More Like this

1. 3D Bioprinted Multicellular Vascular Models

   https://doi.org/10.1002/adhm.202101141  

   Gold, Karli_A; Saha, Biswajit; Rajeeva_Pandian, Navaneeth_Krishna; Walther, Brandon_K; Palma, Jorge_A; Jo, Javier; Cooke, John_P; Jain, Abhishek; Gaharwar, Akhilesh_K (July 2021, Advanced Healthcare Materials)

   Abstract 3D bioprinting is an emerging additive manufacturing technique to fabricate constructs for human disease modeling. However, current cell‐laden bioinks lack sufficient biocompatibility, printability, and structural stability needed to translate this technology to preclinical and clinical trials. Here, a new class of nanoengineered hydrogel‐based cell‐laden bioinks is introduced, that can be printed into 3D, anatomically accurate, multicellular blood vessels to recapitulate both the physical and chemical microenvironments of native human vasculature. A remarkably unique characteristic of this bioink is that regardless of cell density, it demonstrates a high printability and ability to protect encapsulated cells against high shear forces in the bioprinting process. 3D bioprinted cells maintain a healthy phenotype and remain viable for nearly one‐month post‐fabrication. Leveraging these properties, the nanoengineered bioink is printed into 3D cylindrical blood vessels, consisting of living co‐culture of endothelial cells and vascular smooth muscle cells, providing the opportunity to model vascular function and pathophysiology. Upon cytokine stimulation and blood perfusion, this 3D bioprinted vessel is able to recapitulate thromboinflammatory responses observed only in advanced in vitro preclinical models or in vivo. Therefore, this 3D bioprinted vessel provides a potential tool to understand vascular disease pathophysiology and assess therapeutics, toxins, or other chemicals. 

   more » « less
2. Leveraging 3D Bioprinting and Photon‐Counting Computed Tomography to Enable Noninvasive Quantitative Tracking of Multifunctional Tissue Engineered Constructs

   https://doi.org/10.1002/adhm.202302271  

   Gil, Carmen_J; Evans, Connor_J; Li, Lan; Allphin, Alex_J; Tomov, Martin_L; Jin, Linqi; Vargas, Merlyn; Hwang, Boeun; Wang, Jing; Putaturo, Victor; et al (September 2023, Advanced Healthcare Materials)

   Abstract 3D bioprinting is revolutionizing the fields of personalized and precision medicine by enabling the manufacturing of bioartificial implants that recapitulate the structural and functional characteristics of native tissues. However, the lack of quantitative and noninvasive techniques to longitudinally track the function of implants has hampered clinical applications of bioprinted scaffolds. In this study, multimaterial 3D bioprinting, engineered nanoparticles (NPs), and spectral photon‐counting computed tomography (PCCT) technologies are integrated for the aim of developing a new precision medicine approach to custom‐engineer scaffolds with traceability. Multiple CT‐visible hydrogel‐based bioinks, containing distinct molecular (iodine and gadolinium) and NP (iodine‐loaded liposome, gold, methacrylated gold (AuMA), and Gd₂O₃) contrast agents, are used to bioprint scaffolds with varying geometries at adequate fidelity levels. In vitro release studies, together with printing fidelity, mechanical, and biocompatibility tests identified AuMA and Gd₂O₃NPs as optimal reagents to track bioprinted constructs. Spectral PCCT imaging of scaffolds in vitro and subcutaneous implants in mice enabled noninvasive material discrimination and contrast agent quantification. Together, these results establish a novel theranostic platform with high precision, tunability, throughput, and reproducibility and open new prospects for a broad range of applications in the field of precision and personalized regenerative medicine. 

   more » « less
3. Demonstration of doxorubicin's cardiotoxicity and screening using a 3D bioprinted spheroidal droplet-based system

   https://doi.org/10.1039/D3RA00421J  

   El Khoury, Raven; Ramirez, Salma P.; Loyola, Carla D.; Joddar, Binata (March 2023, RSC Advances)

