Your search keyword '"Hassan, Shabir"' showing total 11 results

1. Tunable and Compartmentalized Multimaterial Bioprinting for Complex Living Tissue Constructs.

Author

Hassan S, Gomez-Reyes E, Enciso-Martinez E, Shi K, Campos JG, Soria OYP, Luna-Cerón E, Lee MC, Garcia-Reyes I, Steakelum J, Jeelani H, García-Rivera LE, Cho M, Cortes SS, Kamperman T, Wang H, Leijten J, Fiondella L, and Shin SR

Subjects

Tissue Engineering methods, Printing, Three-Dimensional, Extracellular Matrix chemistry, Gels chemistry, Tissue Scaffolds, Hydrogels chemistry, Bioprinting methods

Abstract

Recapitulating inherent heterogeneity and complex microarchitectures within confined print volumes for developing implantable constructs that could maintain their structure in vivo has remained challenging. Here, we present a combinational multimaterial and embedded bioprinting approach to fabricate complex tissue constructs that can be implanted postprinting and retain their three-dimensional (3D) shape in vivo . The microfluidics-based single nozzle printhead with computer-controlled pneumatic pressure valves enables laminar flow-based voxelation of up to seven individual bioinks with rapid switching between various bioinks that can solve alignment issues generated during switching multiple nozzles. To improve the spatial organization of various bioinks, printing fidelity with the z -direction, and printing speed, self-healing and biodegradable colloidal gels as support baths are introduced to build complex geometries. Furthermore, the colloidal gels provide suitable microenvironments like native extracellular matrices (ECMs) for achieving cell growths and fast host cell invasion via interconnected microporous networks in vitro and in vivo . Multicompartment microfibers ( i.e. , solid, core-shell, or donut shape), composed of two different bioink fractions with various lengths or their intravolume space filled by two, four, and six bioink fractions, are successfully printed in the ECM-like support bath. We also print various acellular complex geometries such as pyramids, spirals, and perfusable branched/linear vessels. Successful fabrication of vascularized liver and skeletal muscle tissue constructs show albumin secretion and bundled muscle mimic fibers, respectively. The interconnected microporous networks of colloidal gels result in maintaining printed complex geometries while enabling rapid cell infiltration, in vivo .

Published

2022

2. Hybrid extracellular vesicles-liposome incorporated advanced bioink to deliver microRNA.

Author

Elkhoury K, Chen M, Koçak P, Enciso-Martínez E, Bassous NJ, Lee MC, Byambaa B, Rezaei Z, Li Y, Ubina López ME, Gurian M, Sobahi N, Hussain MA, Sanchez-Gonzalez L, Leijten J, Hassan S, Arab-Tehrany E, Ward JE, and Shin SR

Subjects

Hydrogels, Liposomes, Printing, Three-Dimensional, Tissue Engineering, Tissue Scaffolds, Bioprinting, Extracellular Vesicles, MicroRNAs genetics

Abstract

In additive manufacturing, bioink formulations govern strategies to engineer 3D living tissues that mimic the complex architectures and functions of native tissues for successful tissue regeneration. Conventional 3D-printed tissues are limited in their ability to alter the fate of laden cells. Specifically, the efficient delivery of gene expression regulators (i.e. microRNAs (miRNAs)) to cells in bioprinted tissues has remained largely elusive. In this study, we explored the inclusion of extracellular vesicles (EVs), naturally occurring nanovesicles (NVs), into bioinks to resolve this challenge. EVs show excellent biocompatibility, rapid endocytosis, and low immunogenicity, which lead to the efficient delivery of miRNAs without measurable cytotoxicity. EVs were fused with liposomes to prolong and control their release by altering their physical interaction with the bioink. Hybrid EVs-liposome (hEL) NVs were embedded in gelatin-based hydrogels to create bioinks that could efficiently encapsulate and deliver miRNAs at the target site in a controlled and sustained manner. The regulation of cells' gene expression in a 3D bioprinted matrix was achieved using the hELs-laden bioink as a precursor for excellent shape fidelity and high cell viability constructs. Novel regulatory factors-loaded bioinks will expedite the translation of new bioprinting applications in the tissue engineering field., (© 2022 IOP Publishing Ltd.)

