Your search keyword '"BIOMATERIALS"' showing total 17,089 results

1. Microfluidic human physiomimetic liver model as a screening platform for drug induced liver injury.

Author

Dey, Souradeep, Bhat, Amritha, Janani, G., Shandilya, Vartik, Gupta, Raghvendra, and Mandal, Biman B.

Subjects

*DRUG side effects, *LIVER injuries, *LIVER cells, *BIOMATERIALS, *LIVER, *THREE-dimensional printing, *RHEOLOGY

Abstract

The pre-clinical animal models often fail to predict intrinsic and idiosyncratic drug induced liver injury (DILI), thus contributing to drug failures in clinical trials, black box warnings and withdrawal of marketed drugs. This suggests a critical need for human-relevant in vitro models to predict diverse DILI phenotypes. In this study, a porcine liver extracellular matrix (ECM) based biomaterial ink with high printing fidelity, biocompatibility and tunable rheological and mechanical properties is formulated for supporting both parenchymal and non-parenchymal cells. Further, we applied 3D printing and microfluidic technology to bioengineer a human physiomimetic liver acinus model (HPLAM), recapitulating the radial hepatic cord-like structure with functional sinusoidal microvasculature network, biochemical and biophysical properties of native liver acinus. Intriguingly, the human derived hepatic cells incorporated HPLAM cultured under physiologically relevant microenvironment, acts as metabolic biofactories manifesting enhanced hepatic functionality, secretome levels and biomarkers expression over several weeks. We also report that the matured HPLAM reproduces dose- and time-dependent hepatotoxic response of human clinical relevance to drugs typically recognized for inducing diverse DILI phenotypes as compared to conventional static culture. Overall, the developed HPLAM emulates in vivo like functions and may provide a useful platform for DILI risk assessment to better determine safety and human risk. In line with the evolution of in vitro liver models, a human physiomimetic liver acinus model (HPLAM) is bioengineered using transdisciplinary technologies for assessing diverse phenotypes of drug induced liver injury with more human specific sensitivity. The microfluidic bioreactor-based HPLAM acts as metabolic biofactories emulating in vivo like hepatic functionality and demonstrates dose- and time-dependent hepatotoxic response of human relevance (Created with BioRender.com). [Display omitted]. [ABSTRACT FROM AUTHOR]

Published

2024

2. Mechanical heterogeneity in a soft biomaterial niche controls BMP2 signaling.

Author

Brauer, Erik, Herrera, Aaron, Fritsche-Guenther, Raphaela, Görlitz, Sophie, Leemhuis, Hans, Knaus, Petra, Kirwan, Jennifer A., Duda, Georg N., and Petersen, Ansgar

Subjects

*GROWTH factors, *STRAINS & stresses (Mechanics), *EXTRACELLULAR matrix, *HETEROGENEITY, *FINITE element method, *BIOMATERIALS, *PLATELET-rich plasma

Abstract

The extracellular matrix is known to impact cell function during regeneration by modulating growth factor signaling. However, how the mechanical properties and structure of biomaterials can be used to optimize the cellular response to growth factors is widely neglected. Here, we engineered a macroporous biomaterial to study cellular signaling in environments that mimic the mechanical stiffness but also the mechanical heterogeneity of native extracellular matrix. We found that the mechanical interaction of cells with the heterogeneous and non-linear deformation properties of soft matrices (E < 5 kPa) enhances BMP-2 growth factor signaling with high relevance for tissue regeneration. In contrast, this effect is absent in homogeneous hydrogels that are often used to study cell responses to mechanical cues. Live cell imaging and in silico finite element modeling further revealed that a subpopulation of highly active, fast migrating cells is responsible for most of the material deformation, while a second, less active population experiences this deformation as an extrinsic mechanical stimulation. At an overall low cell density, the active cell population dominates the process, suggesting that it plays a particularly important role in early tissue healing scenarios where cells invade tissue defects or implanted biomaterials. Taken together, our findings demonstrate that the mechanical heterogeneity of the natural extracellular matrix environment plays an important role in triggering regeneration by endogenously acting growth factors. This suggests the inclusion of such mechanical complexity as a design parameter in future biomaterials, in addition to established parameters such as mechanical stiffness and stress relaxation. [ABSTRACT FROM AUTHOR]

Published

2024

3. Dynamic injectable tissue adhesives with strong adhesion and rapid self-healing for regeneration of large muscle injury.

Author

Nam, Sungmin, Lou, Junzhe, Lee, Sangmin, Kartenbender, Jan-Marc, and Mooney, David J.

Subjects

*MUSCLE injuries, *MUSCLE regeneration, *ADHESIVES, *ULTRASONIC imaging, *HEMATOPOIESIS

Abstract

Wounds often necessitate the use of instructive biomaterials to facilitate effective healing. Yet, consistently filling the wound and retaining the material in place presents notable challenges. Here, we develop a new class of injectable tissue adhesives by leveraging the dynamic crosslinking chemistry of Schiff base reactions. These adhesives demonstrate outstanding mechanical properties, especially in regard to stretchability and self-healing capacity, and biodegradability. Furthermore, they also form robust adhesion to biological tissues. Their therapeutic potential was evaluated in a rodent model of volumetric muscle loss (VML). Ultrasound imaging confirmed that the adhesives remained within the wound site, effectively filled the void, and degraded at a rate comparable to the healing process. Histological analysis indicated that the adhesives facilitated muscle fiber and blood vessel formation, and induced anti-inflammatory macrophages. Notably, the injured muscles of mice treated with the adhesives displayed increased weight and higher force generation than the control groups. This approach to adhesive design paves the way for the next generation of medical adhesives in tissue repair. [ABSTRACT FROM AUTHOR]

Published

2024

4. Trehalose-based coacervates for local bioactive protein delivery to the central nervous system.

Author

Hassan, Laboni F., Sen, Riya, and O'Shea, Timothy M.

Subjects

*CENTRAL nervous system, *TREHALOSE, *MICHAEL reaction, *NEUROTROPHIN receptors, *THERAPEUTIC use of proteins, *GROWTH factors, *PROTEINS

Abstract

Therapeutic outcomes of local biomolecule delivery to the central nervous system (CNS) using bulk biomaterials are limited by inadequate drug loading, neuropil disruption, and severe foreign body responses. Effective CNS delivery requires addressing these issues and developing well-tolerated, highly-loaded carriers that are dispersible within local neural parenchyma. Here, we synthesized biodegradable trehalose-based polyelectrolyte oligomers using facile A2:B3:AR thiol-ene Michael addition reactions that form complex coacervates upon mixing of oppositely charged oligomers. Coacervates permit high concentration loading and controlled release of bioactive growth factors, enzymes, and antibodies, with modular formulation parameters that confer tunable release kinetics. Coacervates are cytocompatible with cultured neural cells in vitro and can be formulated to either direct intracellular protein delivery or sequester media containing proteins and remain extracellular. Coacervates serve as effective vehicles for precisely delivering biomolecules, including bioactive neurotrophins, to the mouse striatum following intraparenchymal injection. These results support the use of trehalose-based coacervates as part of therapeutic protein delivery strategies for CNS disorders. [ABSTRACT FROM AUTHOR]

Published

2024

5. Editorial Note: 'The nanoformula of zoledronic acid and calcium carbonate targets osteoclasts and reverses osteoporosis' Biomaterials, 296 (2023), 122059.

Subjects

*ZOLEDRONIC acid, *CALCIUM carbonate, *OSTEOCLASTS, *BIOMATERIALS, *OSTEOPOROSIS

Published

2025

6. Corrigendum to "Bidirectional juxtacrine ephrinB2/Ephs signaling promotes angiogenesis of ECs and maintains self-renewal of MSCs" [Biomaterials 172 (2018) 1–13].

