and promote vascular network formation [62,64]. In this context, restoring pulp functionality requires not only structural reconstruction but also the re-establishment of a microenvironment capable of supporting metabolic exchange and biological signaling. Vascularization and innervation are essential components, contributing to tissue homeostasis, sensory function, and the delivery of nutrients and oxygen to newly formed cells [56]. Duarte Campos et al. (2020) utilized DPSCs in combination with HUVECs and angiogenic growth factors such as VEGF to stimulate neovascularization. Bioprinting enabled precise spatial positioning of cells and growth factors, facilitating controlled vascular regeneration, which is essential for restoring pulp function [46]. Similarly, Qian et al. (2023) demonstrated that GelMA microspheres loaded with human DPSCs promoted both angiogenesis and neurogenesis during pulp tissue regeneration, as evidenced by the expression of neuronal markers such as microtubule-associated protein 2 (MAP2) and vascular markers such as cluster of differentiation 31 (CD31) [65].

5. In Vitro Evaluations

In vitro studies represent the initial stage in the evaluation of bioprinting strategies, providing a controlled framework for analyzing cell viability and proliferation, scaffold biocompatibility, and the expression of odontogenic differentiation markers, as well as for investigating the influence of the mechanical and biochemical microenvironment on cellular behavior. A summary of the main bioprinting systems, materials, and fabrication parameters used across the analyzed studies is presented in Table 1.
The analyzed data indicate that, under optimized printing parameters, the fabrication technology itself is not the primary determinant of cell survival. Where reported, post-printing viability frequently exceeds 90% across most systems, including fibrin-based bioinks (≈3 × 10⁶ cells/mL) and alginate–dentin constructs (0.8 × 10⁶ cells/mL). However, significant variations arise depending on composition. For example, viability values exceeding 95% have been reported in fibrin–gelatin bioinks incorporating demineralized dentin matrix, compared to approximately 65% in non-functionalized alginate, highlighting the critical role of matrix bioactivity [66,67,68].
In contrast, scaffold composition exerts a decisive influence on subsequent biological responses. Bioinert materials such as PCL or plain alginate support baseline cell viability but induce limited differentiation. The incorporation of bioactive components—including bioactive glass (BG), calcium silicate, dentin matrix, or Biodentine (BD)—results in consistent increases in DSPP and DMP-1 expression and enhanced mineralization. For instance, increases of up to 6–11-fold in calcium deposition have been reported in BD/PCL scaffolds compared to controls, alongside the overexpression of odontogenic markers in PCL/BG and demineralized dentin matrix powder (DDMp) systems [13,68,69]. Hybrid formulations such as gelatin methacryloyl/alginate/cellulose nanocrystals (GelMA/Alg/CNC) have demonstrated up to a 2.2-fold increase in odontogenic marker expression in optimized variants, confirming the regulatory role of the cell–matrix biochemical interface in differentiation [70]. The mechanical and compositional properties of the scaffold matrix act synergistically in directing cellular differentiation. Scaffolds with higher stiffness and the ability to release bioactive ions (Ca²⁺, Si⁴⁺) promote mineralization and odontogenic differentiation, whereas hydrogels with lower stiffness (≈1–2 kPa), closer to that of native pulp tissue, support a pulp-like phenotype and enhanced cellular proliferation. In this context, calcium silicate-enriched bioinks have demonstrated increased cell viability and odontogenic marker expression in an ion-dependent manner, suggesting that the release of bioactive ions is a key regulator of differentiation [67,71].
Scaffold architecture also contributes significantly to biological performance. Filament diameters in the range of 200–500 μm and intermediate pore sizes (≈400–700 μm) have been associated with improved cell adhesion and alkaline phosphatase (ALP) activity. For example, pore sizes of approximately 421 μm have been shown to induce higher ALP activity compared to larger structures (~700 μm), indicating the existence of an optimal range for cell–matrix interactions [13,72]. Additionally, surface functionalization through increased roughness and hydrophilicity (e.g., via plasma treatment and hyaluronic acid coating) significantly enhances cell adhesion and promotes a pulp-like phenotype [13]. In the context of pulp regeneration, angiogenic potential represents a critical factor. Co-culture systems of human dental pulp stem cells (hDPSCs) and human umbilical vein endothelial cells (HUVECs) have demonstrated the formation of CD31-positive vascular networks, with superior performance observed in fibrin-based hydrogels compared to collagen, where vascular tube length was significantly greater (p < 0.05), highlighting the importance of scaffold composition in supporting angiogenesis [46].
Overall, in vitro data indicate that, once technical parameters are optimized, biological outcomes are predominantly determined by the three-dimensional microenvironment, bioactive composition, mechanical properties, and scaffold architecture, all of which actively modulate the behavior and differentiation of dental stem cells. The corresponding in vitro biological outcomes, including cell viability, differentiation, and mineralization responses, are summarized in Table 2.