Published

2022

3. Enzyme-Mediated Alleviation of Peroxide Toxicity in Self-Oxygenating Biomaterials.

Author

Willemen NGA, Hassan S, Gurian M, Jasso-Salazar MF, Fan K, Wang H, Becker M, Allijn IE, Bal-Öztürk A, Leijten J, and Shin SR

Subjects

Catalase, Hydrogels, Hydrogen Peroxide, Oxygen, Tissue Engineering, Biocompatible Materials toxicity, Bioprinting methods

Abstract

Oxygen releasing biomaterials can facilitate the survival of living implants by creating environments with a viable oxygen level. Hydrophobic oxygen generating microparticles (HOGMPs) encapsulated calcium peroxide (CPO) have recently been used in tissue engineering to release physiologically relevant amounts of oxygen for several weeks. However, generating oxygen using CPO is mediated via the generation of toxic levels of hydrogen peroxide (H 2 O 2 ). The incorporation of antioxidants, such as catalases, can potentially reduce H 2 O 2 levels. However, the formulation in which catalases can most effectively scavenge H 2 O 2 within oxygen generating biomaterials has remained unexplored. In this study, three distinct catalase incorporation methods are compared based on their ability to decrease H 2 O 2 levels. Specifically, catalase is incorporated within HOGMPs, or absorbed onto HOGMPs, or freely laden into the hydrogel entrapping HOGMPs and compared with control without catalase. Supplementation of free catalase in an HOGMP-laden hydrogel significantly decreases H 2 O 2 levels reflecting a higher cellular viability and metabolic activity of all the groups. An HOGMP/catalase-laden hydrogel precursor solution containing cells is used as an oxygenating bioink allowing improved viability of printed constructs under severe hypoxic conditions. The combination of HOGMPs with a catalase-laden hydrogel has the potential to decrease peroxide toxicity of oxygen generating tissues., (© 2022 Wiley-VCH GmbH.)

Published

2022

4. Toward a neurospheroid niche model: optimizing embedded 3D bioprinting for fabrication of neurospheroid brain-like co-culture constructs.

Author

Li YE, Jodat YA, Samanipour R, Zorzi G, Zhu K, Hirano M, Chang K, Arnaout A, Hassan S, Matharu N, Khademhosseini A, Hoorfar M, and Shin SR

Subjects

Brain, Coculture Techniques, Hydrogels, Printing, Three-Dimensional, Tissue Engineering, Tissue Scaffolds, Bioprinting

Abstract

A crucial step in creating reliable in vitro platforms for neural development and disorder studies is the reproduction of the multicellular three-dimensional (3D) brain microenvironment and the capturing of cell-cell interactions within the model. The power of self-organization of diverse cell types into brain spheroids could be harnessed to study mechanisms underlying brain development trajectory and diseases. A challenge of current 3D organoid and spheroid models grown in petri-dishes is the lack of control over cellular localization and diversity. To overcome this limitation, neural spheroids can be patterned into customizable 3D structures using microfabrication. We developed a 3D brain-like co-culture construct using embedded 3D bioprinting as a flexible solution for composing heterogenous neural populations with neurospheroids and glia. Specifically, neurospheroid-laden free-standing 3D structures were fabricated in an engineered astrocyte-laden support bath resembling a neural stem cell niche environment. A photo-crosslinkable bioink and a thermal-healing supporting bath were engineered to mimic the mechanical modulus of soft tissue while supporting the formation of self-organizing neurospheroids within elaborate 3D networks. Moreover, bioprinted neurospheroid-laden structures exhibited the capability to differentiate into neuronal cells. These brain-like co-cultures could provide a reproducible platform for modeling neurological diseases, neural regeneration, and drug development and repurposing., (© 2020 IOP Publishing Ltd.)