Author

Cao, Cen, Huang, Ying, Tang, Qingming, Zhang, Chenguang, Shi, Lei, Zhao, Jiajia, Hu, Li, Hu, Zhewen, Liu, Yun, and Chen, Lili

Subjects

*BIOMATERIALS, *NEOVASCULARIZATION

Published

2025

7. Intrinsic antimicrobial resistance: Molecular biomaterials to combat microbial biofilms and bacterial persisters.

Author

Barman, Swagatam, Kurnaz, Leman Buzoglu, Leighton, Ryan, Hossain, Md Waliullah, Decho, Alan W., and Tang, Chuanbing

Subjects

*ANTIMICROBIAL peptides, *DRUG resistance in microorganisms, *STRUCTURE-activity relationships, *BACTERIAL cells, *BIOFILMS, *PEPTIDE antibiotics

Abstract

The escalating rise in antimicrobial resistance (AMR) coupled with a declining arsenal of new antibiotics is imposing serious threats to global public health. A pervasive aspect of many acquired AMR infections is that the pathogenic microorganisms exist as biofilms, which are equipped with superior survival strategies. In addition, persistent and recalcitrant infections are seeded with bacterial persister cells at infection sites. Together, conventional antibiotic therapeutics often fail in the complete treatment of infections associated with bacterial persisters and biofilms. Novel therapeutics have been attempted to tackle AMR, biofilms, and persister-associated complex infections. This review focuses on the progress in designing molecular biomaterials and therapeutics to address acquired and intrinsic AMR, and the fundamental microbiology behind biofilms and persisters. Starting with a brief introduction of AMR basics and approaches to tackling acquired AMR, the emphasis is placed on various biomaterial approaches to combating intrinsic AMR, including (1) semi-synthetic antibiotics; (2) macromolecular or polymeric biomaterials mimicking antimicrobial peptides; (3) adjuvant effects in synergy; (4) nano-therapeutics; (5) nitric oxide-releasing antimicrobials; (6) antimicrobial hydrogels; (7) antimicrobial coatings. Particularly, the structure-activity relationship is elucidated in each category of these biomaterials. Finally, illuminating perspectives are provided for the future design of molecular biomaterials to bypass AMR and cure chronic multi-drug resistant (MDR) infections. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

8. Corrigendum to "HIF-2α-targeted interventional chemoembolization multifunctional microspheres for effective elimination of hepatocellular carcinoma" [Biomaterials 284 (2022) 121512].

Author

Chen, Minjiang, Shu, Gaofeng, Lv, Xiuling, Xu, Xiaoling, Lu, Chenying, Qiao, Enqi, Fang, Shiji, Shen, Lin, Zhang, Nannan, Wang, Jun, Chen, Chunmiao, Song, Jingjing, Liu, Zhuang, Du, Yongzhong, and Ji, Jiansong

Subjects

*HEPATOCELLULAR carcinoma, *CHEMOEMBOLIZATION, *BIOMATERIALS, *MICROSPHERES

Published

2024

9. Skin repair and infection control in diabetic, obese mice using bioactive laser-activated sealants.

Author

Pallod, Shubham, Aguilera Olvera, Rodrigo, Ghosh, Deepanjan, Rai, Lama, Brimo, Souzan, DeCambra, Weston, Sant, Harsh Girish, Ristich, Eron, Singh, Vanshika, Abedin, Muhammad Raisul, Chang, Nicolas, Yarger, Jeffery L., Lee, Jung Keun, Kilbourne, Jacquelyn, Yaron, Jordan R., Haydel, Shelley E., and Rege, Kaushal

Subjects

*METHICILLIN-resistant staphylococcus aureus, *THERMOTHERAPY, *SURGICAL wound dehiscence, *HEALING, *SKIN injuries, *WOUND healing

Abstract

Conventional wound approximation devices, including sutures, staples, and glues, are widely used but risk of wound dehiscence, local infection, and scarring can be exacerbated in these approaches, including in diabetic and obese individuals. This study reports the efficacy and quality of tissue repair upon photothermal sealing of full-thickness incisional skin wounds using silk fibroin-based laser-activated sealants (LASEs) containing copper chloride salt (Cu-LASE) or silver nanoprisms (AgNPr-LASE), which absorb and convert near-infrared (NIR) laser energy to heat. LASE application results in rapid and effective skin sealing in healthy, immunodeficient, as well as diabetic and obese mice. Although lower recovery of epidermal structure and function was seen with AgNPr-LASE sealing, likely because of the hyperthermia induced by laser and presence of this material in the wound space, this approach resulted in higher enhancement in recovery of skin biomechanical strength compared to sutures and Cu-LASEs in diabetic, obese mice. Histological and immunohistochemical analyses revealed that AgNPr-LASEs resulted in significantly lower neutrophil migration to the wound compared to Cu-LASEs and sutures, indicating a more muted inflammatory response. Cu-LASEs resulted in local tissue toxicity likely because of effects of copper ions as manifested in the form of a significant epidermal gap and a 'depletion zone', which was a region devoid of viable cells proximal to the wound. Compared to sutures, LASE-mediated sealing, in later stages of healing, resulted in increased angiogenesis and diminished myofibroblast activation, which can be indicative of lower scarring. AgNPr-LASE loaded with vancomycin, an antibiotic drug, significantly lowered methicillin-resistant Staphylococcus aureus (MRSA) load in a pathogen challenge model in diabetic and obese mice and also reduced post-infection inflammation of tissue compared to antibacterial sutures. Taken together, these attributes indicate that AgNPr-LASE demonstrated a more balanced quality of tissue sealing and repair in diabetic and obese mice and can be used for combating local infections, that can result in poor healing in these individuals. [ABSTRACT FROM AUTHOR]

Published

2024

10. Corrigendum to 'Engineered multilayer ovarian tissue that secretes sex steroids and peptide hormones in response to gonadotropins' [Biomaterials 34/10 (2013) 2412–2420].

Author

Sittadjody, Sivanandane, Saul, Justin M., Joo, Sunyoung, Yoo, James J., Atala, Anthony, and Opara, Emmanuel C.

Subjects

*SEX hormones, *BIOMATERIALS, *TISSUES, *ENGINEERING

Published

2024

11. Implantable CAR T cell factories enhance solid tumor treatment.

Author

Pandit, Sharda, Agarwalla, Pritha, Song, Feifei, Jansson, Anton, Dotti, Gianpietro, and Brudno, Yevgeny

Subjects

*T cells, *TUMOR treatment, *CHIMERIC antigen receptors, *MANUFACTURING cells, *HOSPITAL central service departments, *HEMATOLOGIC malignancies, *BLOOD collection

Abstract

Chimeric Antigen Receptor (CAR) T cell therapy has produced revolutionary success in hematological cancers such as leukemia and lymphoma. Nonetheless, its translation to solid tumors faces challenges due to manufacturing complexities, short-lived in vivo persistence, and transient therapeutic impact. We introduce 'Drydux' - an innovative macroporous biomaterial scaffold designed for rapid, efficient in-situ generation of tumor-specific CAR T cells. Drydux expedites CAR T cell preparation with a mere three-day turnaround from patient blood collection, presenting a cost-effective, streamlined alternative to conventional methodologies. Notably, Drydux-enabled CAR T cells provide prolonged in vivo release, functionality, and enhanced persistence exceeding 150 days, with cells transitioning to memory phenotypes. Unlike conventional CAR T cell therapy, which offered only temporary tumor control, equivalent Drydux cell doses induced lasting tumor remission in various animal tumor models, including systemic lymphoma, peritoneal ovarian cancer, metastatic lung cancer, and orthotopic pancreatic cancer. Drydux's approach holds promise in revolutionizing solid tumor CAR T cell therapy by delivering durable, rapid, and cost-effective treatments and broadening patient accessibility to this groundbreaking therapy. Schematics showing conventional CAR T cell manufacturing requiring ∼2 weeks (A) compared to simplified and rapid Drydux mediated in vivo CAR T cell manufacturing (B). [Display omitted] Implantable CAR T cell factories enhance CAR T cell therapy and drastically improve their function and persistence, offering a more effective and accessible cancer treatment. [ABSTRACT FROM AUTHOR]

Published

2024

12. Exosomes based strategies for cardiovascular diseases: Opportunities and challenges.

Author

Li, Hang, Zhang, Jun, Tan, Mingyue, Yin, Yunfei, Song, Yiyi, Zhao, Yongjian, Yan, Lin, Li, Ning, Zhang, Xianzuo, Bai, Jiaxiang, Jiang, Tingbo, and Li, Hongxia

Subjects

*EXOSOMES, *TISSUE engineering, *CARDIOVASCULAR diseases, *EXTRACELLULAR vesicles, *CELL communication, *CARDIOVASCULAR development, *REGENERATIVE medicine, *BIOMATERIALS

Abstract

Exosomes, as nanoscale extracellular vesicles (EVs), are secreted by all types of cells to facilitate intercellular communication in living organisms. After being taken up by neighboring or distant cells, exosomes can alter the expression levels of target genes in recipient cells and thereby affect their pathophysiological outcomes depending on payloads encapsulated therein. The functions and mechanisms of exosomes in cardiovascular diseases have attracted much attention in recent years and are thought to have cardioprotective and regenerative potential. This review summarizes the biogenesis and molecular contents of exosomes and details the roles played by exosomes released from various cells in the progression and recovery of cardiovascular disease. The review also discusses the current status of traditional exosomes in cardiovascular tissue engineering and regenerative medicine, pointing out several limitations in their application. It emphasizes that some of the existing emerging industrial or bioengineering technologies are promising to compensate for these shortcomings, and the combined application of exosomes and biomaterials provides an opportunity for mutual enhancement of their performance. The integration of exosome-based cell-free diagnostic and therapeutic options will contribute to the further development of cardiovascular regenerative medicine. [Display omitted] • Exosomes are involved in the process of intercellular communication by delivering biologically active payloads. • Exosomes derived from multiple cell types were illustrated to be extremely involved in the pathologic process of cardiovascular diseases. • The application of exosomes still faces multifaceted challenges. • Engineering modifications to exosomes or combining them with biomaterials are promising ideas for drug delivery. [ABSTRACT FROM AUTHOR]