   Doxorubicin (DOX) is a highly effective anthracycline chemotherapy agent effective in treating a broad range of life-threatening malignancies but it causes cardiotoxicity in many subjects. While the mechanism of its cardiotoxic effects remains elusive, DOX-related cardiotoxicity can lead to heart failure in patients. In this study, we investigated the effects of DOX-induced cardiotoxicity on human cardiomyocytes (CMs) using a three-dimensional (3D) bioprinted cardiac spheroidal droplet based-system in comparison with the traditional two-dimensional cell (2D) culture model. The effects of DOX were alleviated with the addition of N -acetylcysteine (NAC) and Tiron. Caspase-3 activity was quantified, and reactive oxygen species (ROS) production was measured using dihydroethidium (DHE) staining. Application of varying concentrations of DOX (0.4 μM–1 μM) to CMs revealed a dose-specific response, with 1 μM concentration imposing maximum cytotoxicity and 0.22 ± 0.11% of viable cells in 3D samples versus 1.02 ± 0.28% viable cells in 2D cultures, after 5 days of culture. Moreover, a flow cytometric analysis study was conducted to study CMs proliferation in the presence of DOX and antioxidants. Our data support the use of a 3D bioprinted cardiac spheroidal droplet as a robust and high-throughput screening model for drug toxicity. In the future, this 3D spheroidal droplet model can be adopted as a human-derived tissue-engineered equivalent to address challenges in other various aspects of biomedical pre-clinical research. 

   more » « less
4. Biomimetic 3D-printed neurovascular phantoms for near-infrared fluorescence imaging

   https://doi.org/10.1364/BOE.9.002810  

   Liu, Yi; Ghassemi, Pejhman; Depkon, Andrew; Iacono, Maria_Ida; Lin, Jonathan; Mendoza, Gonzalo; Wang, Jianting; Tang, Qinggong; Chen, Yu; Pfefer, T_Joshua (May 2018, Biomedical Optics Express)

   Emerging three-dimensional (3D) printing technology enables the fabrication of optically realistic and morphologically complex tissue-simulating phantoms for the development and evaluation of novel optical imaging products. In this study, we assess the potential to print image-defined neurovascular phantoms with patent channels for contrast-enhanced near-infrared fluorescence (NIRF) imaging. An anatomical map defined from clinical magnetic resonance imaging (MRI) was segmented and processed into files suitable for printing a forebrain vessel network in rectangular and curved-surface biomimetic phantoms. Methods for effectively cleaning samples with complex vasculature were determined. A final set of phantoms were imaged with a custom NIRF system at 785 nm excitation using two NIRF contrast agents. In addition to demonstrating the strong potential of 3D printing for creating highly realistic, patient-specific biophotonic phantoms, our work provides insight into optimal methods for accomplishing this goal and elucidates current limitations of this approach. 

   more » « less
5. Taking the 3Rs to a higher level: replacement and reduction of animal testing in life sciences in space research

   https://doi.org/10.1016/j.biotechadv.2025.108574  

   Vinken, Mathieu; Grimm, Daniela; Baatout, Sarah; Baselet, Bjorn; Beheshti, Afshin; Braun, Markus; Carstens, Anna Catharina; Casaletto, James A; Cools, Ben; Costes, Sylvain V; et al (July 2025, Biotechnology Advances)

   Human settlements on the Moon, crewed missions to Mars and space tourism will become a reality in the next few decades. Human presence in space, especially for extended periods of time, will therefore steeply increase. However, despite more than 60 years of spaceflight, the mechanisms underlying the effects of the space environment on human physiology are still not fully understood. Animals, ranging in complexity from flies to monkeys, have played a pioneering role in understanding the (patho)physiological outcome of critical environmental factors in space, in particular altered gravity and cosmic radiation. The use of animals in biomedical research is increasingly being criticized because of ethical reasons and limited human relevance. Driven by the 3Rs concept, calling for replacement, reduction and refinement of animal experimentation, major efforts have been focused in the past decades on the development of alternative methods that fully bypass animal testing or so-called new approach methodologies. These new approach methodologies range from simple monolayer cultures of individual primary or stem cells all up to bioprinted 3D organoids and microfluidic chips that recapitulate the complex cellular architecture of organs. Other approaches applied in life sciences in space research contribute to the reduction of animal experimentation. These include methods to mimic space conditions on Earth, such as microgravity and radiation simulators, as well as tools to support the processing, analysis or application of testing results obtained in life sciences in space research, including systems biology, live-cell, high-content and real-time analysis, high-throughput analysis, artificial intelligence and digital twins. The present paper provides an in-depth overview of such methods to replace or reduce animal testing in life sciences in space research. 

   more » « less