Published

2020

5. Effective bioprinting resolution in tissue model fabrication.

Author

Miri AK, Mirzaee I, Hassan S, Mesbah Oskui S, Nieto D, Khademhosseini A, and Zhang YS

Subjects

Ink, Light, Tissue Array Analysis, Viscosity, Biomimetics methods, Bioprinting methods

Abstract

Recent advancements in bioprinting techniques have enabled convenient fabrication of micro-tissues in organ-on-a-chip platforms. In a sense, the success of bioprinted micro-tissues depends on how close their architectures are to the anatomical features of their native counterparts. The bioprinting resolution largely relates to the technical specifications of the bioprinter platforms and the physicochemical properties of the bioinks. In this article, we compare inkjet, extrusion, and light-assisted bioprinting technologies for fabrication of micro-tissues towards construction of biomimetic organ-on-a-chip platforms. Our theoretical analyses reveal that for a given printhead diameter, surface contact angle dominates inkjet bioprinting resolution, while nozzle moving speed and the nonlinearity of viscosity for bioinks regulate extrusion bioprinting resolution. The resolution of light-assisted bioprinting is strongly affected by the photocrosslinking behavior and light characteristics. Our tutorial guideline for optimizing bioprinting resolution would potentially help model the complex microenvironment of biological tissues in organ-on-a-chip platforms.

Published

2019

6. Digitally Tunable Microfluidic Bioprinting of Multilayered Cannular Tissues.

Author

Pi Q, Maharjan S, Yan X, Liu X, Singh B, van Genderen AM, Robledo-Padilla F, Parra-Saldivar R, Hu N, Jia W, Xu C, Kang J, Hassan S, Cheng H, Hou X, Khademhosseini A, and Zhang YS

Subjects

Biocompatible Materials, Bioprinting instrumentation, Blood Vessel Prosthesis, Cell Survival, Human Umbilical Vein Endothelial Cells, Humans, Hydrogels, Materials Testing, Myocytes, Smooth Muscle, Urinary Bladder, Urothelium, Bioprinting methods, Microfluidics instrumentation, Printing, Three-Dimensional instrumentation, Tissue Scaffolds

Abstract

Despite advances in the bioprinting technology, biofabrication of circumferentially multilayered tubular tissues or organs with cellular heterogeneity, such as blood vessels, trachea, intestine, colon, ureter, and urethra, remains a challenge. Herein, a promising multichannel coaxial extrusion system (MCCES) for microfluidic bioprinting of circumferentially multilayered tubular tissues in a single step, using customized bioinks constituting gelatin methacryloyl, alginate, and eight-arm poly(ethylene glycol) acrylate with a tripentaerythritol core, is presented. These perfusable cannular constructs can be continuously tuned up from monolayer to triple layers at regular intervals across the length of a bioprinted tube. Using customized bioink and MCCES, bioprinting of several tubular tissue constructs using relevant cell types with adequate biofunctionality including cell viability, proliferation, and differentiation is demonstrated. Specifically, cannular urothelial tissue constructs are bioprinted, using human urothelial cells and human bladder smooth muscle cells, as well as vascular tissue constructs, using human umbilical vein endothelial cells and human smooth muscle cells. These bioprinted cannular tissues can be actively perfused with fluids and nutrients to promote growth and proliferation of the embedded cell types. The fabrication of such tunable and perfusable circumferentially multilayered tissues represents a fundamental step toward creating human cannular tissues., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

7. Advances in xenogeneic donor decellularized organs: A review on studies with sheep and porcine‐derived heart valves.

Author

Inal, Muslum Suleyman, Avci, Huseyin, Hassan, Shabir, Darcan, Cihan, Shin, Su Ryon, and Akpek, Ali