Published

2024

13. Progress in the development of piezoelectric biomaterials for tissue remodeling.

Author

Nain, Amit, Chakraborty, Srishti, Barman, Snigdha Roy, Gavit, Pratik, Indrakumar, Sushma, Agrawal, Akhilesh, Lin, Zong-Hong, and Chatterjee, Kaushik

Subjects

*TISSUE remodeling, *BIOMATERIALS, *PIEZOELECTRIC materials, *BIOELECTRONICS, *ENERGY harvesting, *PIEZOELECTRIC ceramics, *TISSUE engineering

Abstract

Piezoelectric biomaterials have demonstrated significant potential in the past few decades to heal damaged tissue and restore cellular functionalities. Herein, we discuss the role of bioelectricity in tissue remodeling and explore ways to mimic such tissue-like properties in synthetic biomaterials. In the past decade, biomedical engineers have adopted emerging functional biomaterials-based tissue engineering approaches using innovative bioelectronic stimulation protocols based on dynamic stimuli to direct cellular activation, proliferation, and differentiation on engineered biomaterial constructs. The primary focus of this review is to discuss the concepts of piezoelectric energy harvesting, piezoelectric materials, and their application in soft (skin and neural) and hard (dental and bone) tissue regeneration. While discussing the prospective applications as an engineered tissue, an important distinction has been made between piezoceramics, piezopolymers, and their composites. The superiority of piezopolymers over piezoceramics to circumvent issues such as stiffness mismatch, biocompatibility, and biodegradability are highlighted. We aim to provide a comprehensive review of the field and identify opportunities for the future to develop clinically relevant and state-of-the-art biomaterials for personalized and remote health care. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

14. Corrigendum to "On-site fabrication of bi-layered adhesive mesenchymal stromal cell dressings for the treatment of heart failure" [Biomaterials 209 (2019) 41–53].

Author

Kobayashi, Kazuya, Ichihara, Yuki, Sato, Nobuhiko, Umeda, Nobuyoshi, Fields, Laura, Fukumitsu, Masafumi, Tago, Yoshiyuki, Ito, Tomoya, Kainuma, Satoshi, Podaru, Mihai, Lewis-McDougall, Fiona, Yamahara, Kenichi, Uppal, Rakesh, and Suzuki, Ken

Subjects

*STROMAL cells, *TREATMENT failure, *HEART failure, *ADHESIVES, *BIOMATERIALS

Published

2024

15. Stiffness assisted cell-matrix remodeling trigger 3D mechanotransduction regulatory programs.

Author

Kersey, Anna L., Cheng, Daniel Y., Deo, Kaivalya A., Dubell, Christina R., Wang, Ting-Ching, Jaiswal, Manish K., Kim, Min Hee, Murali, Aparna, Hargett, Sarah E., Mallick, Sumana, Lele, Tanmay P., Singh, Irtisha, and Gaharwar, Akhilesh K.

Subjects

*MECHANOTRANSDUCTION (Cytology), *HUMAN stem cells, *MESENCHYMAL stem cells, *REGENERATIVE medicine, *YAP signaling proteins

Abstract

Engineered matrices provide a valuable platform to understand the impact of biophysical factors on cellular behavior such as migration, proliferation, differentiation, and tissue remodeling, through mechanotransduction. While recent studies have identified some mechanisms of 3D mechanotransduction, there is still a critical knowledge gap in comprehending the interplay between 3D confinement, ECM properties, and cellular behavior. Specifically, the role of matrix stiffness in directing cellular fate in 3D microenvironment, independent of viscoelasticity, microstructure, and ligand density remains poorly understood. To address this gap, we designed a nanoparticle crosslinker to reinforce collagen-based hydrogels without altering their chemical composition, microstructure, viscoelasticity, and density of cell-adhesion ligand and utilized it to understand cellular dynamics. This crosslinking mechanism utilizes nanoparticles as crosslink epicenter, resulting in 10-fold increase in mechanical stiffness, without other changes. Human mesenchymal stem cells (hMSCs) encapsulated in 3D responded to mechanical stiffness by displaying circular morphology on soft hydrogels (5 kPa) and elongated morphology on stiff hydrogels (30 kPa). Stiff hydrogels facilitated the production and remodeling of nascent extracellular matrix (ECM) and activated mechanotransduction cascade. These changes were driven through intracellular PI3AKT signaling, regulation of epigenetic modifiers and activation of YAP/TAZ signaling. Overall, our study introduces a unique biomaterials platform to understand cell–ECM mechanotransduction in 3D for regenerative medicine as well as disease modelling. [ABSTRACT FROM AUTHOR]

Published

2024

16. Custom-engineered hydrogels for delivery of human iPSC-derived neurons into the injured cervical spinal cord.

Author

Doulames, V.M., Marquardt, L.M., Hefferon, M.E., Baugh, N.J., Suhar, R.A., Wang, A.T., Dubbin, K.R., Weimann, J.M., Palmer, T.D., Plant, G.W., and Heilshorn, S.C.

Subjects

*SPINAL cord, *CERVICAL cord, *INDUCED pluripotent stem cells, *BIOMIMETIC materials, *NEURONS, *AMINO acid sequence, *SPINAL cord injuries

Abstract

Cervical damage is the most prevalent type of spinal cord injury clinically, although few preclinical research studies focus on this anatomical region of injury. Here we present a combinatorial therapy composed of a custom-engineered, injectable hydrogel and human induced pluripotent stem cell (iPSC)-derived deep cortical neurons. The biomimetic hydrogel has a modular design that includes a protein-engineered component to allow customization of the cell-adhesive peptide sequence and a synthetic polymer component to allow customization of the gel mechanical properties. In vitro studies with encapsulated iPSC-neurons were used to select a bespoke hydrogel formulation that maintains cell viability and promotes neurite extension. Following injection into the injured cervical spinal cord in a rat contusion model, the hydrogel biodegraded over six weeks without causing any adverse reaction. Compared to cell delivery using saline, the hydrogel significantly improved the reproducibility of cell transplantation and integration into the host tissue. Across three metrics of animal behavior, this combinatorial therapy significantly improved sensorimotor function by six weeks post transplantation. Taken together, these findings demonstrate that design of a combinatorial therapy that includes a gel customized for a specific fate-restricted cell type can induce regeneration in the injured cervical spinal cord. [ABSTRACT FROM AUTHOR]

Published

2024

17. Biomaterials and bioelectronics for self-powered neurostimulation.

Author

Li, Jinlong, Che, Ziyuan, Wan, Xiao, Manshaii, Farid, Xu, Jing, and Chen, Jun

Subjects

*BIOELECTRONICS, *NEURAL stimulation, *PERIPHERAL nervous system, *TRIBOELECTRICITY, *ELECTRIC stimulation

Abstract

Self-powered neurostimulation via biomaterials and bioelectronics innovation has emerged as a compelling approach to explore, repair, and modulate neural systems. This review examines the application of self-powered bioelectronics for electrical stimulation of both the central and peripheral nervous systems, as well as isolated neurons. Contemporary research has adeptly harnessed biomechanical and biochemical energy from the human body, through various mechanisms such as triboelectricity, piezoelectricity, magnetoelasticity, and biofuel cells, to power these advanced bioelectronics. Notably, these self-powered bioelectronics hold substantial potential for delivering neural stimulations that are customized for the treatment of neurological diseases, facilitation of neural regeneration, and the development of neuroprosthetics. Looking ahead, we expect that the ongoing advancements in biomaterials and bioelectronics will drive the field of self-powered neurostimulation toward the realization of more advanced, closed-loop therapeutic solutions, paving the way for personalized and adaptable neurostimulators in the coming decades. [ABSTRACT FROM AUTHOR]

Published

2024

18. Biomaterials-mediated targeted therapeutics of myocardial ischemia-reperfusion injury.

Author

Luo, Qiang, Sun, Wei, Li, Zhibo, Sun, Jinfeng, Xiao, Yu, Zhang, Jichang, Zhu, Cuilin, Liu, Bin, and Ding, Jianxun

Subjects

*REPERFUSION, *REPERFUSION injury, *MYOCARDIAL infarction, *BIOMATERIALS, *CALCIUM ions, *DRUG administration, *ANTI-inflammatory agents

Abstract

Reperfusion therapy is widely used to treat acute myocardial infarction. However, its efficacy is limited by myocardial ischemia-reperfusion injury (MIRI), which occurs paradoxically due to the reperfusion therapy and contributes to the high mortality rate of acute myocardial infarction. Systemic administration of drugs, such as antioxidant and anti-inflammatory agents, to reduce MIRI is often ineffective due to the inadequate release at the pathological sites. Functional biomaterials are being developed to optimize the use of drugs by improving their targetability and bioavailability and reducing side effects, such as gastrointestinal irritation, thrombocytopenia, and liver damage. This review provides an overview of controlled drug delivery biomaterials for treating MIRI by triggering antioxidation, calcium ion overload inhibition, and/or inflammation regulation mechanisms and discusses the challenges and potential applications of these treatments clinically. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

19. The cell in the ink: Improving biofabrication by printing stem cells for skeletal regenerative medicine.

Author

Cidonio, G., Glinka, M., Dawson, J.I., and Oreffo, R.O.C.