6. In Vivo Studies

In vivo studies are essential for evaluating the clinical applicability of bioprinting strategies, as they integrate complex processes such as vascularization, immune response, and tissue remodeling. Experimental models, including ectopic, orthotopic, and critical-sized bone defect models, enable the differential analysis of these processes and provide valuable insights into construct behavior under physiologically relevant conditions. An overview of the in vivo bioprinting constructs, materials, and fabrication approaches is presented in Table 3.
In ectopic subcutaneous animal models, construct performance is primarily determined by bioactive composition and porous architecture. GelMA hydrogels with microporosity (~20–50 μm) and elasticity of approximately 40 kPa have been shown to support cell viability and induce mechanotransduction activation (Yes-associated protein, YAP), which correlates with significant increases in osteogenic/odontogenic markers (RUNX2, OCN, DSPP), along with effective tissue integration and cellular infiltration [75]. Similarly, scaffolds based on decellularized extracellular matrix/beta-tricalcium phosphate (dECM/β-TCP) have demonstrated a critical balance between bioactivity and cytocompatibility. Optimal concentrations (~20 wt% β-TCP) maintained cell viability at approximately 96–97%, whereas higher concentrations reduced cytocompatibility, suggesting the existence of a threshold for stiffness and mineral content [76]. Orthotopic models further highlight the importance of controlled three-dimensional organization. The implantation of GelMA microspheres loaded with dental pulp stem cells (DPSCs) resulted in complete regeneration of vascularized pulp-like tissue along the entire root canal length within 4–8 weeks, accompanied by odontoblast-like organization and increased expression of angiogenic and neurogenic markers (VEGFα, CD31, microtubule-associated protein 2 (MAP2), growth-associated protein 43 (GAP43)). In contrast, cell delivery in suspension resulted in limited and non-uniform regeneration, indicating that a defined three-dimensional architecture is essential for maintaining cell viability and achieving functional integration [65]. In critical-sized bone defect models, 3D-printed hydroxyapatite/polylactic acid (HyA/PLA) scaffolds loaded with dental pulp stem cells demonstrated significant increases in mineralized volume and the formation of dentin- and bone-like structures in long-term evaluations (up to 9 months), as confirmed by micro-computed tomography (micro-CT) and histological analyses. However, partial scaffold degradation suggests an imbalance between resorption rate and tissue formation, highlighting the need for optimization of biomaterial degradation kinetics [40]. A consistent finding across the analyzed studies is the critical role of vascularization. Microporous scaffolds and dECM-based systems have demonstrated increased vascular density and significant VEGF expression without marked inflammatory responses, indicating a favorable microenvironment for tissue integration and functional regeneration [75,76]. A summary of the in vivo experimental models and functional outcomes, including tissue regeneration and vascularization, is presented in Table 4.
Overall, in vivo data confirm that three-dimensional architecture and scaffold bioactivity are the primary determinants of effective regeneration. Once technical parameters are optimized, the bioprinting technology itself becomes a secondary factor, while material composition, mechanical properties, and cellular organization ultimately dictate biological outcomes and clinical translational potential.

7. Challenges and Future Directions

Three-dimensional bioprinting for dentin–pulp complex regeneration has demonstrated remarkable progress in preclinical models, including high cell viability, enhanced odontogenic marker expression, and the formation of vascularized pulp-like tissue. However, clinical translation remains limited due to methodological variability, the lack of standardized performance criteria, and insufficient long-term functional evaluation, all of which affect the comparability and predictability of outcomes [65,67,75].

7.1. Bioink Standardization and the Three-Dimensional Microenvironment

A major obstacle to further progress is the variability of bioinks employed. Materials based on natural or synthetic polymers differ significantly in terms of mechanical properties, degradation kinetics, and bioactive factor release profiles, complicating the comparison of biological outcomes across experimental systems [13,46,77]. The development of an instructive microenvironment capable of maintaining a pulp-like phenotype while ensuring structural stability remains a key challenge. Materials with high stiffness promote mineralization but may hinder cellular infiltration and vascularization, whereas low-stiffness materials, although closer to native pulp tissue, often exhibit limited architectural stability [67,70,78]. Furthermore, scaffold degradation must be temporally synchronized with tissue regeneration. Rapid degradation may compromise cellular organization, while slow degradation may impair physiological remodeling. In this context, the controlled and sequential release of bioactive factors (e.g., BMP-2, Ca²⁺/Si⁴⁺ ions) requires a transition from empirical approaches toward predictive strategies based on well-characterized kinetics and standardized evaluation models [37,68].

7.2. Functionality - Vascularization and Reinnervation

The restoration of pulp functionality requires the reconstruction of both vascular and neural networks to support metabolic activity and sensory function. Although hDPSC–HUVEC co-culture systems have demonstrated vascular-like structures in vitro, the integrity and perfusability of these networks in vivo remain difficult to control and are often inconsistent across experimental models [46]. Advanced biofabrication strategies, including the 3D bioprinting of vascularized tissues, have demonstrated the generation of perfusable networks in thick constructs, suggesting promising approaches to overcome these limitations [79]. The coordinated regulation of angiogenesis, neurogenesis, and mineralization is essential to prevent fibrosis and premature mineralization [65,75]. Emerging strategies include the incorporation of perfusable microchannels, multimaterial bioprinting with precise spatial cell patterning, and the use of axon-guiding biomaterials to recreate the functional architecture of native pulp tissue [79].

7.3. Clinical Challenges and Preclinical Translation

Regeneration of the dentin–pulp complex faces challenges specific to the endodontic environment, including the narrow and complex geometry of root canals, the presence of microbial biofilms, and chronic inflammatory conditions. These factors directly influence material stability, stem cell behavior, and signaling pathways involved in odontogenic differentiation [80]. Pulpal blood supply is restricted by vascular access through the apical foramen, which may result in hypoxic conditions, reduced cell viability, and incomplete tissue maturation [75]. Hydrogel-based materials, although highly conformable and suitable for minimally invasive delivery, often exhibit limited mechanical stability, whereas thermoplastic scaffolds provide structural support but may be difficult to position within complex canal anatomies [65]. These limitations highlight the need for hybrid strategies that combine mechanical integrity with biological functionality.