Subjects

BIOPRINTING, HEART valves, REGENERATIVE medicine, TISSUE engineering, BIOPROSTHESIS

Abstract

Heart valve replacement surgeries are performed on patients suffering from abnormal heart valve function. In these operations, the problematic tissue is replaced with mechanical valves or with bioprosthetics that are being developed. The thrombotic effect of mechanical valves, reflecting the need for lifelong use of anticoagulation drugs, and the short‐lived nature of biological valves make these two types of valves problematic. In addition, they cannot adapt to the somatic growth of young patients. Although decellularized scaffolds have shown some promise, a successful translation has so far evaded. Although decellularized porcine xenografts have been extensively studied in the literature, they have several disadvantages, such as a propensity for calcification in the implant model, a risk of porcine endogenous retrovirus (PERV) infection, and a high xenoantigen density. As seen in clinical data, it is clear that there are biocompatibility problems in almost all studies. However, since decellularized sheep heart valves have not been tried in the clinic, a large data pool could not be established. This review compares and contrasts decellularized porcine and sheep xenografts for heart valve tissue engineering. It reveals that decellularized sheep heart valves can be an alternative to pigs in terms of biocompatibility. In addition, it highlights the potential advantages of bioinks derived from the decellularized extracellular matrix in 3D bioprinting technology, emphasizing that they can be a new alternative for the application. We also outline the future prospects of using sheep xenografts for heart valve tissue engineering. [ABSTRACT FROM AUTHOR]

Published

2024

8. Bioprinted 3D vascularized tissue model for drug toxicity analysis.

Author

Massa, Solange, Sakr, Mahmoud Ahmed, Jungmok Seo, Bandaru, Praveen, Arneri, Andrea, Bersini, Simone, Zare-Eelanjegh, Elaheh, Jalilian, Elmira, Byung-Hyun Cha, Antona, Silvia, Enrico, Alessandro, Yuan Gao, Hassan, Shabir, Acevedo, Juan Pablo, Dokmeci, Mehmet R., Yu Shrike Zhang, Khademhosseini, Ali, and Su Ryon Shin

Subjects

THREE-dimensional printing, TISSUE engineering, BIONICS, BIOMIMETIC chemicals, BIOPRINTING

Abstract

To develop biomimetic three-dimensional (3D) tissue constructs for drug screening and biological studies, engineered blood vessels should be integrated into the constructs to mimic the drug administration process in vivo. The development of perfusable vascularized 3D tissue constructs for studying the drug administration process through an engineered endothelial layer remains an area of intensive research. Here, we report the development of a simple 3D vascularized liver tissue model to study drug toxicity through the incorporation of an engineered endothelial layer. Using a sacrificial bioprinting technique, a hollow microchannel was successfully fabricated in the 3D liver tissue construct created with HepG2/C3A cells encapsulated in a gelatin methacryloyl hydrogel. After seeding human umbilical vein endothelial cells (HUVECs) into the microchannel, we obtained a vascularized tissue construct containing a uniformly coated HUVEC layer within the hollow microchannel. The inclusion of the HUVEC layer into the scaffold resulted in delayed permeability of biomolecules into the 3D liver construct. In addition, the vascularized construct containing the HUVEC layer showed an increased viability of the HepG2/C3A cells within the 3D scaffold compared to that of the 3D liver constructs without the HUVEC layer, demonstrating a protective role of the introduced endothelial cell layer. The 3D vascularized liver model presented in this study is anticipated to provide a better and more accurate in vitro liver model system for future drug toxicity testing. [ABSTRACT FROM AUTHOR]

Published

2017

9. Bioprinting: A Tumor‐on‐a‐Chip System with Bioprinted Blood and Lymphatic Vessel Pair (Adv. Funct. Mater. 31/2019).

Author

Cao, Xia, Ashfaq, Ramla, Cheng, Feng, Maharjan, Sushila, Li, Jun, Ying, Guoliang, Hassan, Shabir, Xiao, Haiyan, Yue, Kan, and Zhang, Yu Shrike