Subjects

*STEM cells, *CELL morphology, *CELL populations, *BIOMATERIALS, *CELL preservation, *REGENERATIVE medicine, *CELL aggregation

Abstract

Recent advances in regenerative medicine have confirmed the potential to manufacture viable and effective tissue engineering 3D constructs comprising living cells for tissue repair and augmentation. Cell printing has shown promising potential in cell patterning in a number of studies enabling stem cells to be precisely deposited as a blueprint for tissue regeneration guidance. Such manufacturing techniques, however, face a number of challenges including; (i) post-printing cell damage, (ii) proliferation impairment and, (iii) poor or excessive final cell density deposition. The use of hydrogels offers one approach to address these issues given the ability to tune these biomaterials and subsequent application as vectors capable of delivering cell populations and as extrusion pastes. While stem cell-laden hydrogel 3D constructs have been widely established in vitro , clinical relevance, evidenced by in vivo long-term efficacy and clinical application, remains to be demonstrated. This review explores the central features of cell printing, cell-hydrogel properties and cell-biomaterial interactions together with the current advances and challenges in stem cell printing. A key focus is the translational hurdles to clinical application and how in vivo research can reshape and inform cell printing applications for an ageing population. Cell printing - capacity and limitations. Cell type and density are important factors in the printing of living cells. Post-printing consequences including: (i) impaired cell proliferation, (ii) maintenance of phenotype and genotype, (iii) preservation of cell integrity and morphology are issues that need to be considered. Stem cell printing aims to deposit cells in three dimensions within an environment conducive to proliferation and differentiation. Therefore, long-term investigations of cell viability and proliferation in vitro and in vivo are required to elucidate construct maturation and effective tissue regeneration and integration. Importantly, the properties of the hydrogel cell carrier (biocompatibility, bioactivity, physical characteristics) for the select 3D print approach envisaged are crucial for cell encapsulation, protection and support during differentiation and proliferation. Image 1 [ABSTRACT FROM AUTHOR]

Published

2019

20. A three-dimensional (3D) organotypic microfluidic model for glioma stem cells – Vascular interactions.

Author

Truong, Danh, Fiorelli, Roberto, Barrientos, Eric S., Melendez, Ernesto Luna, Sanai, Nader, Mehta, Shwetal, and Nikkhah, Mehdi

Subjects

*MICROFLUIDICS, *GLIOMA treatment, *THREE-dimensional imaging, *CANCER cell proliferation, *CANCER stem cells, *BIOMATERIALS

Abstract

Abstract Glioblastoma (GBM) is one of the deadliest forms of cancer. Despite many treatment options, prognosis of GBM remains dismal with a 5-year survival rate of 4.7%. Even then, tumors often recur after treatment. Tumor recurrence is hypothesized to be driven by glioma stem cell (GSC) populations which are highly tumorigenic, invasive, and resistant to several forms of therapy. GSCs are often concentrated around the tumor vasculature, referred to as the vascular niche, which are known to provide microenvironmental cues to maintain GSC stemness, promote invasion, and resistance to therapies. In this work, we developed a 3D organotypic microfluidic platform, integrated with hydrogel-based biomaterials, to mimic the GSC vascular niche and study the influence of endothelial cells (ECs) on patient-derived GSC behavior and identify signaling cues that mediate their invasion and phenotype. The established microvascular network enhanced GSC migration within a 3D hydrogel, promoted invasive morphology as well as maintained GSC proliferation rates and phenotype (Nestin, SOX2, CD44). Notably, we compared migration behavior to in vivo mice model and found similar invasive morphology suggesting that our microfluidic system could represent a physiologically relevant in vivo microenvironment. Moreover, we confirmed that CXCL12-CXCR4 signaling is involved in promoting GSC invasion in a 3D vascular microenvironment by utilizing a CXCR4 antagonist (AMD3100), while also demonstrating the effectiveness of the microfluidic as a drug screening assay. Our model presents a potential ex vivo platform for studying the interplay of GSCs with its surrounding microenvironment as well as development of future therapeutic strategies tailored toward disrupting key molecular pathways involved in GSC regulatory mechanisms. [ABSTRACT FROM AUTHOR]

Published

2019

21. Tissue engineered bone mimetics to study bone disorders ex vivo: Role of bioinspired materials.

Author

Shih, Yuru Vernon and Varghese, Shyni

Subjects

*BONE diseases, *TISSUE engineering, *EXTRACELLULAR matrix, *MIMICRY (Biology), *BIOMATERIALS

Abstract

Abstract Recent advances in materials development and tissue engineering has resulted in a substantial number of bioinspired materials that recapitulate cardinal features of bone extracellular matrix (ECM) such as dynamic inorganic and organic environment(s), hierarchical organization, and topographical features. Bone mimicking materials, as defined by its self-explanatory term, are developed based on the current understandings of the natural bone ECM during development, remodeling, and fracture repair. Compared to conventional plastic cultures, biomaterials that resemble some aspects of the native environment could elicit a more natural molecular and cellular response relevant to the bone tissue. Although current bioinspired materials are mainly developed to assist tissue repair or engineer bone tissues, such materials could nevertheless be applied to model various skeletal diseases in vitro. This review summarizes the use of bioinspired materials for bone tissue engineering, and their potential to model diseases of bone development and remodeling ex vivo. We largely focus on biomaterials, designed to re-create different aspects of the chemical and physical cues of native bone ECM. Employing these bone-inspired materials and tissue engineered bone surrogates to study bone diseases has tremendous potential and will provide a closer portrayal of disease progression and maintenance, both at the cellular and tissue level. We also briefly touch upon the application of patient-derived stem cells and introduce emerging technologies such as organ-on-chip in disease modeling. Faithful recapitulation of disease pathologies will not only offer novel insights into diseases, but also lead to enabling technologies for drug discovery and new approaches for cell-based therapies. [ABSTRACT FROM AUTHOR]

Published

2019

22. 3D biomaterial matrix to support long term, full thickness, immuno-competent human skin equivalents with nervous system components.

Author

Vidal, Sarah E. Lightfoot, Tamamoto, Kasey A., Nguyen, Hanh, Abbott, Rosalyn D., Cairns, Dana M., and Kaplan, David L.

Subjects

*COLLAGEN, *BIOMATERIALS, *THREE-dimensional imaging, *IMMUNOCOMPETENT cells, *DRUG development, *NEUROPHYSIOLOGY, *SKIN diseases

Abstract

Abstract Current commercially available human skin equivalents (HSEs) are used for relatively short term studies (∼1 week) due in part to the time-dependent contraction of the collagen gel-based matrix and the limited cell types and skin tissue components utilized. In contrast, here we describe a new matrix consisting of a silk-collagen composite system that provides long term, stable cultivation with reduced contraction and degradation over time. This matrix supports full thickness skin equivalents which include nerves. The unique silk-collagen composite system preserves cell-binding domains of collagen while maintaining the stability and mechanics of the skin system for long-term culture with silk. The utility of this new composite protein-based biomaterial was demonstrated by bioengineering full thickness human skin systems using primary cells, including nerves and immune cells to establish an HSE with a neuro-immuno-cutaneous system. The HSEs with neurons and hypodermis, compared to in vitro skin-only HSEs controls, demonstrated higher secretion of pro-inflammatory cytokines. Proteomics analysis confirmed the presence of several proteins associated with inflammation across all sample groups, but HSEs with neurons had the highest amount of detected protein due to the complexity of the model. This improved, in vitro full thickness HSE model system utilizes cross-linked silk-collagen as the biomaterial and allows reduced reliance on animal models and provides a new in vitro tissue system for the assessment of chronic responses related to skin diseases and drug discovery. [ABSTRACT FROM AUTHOR]

Published

2019

23. A new class of biological materials: Cell membrane-derived hydrogel scaffolds.

Author

Fan, Zhiyuan, Deng, Junjie, Li, Peter Y., Chery, Daphney R., Su, Yunfei, Zhu, Pu, Kambayashi, Taku, Blankenhorn, Elizabeth P., Han, Lin, and Cheng, Hao