7.4. Control of Three-Dimensional Architecture and Cellular Distribution

Controlled three-dimensional organization is a key determinant of regenerative performance. Layer-by-layer bioprinting enables uniform cell distribution and more homogeneous differentiation compared to cell suspension delivery, which often results in heterogeneous or incomplete tissue formation [65]. Architectural parameters, including porosity, microscale resolution, and structural gradients, significantly influence cell adhesion and enzymatic activity (e.g., alkaline phosphatase). The integration of these features into clinically scalable systems requires advanced multimaterial printing techniques and personalized digital design approaches capable of replicating the heterogeneity of the native pulp microenvironment [13,43].

7.5. Functional Validation and Long-Term Safety

Most studies focus on early biological indicators such as cell viability, gene expression, or mineralization, which, although informative, do not fully reflect clinical functionality. For successful clinical translation, it is essential to validate sensory reinnervation, responsiveness to stimuli, and the maintenance of pulp homeostasis under physiological mechanical loading and oral environmental conditions. Moreover, long-term safety must be systematically assessed, including host immune responses, the risk of chronic inflammation or fibrosis, and potential adverse effects associated with biomaterial degradation products. The development of standardized functional assays and objective biomarkers represents a critical priority for the clinical validation of regenerative strategies [81].

7.6. Future Directions

Future perspectives in dentin–pulp complex bioprinting are centered on several key directions:
  • Smart bioinks and biodynamic microenvironments: materials capable of dynamically adapting their mechanical properties and degradation behavior in response to local biological cues, thereby synchronizing scaffold remodeling with tissue regeneration.
  • Prevascularization and neurovascular integration: the development of perfusable microchannels, endothelial cell patterning, and axon-guiding biomaterials to enable functional integration with host vascular and neural systems.
  • In situ bioprinting and clinical personalization: direct fabrication within the root canal, supported by real-time imaging, robotic guidance, and AI-assisted design optimization, enabling patient-specific adaptation to anatomical and pathological conditions.
  • Integrated clinical translation: the establishment of standardized protocols, reproducible outcome measures, scalable manufacturing processes, regulatory compliance, and cost-effectiveness, all of which are essential for integrating bioprinting into routine endodontic practice.
By integrating these directions with fundamental principles of tissue regeneration, the field is progressing toward the restoration of fully functional dental pulp, moving beyond purely structural reconstruction.

8. Conclusion

Three-dimensional bioprinting represents a highly promising approach for dentin–pulp complex regeneration, offering precise control over the architecture and composition of biomimetic constructs. Current evidence indicates that regenerative outcomes are influenced more by the engineered three-dimensional microenvironment than by the specific printing technology employed.
The primary challenges are no longer related to feasibility, but rather to the optimization of the microenvironment, the standardization of bioinks, and the validation of long-term functional outcomes. In this context, bioprinting should be regarded not merely as a fabrication technique, but as a platform for the controlled modulation of biological processes involved in dental pulp regeneration, with strong potential for translation into predictable clinical therapies.

Author Contributions

Conceptualization, L.C.T., C.N.F and A.I.; methodology, L.C.T., C.N.F., A.I., A.M., D.F., and S.M.P.; validation, L.C.T, C.N.F., A.I., A.M., D.F., S.M.P., A.I., R.C., A.M.B. and W.A.U.; formal analysis, L.C.T., C.N.F., A.I., W.A.U. and R.C.; investigation, L.C.T., C.N.F., A.I., A.M.B. and A.I.; resources, L.C.T., C.N.F., A.I., A.M., D.F., and S.M.P; data curation, L.C.T., C.N.F., A.I., W.A.U. and R.C; writing—original draft preparation, L.C.T., C.N.F and A.I; writing—review and editing, L.C.T., C.N.F and A.I; visualization, L.C.T., C.N.F., A.I., A.M., D.F., and S.M.P; supervision, L.C.T, C.N.F., A.I., A.M., D.F., S.M.P., A.I., R.C., A.M.B. and W.A.U.; project administration, L.C.T. and A.I. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Acknowledgments

This research was supported by the project “Strengthening the capacity of the “Iuliu Hațieganu” University of Medicine and Pharmacy to train doctoral and postdoctoral students through the development of research programs and continuous medical education”, project code SMIS: 350525. During the preparation of this manuscript/study, the authors used GenAI tools (e.g., ChatGPT) for the purposes of language editing and English translation, as well as to support the creation of Figures 1–4. The authors have reviewed and edited the output and take full responsibility for the content of this publication.

Conflicts of Interest

The authors declare no conflicts of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.