Subjects

BIOPRINTING, BLOOD vessels, EXTRACELLULAR fluid

Abstract

Highlights from the article: Bioprinting: A Tumor-on-a-Chip System with Bioprinted Blood and Lymphatic Vessel Pair (Adv. Funct. Keywords: bioprinting; blood vessels; diffusion; lymphatic vessels; tumor-on-a-chip Bioprinting, blood vessels, diffusion, lymphatic vessels, tumor-on-a-chip.

Published

2019

10. A Tumor‐on‐a‐Chip System with Bioprinted Blood and Lymphatic Vessel Pair.

Author

Cao, Xia, Ashfaq, Ramla, Cheng, Feng, Maharjan, Sushila, Li, Jun, Ying, Guoliang, Hassan, Shabir, Xiao, Haiyan, Yue, Kan, and Zhang, Yu Shrike

Subjects

BLOOD vessels, BIOLOGICAL systems, DOSAGE forms of drugs, EARLY detection of cancer

Abstract

Current in vitro antitumor drug screening strategies insufficiently mimic biological systems. They tend to lack true perfusion and draining microcirculation systems, which may post significant limitations in explicitly reproducing the transport kinetics of cancer therapeutics. Herein, the fabrication of an improved tumor model consisting of a bioprinted hollow blood vessel and a lymphatic vessel pair, hosted in a 3D tumor microenvironment‐mimetic hydrogel matrix is reported, termed as the tumor‐on‐a‐chip with a bioprinted blood and a lymphatic vessel pair (TOC‐BBL). The bioprinted blood vessel is a perfusable channel with an opening on both ends, while the bioprinted lymphatic vessel is blinded on one end, both of which are embedded in a hydrogel tumor mass, with vessel permeability individually tunable through optimization of the compositions of the bioinks. It is demonstrated that systems with different combinations of these bioprinted blood/lymphatic vessels exhibit varying levels of diffusion profiles for biomolecules and anticancer drugs. The results suggest that this unique in vitro tumor model containing the bioprinted blood/lymphatic vessel pair may have the capacity of simulating the complex transport mechanisms of certain pharmaceutical compounds inside the tumor microenvironment, potentially providing improved accuracy in future cancer drug screening. [ABSTRACT FROM AUTHOR]

Published

2019

11. Modular fabrication of intelligent material-tissue interfaces for bioinspired and biomimetic devices.

Author

Clegg, John R., Wagner, Angela M., Shin, Su Ryon, Hassan, Shabir, Khademhosseini, Ali, and Peppas, Nicholas A.

Subjects

*BIOMIMETIC materials, *REVERSE engineering, *ELECTROMAGNETIC fields, *SOFT robotics, *THREE-dimensional printing, *BIOPRINTING

Abstract

One of the goals of biomaterials science is to reverse engineer aspects of human and non-human physiology. Similar to the body's regulatory mechanisms, such devices must transduce changes in the physiological environment or the presence of an external stimulus into a detectable or therapeutic response. This review is a comprehensive evaluation and critical analysis of the design and fabrication of environmentally responsive cell-material constructs for bioinspired machinery and biomimetic devices. In a bottom-up analysis, we begin by reviewing fundamental principles that explain materials' responses to chemical gradients, biomarkers, electromagnetic fields, light, and temperature. Strategies for fabricating highly ordered assemblies of material components at the nano to macro-scales via directed assembly, lithography, 3D printing and 4D printing are also presented. We conclude with an account of contemporary material-tissue interfaces within bioinspired and biomimetic devices for peptide delivery, cancer theranostics, biomonitoring, neuroprosthetics, soft robotics, and biological machines. [ABSTRACT FROM AUTHOR]

Published

2019