Subjects

*BIOMATERIALS, *HYDROGELS, *TISSUE scaffolds, *BLOOD cells, *CELL membranes

Abstract

Abstract Biological materials are superior to synthetic biomaterials in biocompatibility and active interactions with cells. Here, a new class of biological materials, cell membrane-derived hydrogel scaffolds are reported for harnessing these advantages. To form macroporous scaffolds, vesicles derived from red blood cell membranes (RBCMs) are chemically crosslinked via cryogelation. The RBCM scaffolds with a pore size of around 70 μm are soft and injectable. Highly biocompatible scaffolds are typically made of superhydrophilic polymers and lack the ability to encapsulate and release hydrophobic drugs in a controlled manner. However, hydrophobic molecules can be efficiently encapsulated inside RBCM scaffolds and be sustainedly released. RBCM scaffolds show low neutrophil infiltration after subcutaneous injection in mice, and a significantly higher number of infiltrated macrophages than methacrylate alginate (MA-alginate) scaffolds. According to gene expression and surface markers, these macrophages have an M2-like phenotype, which is anti-inflammatory and immune suppressive. There are also higher percentages of macrophages presenting immunosuppressive PD-L1 in RBCM-scaffolds than in MA-alginate scaffolds. Interestingly, the concentrations of anti-inflammatory cytokine, IL-10 in both types of scaffolds are higher than those in normal organ tissues. This study sheds light on cell membrane-derived hydrogels, which can actively modulate cells in unique ways unavailable to existing hydrogel scaffolds. Graphical abstract Image 1 [ABSTRACT FROM AUTHOR]

Published

2019

24. Injectable mineralized microsphere-loaded composite hydrogels for bone repair in a sheep bone defect model.

Author

Ingavle, Ganesh C., Gionet-Gonzales, Marissa, Vorwald, Charlotte E., Bohannon, Laurie K., Clark, Kaitlin, Galuppo, Larry D., and Leach, J. Kent

Subjects

*MICROSPHERES, *HYDROGELS, *BONE abnormalities, *BIOMATERIALS, *BONE grafting

Abstract

Abstract The efficacy of cell-based therapies as an alternative to autologous bone grafts requires biomaterials to localize cells at the defect and drive osteogenic differentiation. Hydrogels are ideal cell delivery vehicles that can provide instructional cues via their composition or mechanical properties but commonly lack osteoconductive components that nucleate mineral. To address this challenge, we entrapped mesenchymal stromal cells (MSCs) in a composite hydrogel based on two naturally-derived polymers (alginate and hyaluronate) containing biomineralized polymeric microspheres. Mechanical properties of the hydrogels were dependent upon composition. The presentation of the adhesive tripeptide Arginine-Glycine-Aspartic Acid (RGD) from both polymers induced greater osteogenic differentiation of ovine MSCs in vitro compared to gels formed of RGD-alginate or RGD-alginate/hyaluronate alone. We then evaluated the capacity of this construct to stimulate bone healing when transplanting autologous, culture-expanded MSCs into a surgical induced, critical-sized ovine iliac crest bone defect. At 12 weeks post-implantation, defects treated with MSCs transplanted in composite gels exhibited significant increases in blood vessel density, osteoid formation, and bone formation compared to acellular gels or untreated defects. These findings demonstrate the capacity of osteoconductive hydrogels to promote bone formation with autologous MSCs in a large animal bone defect model and provide a promising vehicle for cell-based therapies of bone healing. [ABSTRACT FROM AUTHOR]

Published

2019

25. Role of nuclear mechanosensitivity in determining cellular responses to forces and biomaterials.

Author

Lee, Jung-Hwan, Kim, Dong-Hwee, Lee, Hae-Hyoung, and Kim, Hae-Won

Subjects

*BIOMATERIALS, *CELL physiology, *TISSUE engineering, *TRANSCRIPTION factors, *GENETIC transcription

Abstract

Abstract Tissue engineers use biomaterials or apply forces to alter cell behaviors and cure damaged/diseased tissues. The external physical cues perceived by cells are transduced intracellularly along the mechanosensitive machineries, including subcellular adhesion molecules and cytoskeletons. The signals are further channeled to a nucleus through the physical links of nucleoskeleton and cytoskeleton or the biochemical translocation of transcription factors. Thus, the external cues are thought to affect directly or indirectly the nucleus and the genetic transcriptional process, ultimately determining cell fate. Here we communicate the importance of such mechanotransductory processes in cell and tissue engineering where external forces- or biomaterials-related physical cues essentially regulate cellular behaviors, with an emphasis on the mechanosensing and signaling along the road to a nucleus. [ABSTRACT FROM AUTHOR]

Published

2019

26. Mussel-inspired injectable hydrogel and its counterpart for actuating proliferation and neuronal differentiation of retinal progenitor cells.

Author

Tang, Zhimin, Jiang, Fang, Zhang, Yuanhao, Zhang, Yi, YuanYang, Huang, Xiaolin, Wang, Yuyao, Zhang, Dandan, Ni, Ni, Liu, Feng, Luo, Min, Fan, Xianqun, Zhang, Weian, and Gu, Ping

Subjects

*HYDROGELS in medicine, *PROGENITOR cells, *CELL differentiation, *CELL proliferation, *BIOMATERIALS, *RETINAL degeneration treatment

Abstract

Abstract Biomaterials-mediated retinal progenitor cell (RPC)-based transplantation therapy has shown substantial potential for retinal degeneration (RD), but it is limited by the poor RPC survival, proliferation and differentiation. Herein, the gelatin-hyaluronic acid (Gel-HA)-based hydrogels formed via moderate Michael-type addition reaction with or without the introduction of mussel-inspired polydopamine (PDA), i.e. Gel-HA-PDA and its counterpart Gel-HA hydrogels are developed, and their effects on the biological behaviour of RPCs, including adhesion, survival, proliferation, differentiation, delivery and migration are investigated. The hybrid hydrogels can adopt the intricate structure of the retina with suitable mechanical strength, degradation rate and biological activity to support cellular adhesion, survival and delivery. Meanwhile, Gel-HA hydrogel can remarkably promote RPC proliferation with much larger cell clusters, while Gel-HA-PDA hydrogel significantly enhances RPC adhesion and migration, and directs RPCs to preferentially differentiate toward retinal neurons such as photoreceptors (the most crucial cell-type for RD treatment), which is mainly induced by the activation of integrin α5β1-phosphatidylinositol-3-kinase (PI3K) pathway. This study demonstrates that Gel-HA hydrogel possesses great potential for RPC proliferation, while mussel-inspired PDA-modified Gel-HA hydrogel with superior biocompatibility can significantly promote RPC neuronal differentiation, providing new insights for developing biomedical materials applied for RPC-based transplantation therapy. [ABSTRACT FROM AUTHOR]

Published

2019

27. A combined hiPSC-derived endothelial cell and in vitro microfluidic platform for assessing biomaterial-based angiogenesis.

Author

Natividad-Diaz, Sylvia L., Browne, Shane, Jha, Amit K., Ma, Zhen, Hossainy, Samir, Kurokawa, Yosuke K., George, Steven C., and Healy, Kevin E.

Subjects

*INDUCED pluripotent stem cells, *ENDOTHELIAL cells, *MICROFLUIDIC devices, *NEOVASCULARIZATION, *BIOMATERIALS, *CELL differentiation

Abstract

Abstract Human induced pluripotent stem cell (hiPSC) derived angiogenesis models present a unique opportunity for patient-specific platforms to study the complex process of angiogenesis and the endothelial cell response to biomaterial and biophysical changes in a defined microenvironment. We present a refined method for differentiating hiPSCs into a CD31 + endothelial cell population (hiPSC-ECs) using a single basal medium from pluripotency to the final stage of differentiation. This protocol produces endothelial cells that are functionally competent in assays following purification. Subsequently, an in vitro angiogenesis model was developed by encapsulating the hiPSC-ECs into a tunable, growth factor sequestering hyaluronic acid (HyA) matrix where they formed stable, capillary-like networks that responded to environmental stimuli. Perfusion of the networks was demonstrated using fluorescent beads in a microfluidic device designed to study angiogenesis. The combination of hiPSC-ECs, bioinspired hydrogel, and the microfluidic platform creates a unique testbed for rapidly assessing the performance of angiogenic biomaterials. [ABSTRACT FROM AUTHOR]

Published

2019

28. M cell targeting engineered biomaterials for effective vaccination.

Author

Islam, Mohammad Ariful, Firdous, Jannatul, Badruddoza, Abu Zayed Md, Reesor, Emma, Azad, Mohammad, Hasan, Anwarul, Lim, Michael, Cao, Wuji, Guillemette, Simon, and Cho, Chong Su

Subjects

*BIOMATERIALS, *VACCINE effectiveness, *DRUG delivery systems, *M cells

Abstract

Abstract Vaccines are one of the greatest medical interventions of all time and have been successful in controlling and eliminating a myriad of diseases over the past two centuries. Among several vaccination strategies, mucosal vaccines have wide clinical applications and attract considerable interest in research, showing potential as innovative and novel therapeutics. In mucosal vaccination, targeting (microfold) M cells is a frontline prerequisite for inducing effective antigen-specific immunostimulatory effects. In this review, we primarily focus on materials engineered for use as vaccine delivery platforms to target M cells. We also describe potential M cell targeting areas, methods to overcome current challenges and limitations of the field. Furthermore, we present the potential of biomaterials engineering as well as various natural and synthetic delivery technologies to overcome the challenges of M cell targeting, all of which are absent in current literature. Finally, we briefly discuss manufacturing and regulatory processes to bring a robust perspective on the feasibility and potential of this next-generation vaccine technology. [ABSTRACT FROM AUTHOR]