Abbreviations

The following abbreviations are used in this manuscript:
AFM Atomic Force Microscopy
ALP Alkaline Phosphatase
Alg Alginate
ARS Alizarin Red S Staining
BBB Basso, Beattie, Bresnahan Locomotor Rating Scale
BD Biodentine
BG Bioactive Glass
BMP-2 Bone Morphogenetic Protein-2
BMP-4 Bone Morphogenetic Protein-4
BMP-7 Bone Morphogenetic Protein-7
bFGF Basic Fibroblast Growth Factor
Ca²⁺ Calcium Ion
CAD Computer-Aided Design
CCK-8 Cell Counting Kit-8
CD31 Cluster of Differentiation 31
CEMP1 Cementum Protein 1
CLSM Confocal Laser Scanning Microscopy
CNC Cellulose Nanocrystals
CO₂ Carbon Dioxide
CS Chitosan
CSF Collagen–Silk Fibroin
CT Computed Tomography
dDPSC Differentiated Dental Pulp Stem Cells
dECM Decellularized Extracellular Matrix
DDMp Decellularized Dentin Matrix Particles
DLP Digital Light Processing
DMD Digital Micromirror Device
DMP1 Dentin Matrix Protein 1
DSPP Dentin Sialophosphoprotein
DPSC Dental Pulp Stem Cell
EDX/EDS Energy-Dispersive X-Ray Spectroscopy
EBP Extrusion-Based Bioprinting
ELISA Enzyme-Linked Immunosorbent Assay
FDM Fused Deposition Modeling
FESEM Field Emission Scanning Electron Microscopy
FGF-2 Fibroblast Growth Factor-2
FTIR Fourier-Transform Infrared Spectroscopy
G (Gauge) Needle Diameter Unit
GAP43 Growth-Associated Protein 43
GelMA Gelatin Methacryloyl
GFAP Glial Fibrillary Acidic Protein
H&E Hematoxylin and Eosin Staining
HA Hydroxyapatite
HAMA Methacrylated Hyaluronic Acid
HE Hematoxylin and Eosin Staining
HLA Human Leukocyte Antigen
hDPSC Human Dental Pulp Stem Cells
HUVEC Human Umbilical Vein Endothelial Cells
HyA Hyaluronic Acid
ICP-AES Inductively Coupled Plasma Atomic Emission Spectroscopy
IF Immunofluorescence
IHC Immunohistochemistry
IJP Inkjet-Based Bioprinting
kPa Kilopascal
Ki67 Proliferation Marker
LAP Lithium Phenyl-2,4,6-Trimethylbenzoylphosphinate
LIFT Laser-Induced Forward Transfer
Live/Dead Live/Dead Viability Assay
MAP2 Microtubule-Associated Protein 2
MesoCS Mesoporous Calcium Silicate
MMPs Matrix Metalloproteinases
MRI Magnetic Resonance Imaging
MTA Mineral Trioxide Aggregate
MTT 3-(4,5-Dimethylthiazol-2-Yl)-2,5-Diphenyltetrazolium Bromide Assay
μm Micrometer
µL/min Microliter Per Minute
MSCs Mesenchymal Stem Cells
nL/s Nanoliter Per Second
N₂ Nitrogen Gas
NANOG Homeobox Transcription Factor NANOG
NGF Nerve Growth Factor
OC/OCN Osteocalcin
OPN Osteopontin
OCT4 Octamer-Binding Transcription Factor 4
PBS Phosphate-Buffered Saline
PCL Polycaprolactone
PDGF Platelet-Derived Growth Factor
PEG Polyethylene Glycol
PEGDMA Polyethylene Glycol Dimethacrylate
PLA Polylactic Acid
PLL Poly-L-Lysine
PPG Polypropylene Glycol
PS Polystyrene
RT-qPCR Reverse Transcription Quantitative Polymerase Chain Reaction
RGD Arginine–Glycine–Aspartic Acid
RT Room Temperature
RUNX2 Runt-Related Transcription Factor 2
SCAPs Stem Cells from the Apical Papilla
SLA Stereolithography
SHH Sonic Hedgehog
Si⁴⁺ Silicon Ion
SEM Scanning Electron Microscopy
SOX2 SRY-Box Transcription Factor 2
T10 Thoracic Vertebra 10
TGF-β1 Transforming Growth Factor Beta-1
TEM Transmission Electron Microscopy
TGA Thermogravimetric Analysis
TCP Tricalcium Phosphate
β-TCP Beta-Tricalcium Phosphate
UV Ultraviolet
VEGF Vascular Endothelial Growth Factor
WB Western Blot
WST-1 Water-Soluble Tetrazolium Assay
XRD X-Ray Diffraction
YAP Yes-Associated Protein