Published

2019

29. Molecular bionics – engineering biomaterials at the molecular level using biological principles.

Author

Rodríguez-Arco, Laura, Poma, Alessandro, Ruiz-Pérez, Lorena, Scarpa, Edoardo, Ngamkham, Kamolchanok, and Battaglia, Giuseppe

Subjects

*BIONICS, *BIOMATERIALS, *SUPRAMOLECULAR chemistry

Abstract

Abstract Life and biological units are the result of the supramolecular arrangement of many different types of molecules, all of them combined with exquisite precision to achieve specific functions. Taking inspiration from the design principles of nature allows engineering more efficient and compatible biomaterials. Indeed, bionic (from bion -, unit of life and - ic , like) materials have gained increasing attention in the last decades due to their ability to mimic some of the characteristics of nature systems, such as dynamism, selectivity, or signalling. However, there are still many challenges when it comes to their interaction with the human body, which hinder their further clinical development. Here we review some of the recent progress in the field of molecular bionics with the final aim of providing with design rules to ensure their stability in biological media as well as to engineer novel functionalities which enable navigating the human body. [ABSTRACT FROM AUTHOR]

Published

2019

30. Gene to diagnostic: Self immobilizing protein for silica microparticle biosensor, modelled with sarcosine oxidase.

Author

Henderson, Cassi J., Pumford, Elizabeth, Seevaratnam, Dushanth J., Daly, Ronan, and Hall, Elizabeth A.H.

Subjects

*BIOMATERIALS, *SILICA, *MICROENCAPSULATION, *HORSERADISH peroxidase, *PROTEIN analysis

Abstract

Abstract A rational design approach is proposed for a multifunctional enzyme reagent for point-of-care diagnostics. The biomaterial reduces downstream isolation steps and eliminates immobilization coupling chemicals for integration in a diagnostic platform. Fusion constructs combined the central functional assay protein (e.g. monomeric sarcosine oxidase, mSOx, horseradish peroxidase, HRP), a visualizing protein (e.g. mCherry) and an in-built immobilization peptide (e.g. R5). Monitoring protein expression in E.coli was facilitated by following the increase in mCherry fluorescence, which could be matched to a color card, indicating when good protein expression has occurred. The R5 peptide (SSKKSGSYSGSKGSKRRIL) provided inbuilt affinity for silica and an immobilization capability for a silica based diagnostic, without requiring additional chemical coupling reagents. Silica particles extracted from beach sand were used to collect protein from crude protein extract with 85–95% selective uptake. The silica immobilized R5 proteins were stable for more than 2 months at room temperature. The K m for the silica-R5 2 -mCh-mSOx-R5-6H was 16.5 ± 0.9 mM (compared with 16.5 ± 0.4 mM, 16.3 ± 0.3 mM, and 16.1 ± 0.4 mM for R5 2 -mCh-mSOx-R5-6H, mSOx-R5-6H and mSOx-6H respectively in solution). The use of the "silica-enzymes" in sarcosine and peroxide assays was shown, and a design using particle sedimentation through the sample was examined. Using shadowgraphy and particle image velocimetry the particle trajectory through the sample was mapped and an hourglass design with a narrow waist shown to give good control of particle position. The hourglass biosensor was demonstrated for sarcosine assay in the clinically useful range of 2.5–10 μM in both a dynamic and end point measurement regime. Graphical abstract Image 1 [ABSTRACT FROM AUTHOR]

Published

2019

31. Vascularized 3D printed scaffolds for promoting bone regeneration.

Author

Yan, Yufei, Chen, Hao, Zhang, Hongbo, Guo, Changjun, Yang, Kai, Chen, Kaizhe, Cheng, Ruoyu, Qian, Niandong, Sandler, Niklas, Zhang, Yu Shrike, Shen, Haokai, Qi, Jin, Cui, Wenguo, and Deng, Lianfu

Subjects

*TISSUE scaffolds, *TISSUE engineering, *BONE regeneration, *BIOMATERIALS, *BIOLOGICAL products

Abstract

Abstract 3D printed scaffolds hold promising perspective for bone tissue regeneration. Inspired by process of bone development stage, 3D printed scaffolds with rapid internal vascularization ability and robust osteoinduction bioactivity will be an ideal bone substitute for clinical use. Here, we fabricated a 3D printed biodegradable scaffold that can control release deferoxamine, via surface aminolysis and layer-by-layer assembly technique, which is essential for angiogenesis and osteogenesis and match to bone development and reconstruction. Our in vitro studies show that the scaffold significantly accelerates the vascular pattern formation of human umbilical endothelial cells, boosts the mineralized matrix production, and the expression of osteogenesis-related genes during osteogenic differentiation of mesenchymal stem cells. In vivo results show that deferoxamine promotes the vascular ingrowth and enhances the bone regeneration at the defect site in a rat large bone defect model. Moreover, this 3D-printed scaffold has excellent biocompatibility that is suitable for mesenchymal stem cells grow and differentiate and possess the appropriate mechanical property that is similar to natural cancellous bone. In summary, this 3D-printed scaffold holds huge potential for clinical translation in the treatment of segmental bone defect, due to its flexibility, economical friendly and practicality. [ABSTRACT FROM AUTHOR]

Published

2019

32. Guided tissue engineering for healing of cancellous and cortical bone using a combination of biomaterial based scaffolding and local bone active molecule delivery.

Author

Raina, Deepak Bushan, Qayoom, Irfan, Larsson, David, Zheng, Ming Hao, Kumar, Ashok, Isaksson, Hanna, Lidgren, Lars, and Tägil, Magnus

Subjects

*TISSUE engineering, *COMPACT bone, *BIOMATERIALS, *COLLAGEN, *BONE regeneration

Abstract

Abstract A metaphyseal bone defect due to infection, tumor or fracture leads to loss of cancellous and cortical bone. An animal model separating the cancellous and cortical healing was used with a combination of a macroporous gelatin-calcium sulphate-hydroxyapatite (Gel-CaS-HA) biomaterial as a cancellous defect filler, and a thin collagen membrane (CM) guiding cortical bone regeneration. The membrane was immobilized with bone morphogenic protein-2 (rhBMP-2) to enhance the osteoinductive properties. The Gel-CaS-HA cancellous defect filler contained both rhBMP-2 and a bisphosphonate, (zoledronate = ZA) to prevent premature callus resorption induced by the pro-osteoclast effect of rhBMP-2 alone. In the first part of the study, the CM delivering both rhBMP-2 and ZA was tested in a muscle pouch model in rats and the co-delivery of rhBMP-2 and ZA via the CM resulted in higher amounts of bone compared to rhBMP-2 alone. Secondly, an established tibia defect model in rats was used to study cortical and cancellous bone regeneration. The defect was left empty, filled with Gel-CaS-HA alone, Gel-CaS-HA immobilized with ZA or Gel-CaS-HA immobilized with rhBMP-2+ZA. Functionalization of the Gel-CaS-HA scaffold with bioactive molecules produced significantly more bone in the cancellous defect and its surroundings but cortical defect healing was delayed likely due to the protrusion of the Gel-CaS-HA into the cortical bone. To guide cortical regeneration, the cortical defect was sealed endosteally by a CM with or without rhBMP-2. Subsequently, the cancellous defect was filled with Gel-CaS-HA containing ZA and rhBMP-2+ZA. In the groups where the CM was doped with rhBMP-2, significantly higher number of cortices bridged. The approach to guide cancellous as well as cortical bone regeneration separately in a metaphyseal defect using two bioactive molecule immobilized biomaterials is promising and could improve the clinical care of patients with metaphyseal defects. [ABSTRACT FROM AUTHOR]

Published

2019

33. Beyond RGD; nanoclusters of syndecan- and integrin-binding ligands synergistically enhance cell/material interactions.

Author

Karimi, Fatemeh, Thombare, Varsha Jagannath, Hutton, Craig A., O'Connor, Andrea J., Qiao, Greg G., and Heath, Daniel E.