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  81. Matai, I.; Kaur, G.; Seyedsalehi, A.; McClinton, A.; Laurencin, C.T. Progress in 3D bioprinting technology for tissue/organ regenerative engineering. Biomaterials 2020, 226, 119536. [CrossRef]
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Figure 1. Schematic comparison between 3D printing and bioprinting approaches.
Figure 1. Schematic comparison between 3D printing and bioprinting approaches.
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Figure 2. Schematic representation of bioprinted scaffold application for dentin–pulp complex regeneration.
Figure 2. Schematic representation of bioprinted scaffold application for dentin–pulp complex regeneration.
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Figure 3. Schematic comparison of the main advantages and limitations of 3D scaffold fabrication techniques.
Figure 3. Schematic comparison of the main advantages and limitations of 3D scaffold fabrication techniques.
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Figure 4. Schematic representation of the bioprinting process and its main features.
Figure 4. Schematic representation of the bioprinting process and its main features.
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Table 1. In vitro bioprinting strategies for dental tissue engineering.
Table 1. In vitro bioprinting strategies for dental tissue engineering.
Author/ Year Tissue Type Material / Bioink
(Experimental)		 Material / Bioink
(Control)		 Cell Type Printing Method Bioprinting Conditions
Mousavi Nejad et al. (2021) [13] Dentin–pulp PCL + 45S5 BG / PCL + HyA PCL hDPSC Extrusion-based bioprinting Bioprinter N2 (3DPL Co., Iran): 90 °C; 600 kPa; 2 mm/s; PCL:BG 70:30; plasma (100 W, 0.6 mbar, 40 kHz, 10 min); HyA coating; freeze-drying (−58 °C, 0.5 Torr, 24 h).
Han et al. (2019)
[66]		 Dentin–pulp Fibrin (F5-F20) + PCL Control (fibrin formulations, F5–F20) hDPSC Extrusion-based bioprinting Custom 3D bioprinter (3-axis, multi-cartridge): nozzle 100–200 µm; speed 0.83–2.33 mm/s; dispensing 34.55–138.21 nL/s; fibrinogen 5–50 mg/mL.
Athirasala et al. (2018)
[67]		 Dentin–pulp Alginate–dentin (3% alginate; 2:1/1:1/1:2 Alg:Dent ratios) Control (Alg:Dent ratios) SCAPs Extrusion-based bioprinting Hyrel 3D (USA): coaxial nozzle 26G/19G; flow 45 µL/min; feed 0.5–0.8; grids 20×20 mm; 4-layer constructs (15×15 mm).
Author/ Year Tissue Type Material / Bioink
(Experimental) 		Material / Bioink
(Control) 		Cell Type Printing Method Bioprinting Conditions
Duarte Campos et al. (2020) [46] Pulp
tissue		 Collagen type I -agarose (0.2%/0.5%) Fibrin (0.5%) or
Collagen type I (0.3%)
(cell-free)		 hDPSC + HUVEC Inkjet (drop-on-demand) DropGun (BlackDrop, Germany): nozzle 300 µm; pressure 25–250 kPa; droplet 20–600 nL; frequency ≤1000 Hz; layer ~100 µm; alginate 0.5%; collagen 0.2%; RT printing.
Jiang et al. (2021)
[43]		 Dentin Collagen type I /silk fibroin (CSF1–3) Control (CSF formulations) hDPSC Extrusion-based bioprinting OrganP 1800 (China): nozzle 260 µm; speed 2–10 mm/s; layer 320 µm; height 0.7 mm; platform 20 °C; collagen/silk fibroin (1:1).
Huang et al. (2018)
[37]		 Dentin MesoCS + BMP-2 Control (non-mesoporous CS scaffold) hDPSC Extrusion-based bioprinting Bio-Scaffolder 3.1 (GeSiM, Germany): nozzle 400–500 µm; pressure 400–500 kPa; speed 1–5 mm/s; layer height 300 µm; spacing 500–600 µm; 7–16 layers; 90° orientation.
Han et al. (2021)
[68]		 Dentin Fibrinogen+DDMp Control (no DDMp) hDPSC Extrusion-based bioprinting Custom multi-cartridge bioprinter: nozzle 300 µm; speed 0.08–5.33 mm/s; extrusion 34.3 µL/min; layer width 400 µm; layer height 150 µm.
Ho et al. (2018)
[69]		 Dentin Biodentine + PCL PCL hDPSC Extrusion-based bioprinting BioScaffolder 3.1 (variant): nozzle 500 µm; pressure 500 kPa; speed 1–5 mm/s; layer height 300 µm; spacing 500 µm; 7 layers; 90° orientation.
Li et al. (2024)
[70]		 Dentin GelMA/Alg/CNC formulations (0–5% Alg; inverse CNC gradient, 6 groups) Control (GelMA/Alg/CNC ratio formulations) hDPSC Extrusion-based bioprinting 3D Discovery Evolution (regenHU): nozzle 260 µm; temperature 20 °C; UV 365 nm (5 min); Ca²⁺ crosslinking 0.1 M (1 h).
Lin et al. (2021)
[71]		 Dentin GelMA + CS
(5–10%)		 GelMA hDPSC Extrusion-based bioprinting BioX (CELLINK, Sweden): nozzle 30G; pressure 180 kPa; speed 20 mm/s; UV curing 405 nm (90 s).
Choi et al. (2022)
[72]		 Dentin GelMA + MTA GelMA hDPSC Extrusion-based bioprinting Rokit INVIVO 3D: nozzle 200 µm; speed 10 mm/s; pressure 90 kPa; bed 4 °C; UV 365 nm (5–10 min); ethanol 70% (30 min); lyophilization (−70 °C, 24 h).
Yeh et al. (2022)
[73]		 Dentin MSCS/ 2% Quercetin/ PCL MSCS + PCL hDPSC Extrusion-based bioprinting Bio-Scaffolder 3.1 (GeSiM, Germany): nozzle 400 µm; pressure 400 kPa; layer height 300 µm; spacing 600 µm.
Yu et al. (2019)
[74]		 Dentin Alg/Gel+ hDPSCs hDPSCs (no extract) hDPSC Extrusion-based bioprinting Bioplotter (ETEC, Germany): nozzle 400 µm; N₂ pressure 20 kPa; speed 2 mm/s; temperature 37 °C; platform 5 °C; 7 layers.
PCL – polycaprolactone; BG – bioactive glass; 45S5 BG – 45S5 bioactive glass composition; HyA – hyaluronic acid; hDPSC – human dental pulp stem cells; SCAPs – stem cells from the apical papilla; HUVEC – human umbilical vein endothelial cells; GelMA – gelatin methacrylate; MTA – mineral trioxide aggregate; CS – chitosan; CSF – collagen–silk fibroin; MesoCS – mesoporous calcium silicate; BMP-2 – bone morphogenetic protein-2; DDMp – decellularized dentin matrix particles; MSCS – mesenchymal stem cells; Alg – alginate; Dent – dentin; F5–F20 – fibrinogen formulations (5–20 mg/mL); N₂ – nitrogen gas; UV – ultraviolet; kPa – kilopascal; µm – micrometer; µL/min – microliter per minute; nL/s – nanoliter per second; RT – room temperature.
Table 2. In vitro biological evaluation of 3D bioprinted scaffolds for dental tissue engineering.
Table 2. In vitro biological evaluation of 3D bioprinted scaffolds for dental tissue engineering.
Author/ Year Tissue Type Material / Bioink Cell Type
(Cell Density)		 Assessment Outcomes
Mousavi Nejad et al. (2021) [13] Dentin–pulp PCL + 45S5 BG / PCL + HyA hDPSC
(5 × 10⁴ cells/well)		 Viability (MTT); morphology (FESEM/EDS); gene expression (RT-qPCR); surface roughness (AFM); mechanical testing (compression) Viability >90% (p<0.01). PCL/BG enhanced odontogenic differentiation via RT-qPCR upregulation of ALP, DSPP, DMP-1, OCN and hydroxyapatite formation with improved mechanical strength. PCL/HyA improved adhesion, wettability (63°), and pulp-like phenotype (VEGF, HLA, CEMP1).
Han et al. (2019)
[66]		 Dentin–pulp Fibrin + PCL hDPSC
(3 × 10⁶ cells/mL)		 Viability (Live/Dead, alamarBlue); mineralization (ARS); differentiation (ALP); gene expression (RT-qPCR); morphology (SEM) Viability >90% (Day 4). Fibrin ≥10 mg/mL enhanced mineralization and odontogenic gene expression (DSPP, DMP1). F20 showed highest odontogenic potential; F5 favored pulp-like phenotype. Increased stiffness (1.5×) and reduced degradation (~50%).
Athirasala et al. (2018)
[67]		 Dentin–pulp Alg:Dent SCAPs
(0.8 × 10⁶ cells/mL)		 Rheology; mechanical testing; viability (Live/Dead); differentiation (ALP); gene expression (RT-qPCR) Viability >90% (1:1/1:2). Strong RT-qPCR upregulation of ALP and RUNX2 (up to 26×). Scaffold exhibited pulp-like stiffness (1–2 kPa) and supported odontogenic differentiation without external induction.
Duarte Campos et al. (2020) [46] Pulp
tissue		 Collagen type I -agarose hDPSC (3 × 10⁶ cells/ml) + HUVEC (3 × 10⁶ cells/ml)
(co-culture)		 Morphology/vasculogenesis (CD31 confocal); SEM; rheology; mechanical testing; printability analysis Co-culture formed CD31+ vascular networks. Hydrogels supported vasculogenesis and structural stability up to 14 days. Fibrin-based systems enhanced vascular tube formation vs collagen-based constructs.
Jiang et al. (2021)
[43]		 Dentin Collagen type I /silk fibroin hDPSC
(1 × 10⁵ cells/scaffold)		 Morphology (SEM); viability (CCK-8); differentiation (ALP); histology (HE) CSF scaffolds enhanced adhesion and proliferation (p < 0.05), with highest ALP activity in CSF1 (p < 0.01). Multilayer growth observed; odontogenic differentiation confirmed, indicating dentin–pulp regenerative potential.
Huang et al. (2018)
[37]		 Dentin MesoCS + BMP-2 hDPSC
NR 		Viability (PrestoBlue); morphology (SEM/TEM); mineralization (ARS); ALP; gene/protein expression (RT-qPCR/ELISA/WB); ion release (ICP-AES); mechanics MesoCSB increased proliferation (+37%, p < 0.05), ALP activity and odontogenic markers (OC, DMP-1, DSPP). Enhanced mineralization and BMP-2 release (~2×) with SMAD/ERK pathway activation.
Han et al. (2021)
[68]		 Dentin Fibrinogen+DDMp hDPSC
(3 × 10⁶ cells/mL)		 Viability (Live/Dead, AlamarBlue); mineralization (ARS); differentiation (ALP); gene expression (RT-qPCR); morphology (SEM) Viability >95%. DDMp reduced proliferation but significantly enhanced mineralization and odontogenic markers DSPP and DMP-1 (p < 0.01).
Ho et al. (2018)
[69]		 Dentin Biodentine + PCL hDPSC
(1 ×10⁴ cells/mL)		 Morphology (SEM); viability (PrestoBlue); ALP; protein expression (ELISA); mineralization (ARS) BD/PCL enhanced proliferation (1.7×–1.3×, p < 0.05), ALP activity and OC secretion. Strong mineralization observed (up to 11.7× vs control), confirming osteoinductive effect.
Author/ Year Tissue Type Material / Bioink
 Cell Type
(Cell Density) 		Assessment Outcomes