Subjects

*BIOMATERIALS, *BIOMIMETIC chemicals, *BIOMIMETIC polymers, *LIGANDS (Chemistry), *ENDOTHELIAL cells

Abstract

Abstract Biomaterials are a powerful platform for directing cellular behaviour. Herein, we employed a biomimetic strategy to synthesize a low-fouling polymer functionalized with nano-scale clusters of ligands that bind both integrin and syndecan-4 receptors, as both receptor types are critical in focal adhesion signalling and mechanotransduction. Our results demonstrate that the presence of both ligand types synergistically increases the adhesion of human umbilical vein endothelial cells (more than a two fold increase after 4 h) and increases the rate of surface endothelialization compared to surfaces functionalized with only one ligand type. Additionally, we observe that the mixed population of ligands regulates endothelial cell migration, likely due to improved focal adhesion formation as observed through confocal microscopy. Furthermore, we illustrate that only endothelial cells cultured on these mixed ligand surfaces exhibit the appropriate morphological changes – elongation and alignment in the direction of flow - when exposed to laminar shear flow, and neither of the individual ligands alone is sufficient. These results illustrate that both receptor types must be engaged for optimum cell-material interactions and are mandatory for appropriate mechanotransduction. The results presented in this manuscript will be critical for the development of next generation biomedical devices and tissue engineering scaffolds. Graphical abstract Image 1 [ABSTRACT FROM AUTHOR]

Published

2018

34. Bone physiology as inspiration for tissue regenerative therapies.

Author

Lopes, Diana, Martins-Cruz, Cláudia, Oliveira, Mariana B., and Mano, João F.

Subjects

*BONE physiology, *BONE regeneration, *BIOMIMETIC chemicals, *EXTRACELLULAR matrix, *BIOMATERIALS

Abstract

Abstract The development, maintenance of healthy bone and regeneration of injured tissue in the human body comprise a set of intricate and finely coordinated processes. However, an analysis of current bone regeneration strategies shows that only a small fraction of well-reported bone biology aspects has been used as inspiration and transposed into the development of therapeutic products. Specific topics that include inter-scale bone structural organization, developmental aspects of bone morphogenesis, bone repair mechanisms, role of specific cells and heterotypic cell contact in the bone niche (including vascularization networks and immune system cells), cell-cell direct and soluble-mediated contact, extracellular matrix composition (with particular focus on the non-soluble fraction of proteins), as well as mechanical aspects of native bone will be the main reviewed topics. In this Review we suggest a systematic parallelization of (i) fundamental well-established biology of bone, (ii) updated and recent advances on the understanding of biological phenomena occurring in native and injured tissue, and (iii) critical discussion of how those individual aspects have been translated into tissue regeneration strategies using biomaterials and other tissue engineering approaches. We aim at presenting a perspective on unexplored aspects of bone physiology and how they could be translated into innovative regeneration-driven concepts. [ABSTRACT FROM AUTHOR]

Published

2018

35. A supramolecular polymer-collagen microparticle slurry for bone regeneration with minimal growth factor.

Author

McClendon, Mark T., Ji, Wei, Greene, Allison C., Sai, Hiroaki, Sangji, M. Hussain, Sather, Nicholas A., Chen, Charlotte H., Lee, Sungsoo S., Katchko, Karina, Jeong, Soyeon Sophia, Kannan, Abhishek, Weiner, Joseph, Cook, Ralph, Driscoll, Adam, Lubbe, Ryan, Chang, Kevin, Haleem, Meraaj, Chen, Feng, Qiu, Ruomeng, and Chun, Danielle

Subjects

*BONE regeneration, *BIOMATERIALS, *COLLAGEN, *SLURRY, *MINIMALLY invasive procedures, *BONE growth, *SPINAL fusion

Abstract

Recombinant bone morphogenetic protein-2 (BMP-2) is a potent osteoinductive growth factor that can promote bone regeneration for challenging skeletal repair and even for ectopic bone formation in spinal fusion procedures. However, serious clinical side effects related to supraphysiological dosing highlight the need for advances in novel biomaterials that can significantly reduce the amount of this biologic. Novel biomaterials could not only reduce clinical side effects but also expand the indications for use of BMP-2, while at the same time lowering the cost of such procedures. To achieve this objective, we have developed a slurry containing a known supramolecular polymer that potentiates BMP-2 signaling and porous collagen microparticles. This slurry exhibits a paste-like consistency that stiffens into an elastic gel upon implantation making it ideal for minimally invasive procedures. We carried out in vivo evaluation of the novel biomaterial in the rabbit posterolateral spine fusion model, and discovered efficacy at unprecedented ultra-low BMP-2 doses (5 μg/implant). This dose reduces the growth factor requirement by more than 100-fold relative to current clinical products. This observation is significant given that spinal fusion involves ectopic bone formation and the rabbit model is known to be predictive of human efficacy. We expect the novel biomaterial can expand BMP-2 indications for difficult cases requiring large volumes of bone formation or involving patients with underlying conditions that compromise bone regeneration. [ABSTRACT FROM AUTHOR]

Published

2023

36. Corrigendum to "PEGylated fullerene/iron oxide nanocomposites for photodynamic therapy, targeted drug delivery and MR imaging" [Biomaterials 34 (2013) 9666–9677/ pubmed: 24034498].

Author

Shi, Jinjin, Yu, Xiaoyuan, Wang, Lei, Liu, Yan, Gao, Jun, Zhang, Jing, Ma, Rou, Liu, Ruiyuan, and Zhang, Zhenzhong

Subjects

*FERRIC oxide, *MAGNETIC resonance imaging, *PHOTODYNAMIC therapy, *BIOMATERIALS, *NANOCOMPOSITE materials, *FULLERENES, *IRON oxides, *IRON oxide nanoparticles

Published

2023

37. Translational tissue-engineered vascular grafts: From bench to bedside.

Author

West-Livingston, Lauren, Lim, Jae Woong, and Lee, Sang Jin

Subjects

*VASCULAR grafts, *BIOPRINTING, *METAL scaffolding, *MATERIALS science, *BLOOD vessels

Abstract

Cardiovascular disease is a primary cause of mortality worldwide, and patients often require bypass surgery that utilizes autologous vessels as conduits. However, the limited availability of suitable vessels and the risk of failure and complications have driven the need for alternative solutions. Tissue-engineered vascular grafts (TEVGs) offer a promising solution to these challenges. TEVGs are artificial vascular grafts made of biomaterials and/or vascular cells that can mimic the structure and function of natural blood vessels. The ideal TEVG should possess biocompatibility, biomechanical mechanical properties, and durability for long-term success in vivo. Achieving these characteristics requires a multi-disciplinary approach involving material science, engineering, biology, and clinical translation. Recent advancements in scaffold fabrication have led to the development of TEVGs with improved functional and biomechanical properties. Innovative techniques such as electrospinning, 3D bioprinting, and multi-part microfluidic channel systems have allowed the creation of intricate and customized tubular scaffolds. Nevertheless, multiple obstacles must be overcome to apply these innovations effectively in clinical practice, including the need for standardized preclinical models and cost-effective and scalable manufacturing methods. This review highlights the fundamental approaches required to successfully fabricate functional vascular grafts and the necessary translational methodologies to advance their use in clinical practice. [ABSTRACT FROM AUTHOR]

Published

2023

38. Crossover of surface waves and capillary-viscous-elastic transition in soft biomaterials detected by resonant acoustic rheometry.

Author

Hobson, Eric C., Li, Weiping, Friend, Nicole E., Putnam, Andrew J., Stegemann, Jan P., and Deng, Cheri X.

Subjects

*FIBRIN, *RESONANT ultrasound spectroscopy, *BIOMATERIALS, *GELATION, *CROSSLINKING (Polymerization), *PHASE transitions, *POLYMERIZATION kinetics, *SURFACE tension measurement

Abstract

Viscoelastic properties of hydrogels are important for their application in science and industry. However, rheological assessment of soft hydrogel biomaterials is challenging due to their complex, rapid, and often time-dependent behaviors. Resonant acoustic rheometry (RAR) is a newly developed technique capable of inducing and measuring resonant surface waves in samples in a non-contact fashion. By applying RAR at high temporal resolution during thrombin-induced fibrin gelation and ultraviolet-initiated polyethylene glycol (PEG) polymerization, we observed distinct changes in both frequency and amplitude of the resonant surface waves as the materials changed over time. RAR detected a series of capillary-elastic, capillary-viscous, and visco-elastic transitions that are uniquely manifested as crossover of different types of surface waves in the temporally evolving materials. These results reveal the dynamic interplay of surface tension, viscosity, and elasticity that is controlled by the kinetics of polymerization and crosslinking during hydrogel formation. RAR overcomes many limitations of conventional rheological approaches by offering a new way to comprehensively and longitudinally characterize soft materials during dynamic processes. • RAR captures in real time the liquid-to-solid transition during fibrin and PEG gelation • Competing influences of surface tension, viscosity, and elasticity of hydrogels results in crossover of different surface wave regimes • Capillary-viscous-elastic transition in temporally changing hydrogels depends on the rates of polymerization and crosslinking • RAR provides a new non-contact approach for rapid measurements of surface tension and viscoelasticity of soft materials simultaneously [ABSTRACT FROM AUTHOR]

Published

2023

39. Succinate in the tumor microenvironment affects tumor growth and modulates tumor associated macrophages.

Author

Inamdar, Sahil, Suresh, Abhirami P., Mangal, Joslyn L., Ng, Nathan D., Sundem, Alison, Behbahani, Hoda Shokrollahzadeh, Rubino, Thomas E., Yaron, Jordan R., Khodaei, Taravat, Green, Matthew, Curtis, Marion, and Acharya, Abhinav P.