Li et al. (2024)
[70]		 Dentin GelMA/Alg/CNC hDPSC
(1 × 10⁶
cells/mL)		 Viability (Live/Dead, MTT); morphology (SEM, AFM); mechanics (compression/rheology); structure (XRD/TGA); differentiation (ALP); gene expression (RT-qPCR) GelMA/Alg/CNC (GelMA-2A3C) showed highest viability and proliferation (p < 0.001), strongest ALP activity and upregulation of ALP, OPN and DSPP (1.5–2.2×), with superior mineralization among all formulations.
Lin et al. (2021)
[71]		 Dentin GelMA + CS hDPSC
(5 × 10⁶ cells/mL)		 Morphology (confocal/FTIR/XRD); rheology; ion release (ICP-AES); protein expression (ELISA/WB); ALP CS/GelMA increased viability and proliferation (p < 0.05). CS10 showed highest mineralization and upregulation of ALP, DMP-1 and OCN (p < 0.01), driven by Si ion release.
Choi et al. (2022)
[72]		 Dentin GelMA + MTA hDPSC
(5 × 10⁴ cells/well)		 Morphology (SEM); viability (WST-1); gene expression (RT-qPCR); ALP; mineralization (ARS) Cell viability comparable to control (p > 0.05). MTA-GelMA increased ALP activity and calcium deposition (p < 0.05) with upregulation of DSPP and DMP-1, indicating odontogenic differentiation.
Yeh et al. (2022)
[73]		 Dentin MSCS/ Quercetin/ PCL hDPSC
(1 ×10⁴ cells/mL)		 Morphology (TEM/SEM); mechanics (XRD); viability (PrestoBlue); protein expression (ELISA); mineralization (ARS) MSCSQ increased viability (~15%, p < 0.05), proliferation and mineralization with upregulation of DSPP and DMP-1, supporting pulp–dentin regeneration.
Yu et al. (2019)
[74]		 Dentin Alg/Gel+ hDPSCs hDPSC
(1×10⁶ cells/mL /~5×10⁴ cells/scaffold)		 Viability (Live/Dead, MTT, CCK-8); morphology (SEM); differentiation (ALP); gene expression (RT-qPCR); protein expression (WB) Alg-Gel scaffolds enhanced proliferation (1.2–1.4×, p < 0.001), ALP activity and expression of ALP, OCN and DSPP, with increased mineralization and osteo/odontogenic differentiation.
PCL – polycaprolactone; BG – bioactive glass; 45S5 BG – 45S5 bioactive glass composition; HyA – hyaluronic acid; hDPSC – human dental pulp stem cells; SCAPs – stem cells from the apical papilla; HUVEC – human umbilical vein endothelial cells; GelMA – gelatin methacrylate; MTA – mineral trioxide aggregate; CS – chitosan; CSF – collagen–silk fibroin; MesoCS – mesoporous calcium silicate; BMP-2 – bone morphogenetic protein-2; DDMp – decellularized dentin matrix particles; MSCS – mesenchymal stem cells; Alg – alginate; CNC – cellulose nanocrystals; BD – Biodentine; MTT – 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay; WST-1 – water-soluble tetrazolium assay; CCK-8 – Cell Counting Kit-8; Live/Dead – live/dead viability assay; alamarBlue – resazurin-based viability assay; ARS – Alizarin Red S staining; ALP – alkaline phosphatase; RT-qPCR – reverse transcription quantitative polymerase chain reaction; ELISA – enzyme-linked immunosorbent assay; WB – Western blot; SEM – scanning electron microscopy; FESEM – field emission scanning electron microscopy; TEM – transmission electron microscopy; EDS – energy-dispersive spectroscopy; AFM – atomic force microscopy; XRD – X-ray diffraction; FTIR – Fourier-transform infrared spectroscopy; TGA – thermogravimetric analysis; ICP-AES – inductively coupled plasma atomic emission spectroscopy; HE – hematoxylin and eosin staining; CD31 – cluster of differentiation 31 (endothelial marker); VEGF – vascular endothelial growth factor; HLA – human leukocyte antigen; CEMP1 – cementum protein 1; DSPP – dentin sialophosphoprotein; DMP-1 – dentin matrix protein 1; OCN/OC – osteocalcin; OPN – osteopontin; RUNX2 – runt-related transcription factor 2; NR – not reported; RT – room temperature; kPa – kilopascal; µm – micrometer; µL/min – microliter per minute; nL/s – nanoliter per second.
Table 3. In vivo bioprinting strategies for dental tissue engineering.
Table 3. In vivo bioprinting strategies for dental tissue engineering.
Author/ Year Tissue Type Material / Bioink
(Experimental)		 Material / Bioink
(Control)		 Cell Type Printing Method Printing Parameters
Zhou et al. (2024)
[75]		 Pulp Tissue GelMA/dextran emulsion Bulk GelMA
hydrogel		 hDPSCs/
HUVECs		 Digital Light Processing (DLP)
bioprinting		 405 nm UV light; DMD-based patterning; 10 s/layer exposure; layer-by-layer photopolymerization; post-curing at 37 °C in PBS
Qian et al. (2023)
[65]		 Pulp and
Spinal Cord Tissue		 GelMA hydrogel microspheres 2D-GelMA
2D-PS		 hDPSCs Digital Light Processing (DLP)
bioprinting		 405 nm UV light; 5% GelMA + 0.25% LAP; DLP-based layer-by-layer photopolymerization
Chen et al. (2021)
[40]		 Dentin-/Bone-like Tissue HyA/PLA scaffold HyA/PLA scaffolds
(Cell-free)		 DPSCs
(canine derived cell line)		 Material extrusion–based 3D printing (FDM) Ultimaker 2.0 Plus; 250 μm nozzle; 30 mm/s printing speed; 100 μm layer height; 200 °C nozzle; 60 °C bed; Cura 2.7 slicing
Kim et al. (2022)
[76]		 Dentin
Tissue		 dECM/β-TCP composite Collagen type 1/
β-TCP		 hDPSCs Pneumatic extrusion-based bioprinting 25G nozzle (250 μm); 10 mm/s deposition speed; pneumatic extrusion; genipin crosslinking (1 mM, 30 min, 37 °C, 5% CO₂)
GelMA – gelatin methacrylate; HyA – hyaluronic acid; PLA – polylactic acid; dECM – decellularized extracellular matrix; β-TCP – beta-tricalcium phosphate; LAP – lithium phenyl-2,4,6-trimethylbenzoylphosphinate (photoinitiator); hDPSCs – human dental pulp stem cells; HUVECs – human umbilical vein endothelial cells; DPSCs – dental pulp stem cells; DLP – digital light processing; DMD – digital micromirror device; FDM – fused deposition modeling; PBS – phosphate-buffered saline; PS – polystyrene; UV – ultraviolet; °C – degrees Celsius; mm/s – millimeters per second; μm – micrometer; G – needle gauge; mM – millimolar; CO₂ - carbon dioxide.
Table 4. In vivo biological evaluation of 3D bioprinted scaffolds for dental tissue engineering.
Table 4. In vivo biological evaluation of 3D bioprinted scaffolds for dental tissue engineering.
Author/ Year Tissue Type Animal Model Defect Area Assessment Outcomes
Zhou et al. (2024)
[75]		 Pulp Tissue Immunodeficient mice Subcutaneous implantation (ectopic; not explicitly reported) CLSM, SEM, qPCR, ALP, IHC, CCK-8, transwell, H&E, tube formation, neurite assay, mechanical testing DPGC hydrogels (~40 kPa, ~49 μm porosity) supported hDPSC viability and stemness (OCT4, NANOG, SOX2; p<0.01) with YAP activation, while enhancing osteo/odontogenic differentiation (RUNX2, OCN, DSPP; p<0.001), angiogenesis (VEGF, tube formation assays) and neurogenic responses (NGF, neurite outgrowth) after 4 weeks.
Qian et al. (2023)
[65]		 Pulp and
Spinal Cord Tissue		 Minipig, rat, nude mouse Rat SCI: T10 complete spinal cord transection injury (~3 mm gap); mouse pulp model (apical foramen enlargement ~1 mm); minipig root canal model; subcutaneous degradation assay CLSM, SEM, RT-qPCR, ALP, IF, CCK-8, transwell, H&E, micro-CT, motor scoring Enabled functional recovery in SCI (BBB 8–9), reduced lesion size and upregulated GAP43/MAP2/GFAP. In pulp models, promoted vascularized pulp regeneration with Ki67+/OCT4+/SOX2+ cells, DSPP/DMP1 expression, angiogenesis (CD31/VEGFα) and neurogenesis (MAP2/GAP43), resembling native pulp at 4–8 weeks.
Chen et al. (2021)
[40]		 Dentin-/Bone-like
Tissue		 Beagle dogs Bilateral mandibular defects (incisors 3×8 mm; premolars 6×8 mm) H&E, Masson’s trichrome, IHC (DSPP, DMP1), micro-CT, histomorphometry, qRT-PCR HyA/PLA scaffolds supported progressive mineralization and dentin/bone-like tissue formation over 6–36 weeks, with increased bone/dentin-like tissue volume and mineralized matrix density (p<0.05). dDPSC-seeded scaffolds enhanced mineral deposition and remodeling, with partial degradation observed up to 9 months.
Kim et al. (2022)
[76]		 Dentin Tissue Nude mice Subcutaneous ectopic implantation (dorsal; incision depth not explicitly reported) H&E, IF (DSPP, DMP1), qRT-PCR, ALP, ARS, MTT, cytoskeletal staining dECM-based scaffolds enhanced angiogenesis (p<0.05), odontogenic gene expression (DSPP, DMP1; p<0.01) and mineralized matrix formation, promoting osteo/odontogenic differentiation and dentin-like tissue formation after 8 weeks.
hDPSC/hDPSCs – human dental pulp stem cells; dDPSC – differentiated dental pulp stem cells; SCI – spinal cord injury; T10 – thoracic vertebra 10; BBB – Basso, Beattie, Bresnahan locomotor rating scale; CLSM – confocal laser scanning microscopy; SEM – scanning electron microscopy; qPCR/RT-qPCR – quantitative / reverse transcription quantitative polymerase chain reaction; ALP – alkaline phosphatase; IHC – immunohistochemistry; IF – immunofluorescence; H&E – hematoxylin and eosin staining; ARS – Alizarin Red S staining; MTT – 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay; micro-CT – micro-computed tomography; DSPP – dentin sialophosphoprotein; DMP1 – dentin matrix protein 1; OCN – osteocalcin; RUNX2 – runt-related transcription factor 2; VEGF/VEGFα – vascular endothelial growth factor; CD31 – cluster of differentiation 31; NGF – nerve growth factor; GAP43 – growth-associated protein 43; MAP2 – microtubule-associated protein 2; GFAP – glial fibrillary acidic protein; OCT4, NANOG, SOX2 – stemness-associated transcription factors; YAP – yes-associated protein (Hippo pathway effector); Ki67 – proliferation marker; HyA – hyaluronic acid; PLA – polylactic acid; dECM – decellularized extracellular matrix; kPa – kilopascal; μm – micrometer.
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