Subjects

*TUMOR growth, *TUMOR microenvironment, *MACROPHAGES, *TYPE I interferons, *CANCER cells, *BIOMATERIALS, *BRAF genes

Abstract

Succinate is an important metabolite that modulates metabolism of immune cells and cancer cells in the tumor microenvironment (TME). Herein, we report that polyethylene succinate (PES) microparticles (MPs) biomaterial mediated controlled delivery of succinate in the TME modulates macrophage responses. Administering PES MPs locally with or without a BRAF inhibitor systemically in an immune-defective aging mice with clinically relevant BRAFV600E mutated YUMM1.1 melanoma decreased tumor volume three-fold. PES MPs in the TME also led to maintenance of M1 macrophages with up-regulation of TSLP and type 1 interferon pathway. Impressively, this led to generation of pro-inflammatory adaptive immune responses in the form of increased T helper type 1 and T helper type 17 cells in the TME. Overall, our findings from this challenging tumor model suggest that immunometabolism-modifying PES MP strategies provide an approach for developing robust cancer immunotherapies. [ABSTRACT FROM AUTHOR]

Published

2023

40. Regenerative bioelectronics: A strategic roadmap for precision medicine.

Author

Panda, Asish Kumar and Basu, Bikramjit

Subjects

*BIOELECTRONICS, *REGENERATION (Biology), *INDIVIDUALIZED medicine, *CYTOLOGY, *STEM cell treatment, *DEGENERATION (Pathology)

Abstract

In the past few decades, stem cell-based regenerative engineering has demonstrated its significant potential to repair damaged tissues and to restore their functionalities. Despite such advancement in regenerative engineering, the clinical translation remains a major challenge. In the stance of personalized treatment, the recent progress in bioelectronic medicine likewise evolved as another important research domain of larger significance for human healthcare. Over the last several years, our research group has adopted biomaterials-based regenerative engineering strategies using innovative bioelectronic stimulation protocols based on either electric or magnetic stimuli to direct cellular differentiation on engineered biomaterials with a range of elastic stiffness or functional properties (electroactivity/magnetoactivity). In this article, the role of bioelectronics in stem cell-based regenerative engineering has been critically analyzed to stimulate futuristic research in the treatment of degenerative diseases as well as to address some fundamental questions in stem cell biology. Built on the concepts from two independent biomedical research domains (regenerative engineering and bioelectronic medicine), we propose a converging research theme, 'Regenerative Bioelectronics'. Further, a series of recommendations have been put forward to address the current challenges in bridging the gap in stem cell therapy and bioelectronic medicine. Enacting the strategic blueprint of bioelectronic-based regenerative engineering can potentially deliver the unmet clinical needs for treating incurable degenerative diseases. [ABSTRACT FROM AUTHOR]

Published

2023

41. Organic functional substance engineered living materials for biomedical applications.

Author

Wang, Tongtong, Wu, Min, Cao, Lei, and Liu, Bin

Subjects

*BIOMEDICAL materials, *WOUND healing, *SMALL molecules, *HEALING, *BIOCOMPATIBILITY, *ENGINEERING, *ORGANIC semiconductors

Abstract

Modifying living materials with organic functional substances (OFS) is a convenient and effective strategy to control and monitor the transport, engraftment, and secretion processes in living organisms. OFSs, including small organic molecules and organic polymers, own the merit of design flexibility, satisfying performance, and excellent biocompatibility, which allow for living materials functionalization to realize real-time sensing, controlled drug release, enhanced biocompatibility, accurate diagnosis, and precise treatment. In this review, we discuss the different principles of OFS modification on living materials and demonstrate the applications of engineered living materials in health monitoring, drug delivery, wound healing, and tissue regeneration. [ABSTRACT FROM AUTHOR]

Published

2023

42. Biomaterial based implants caused remote liver fatty deposition through activated blood-derived macrophages.

Author

Peng, Zhi, Xie, Chang, Jin, Shucheng, Hu, Jiajie, Yao, Xudong, Ye, Jinchun, Zhang, Xianzhu, Lim, Jia Xuan, Wu, Bingbing, Wu, Haoyu, Liang, Renjie, Wen, Ya, Huang, Jiahui, Zou, Xiaohui, and Ouyang, Hongwei

Subjects

*FATTY liver, *LIPID metabolism disorders, *BIOMATERIALS, *HERNIA surgery, *SILK fibroin, *MACROPHAGES

Abstract

Understanding the biocompatibility of biomaterials is a prerequisite for the prediction of its clinical application, and the present assessments mainly rely on in vitro cell culture and in situ histopathology. However, remote organs responses after biomaterials implantation is unclear. Here, by leveraging body-wide-transcriptomics data, we performed in-depth systems analysis of biomaterials – remote organs crosstalk after abdominal implantation of polypropylene and silk fibroin using a rodent model, demonstrating local implantation caused remote organs responses dominated by acute-phase responses, immune system responses and lipid metabolism disorders. Of note, liver function was specially disturbed, defined as hepatic lipid deposition. Combining flow cytometry analyses and liver monocyte recruitment inhibition experiments, we proved that blood derived monocyte-derived macrophages in the liver underlying the mechanism of abnormal lipid deposition induced by local biomaterials implantation. Moreover, from the perspective of temporality, the remote organs responses and liver lipid deposition of silk fibroin group faded away with biomaterial degradation and restored to normal at end, which highlighted its superiority of degradability. These findings were further indirectly evidenced by human blood biochemical ALT and AST examination from 141 clinical cases of hernia repair using silk fibroin mesh and polypropylene mesh. In conclusion, this study provided new insights on the crosstalk between local biomaterial implants and remote organs, which is of help for future selecting and evaluating biomaterial implants with the consideration of whole-body response. [ABSTRACT FROM AUTHOR]

Published

2023

43. Corrigendum to A hypochlorite-activated strategy for realizing fluorescence turn-on, type I and type II ROS-combined photodynamic tumor ablation Biomaterials Volume 297, 122108, (2023).

Author

Huang, Tonghui, Ji, Heng, Yan, Shirong, Zuo, Yifan, Li, Jie, Lam, Jacky W.Y., Han, Cuiping, and Tang, Ben Zhong

Subjects

*FLUORESCENCE, *TUMORS, *BIOMATERIALS

Published

2023

44. Corrigendum to Affordable oral proinsulin bioencapsulated in plant cells regulates blood sugar levels similar to natural insulin. Biomaterials 298, 122142, (2023).

Author

Daniell, Henry, Singh, Rahul, Mangu, Venkata, Nair, Smruti K., Wakade, Geetanjali, and Balashova, Nataliya

Subjects

*BLOOD cells, *PROINSULIN, *BIOMATERIALS, *PLANT cell culture, *INSULIN

Published

2023

45. Self-assembled block copolymer biomaterials for oral delivery of protein therapeutics.

Author

Chapa-Villarreal, Fabiola A., Miller, Matthew, Rodriguez-Cruz, J Jesus, Pérez-Carlos, Diego, and Peppas, Nicholas A.

Subjects

*BLOCK copolymers, *BIOMATERIALS, *PATIENT compliance, *DRUG carriers, *THERAPEUTICS, *TREATMENT effectiveness, *COPOLYMERS

Abstract

Protein therapeutics have guided a transformation in disease treatment for various clinical conditions. They have been successful in numerous applications, but administration of protein therapeutics has been limited to parenteral routes which can decrease patient compliance as they are invasive and painful. In recent years, the synergistic relationship of novel biomaterials with modern protein therapeutics has been crucial in the treatment of diseases that were once thought of as incurable. This has guided the development of a variety of alternative administration routes, but the oral delivery of therapeutics remains one of the most desirable due to its ease of administration. This review addresses important aspects of micellar structures prepared by self-assembled processes with applications for oral delivery. These two characteristics have not been placed together in previous literature within the field. Therefore, we describe the barriers for delivery of protein therapeutics, and we concentrate in the oral/transmucosal pathway where drug carriers must overcome several chemical, physical, and biological barriers to achieve a successful therapeutic effect. We critically discuss recent research on biomaterials systems for delivering such therapeutics with an emphasis on self-assembled synthetic block copolymers. Polymerization methods and nanoparticle preparation techniques are similarly analyzed as well as relevant work in this area. Based on our own and others' research, we analyze the use of block copolymers as therapeutic carriers and their promise in treating a variety of diseases, with emphasis on self-assembled micelles for the next generation of oral protein therapeutic systems. [ABSTRACT FROM AUTHOR]

Published

2023

46. Orally delivered 2D covalent organic frameworks releasing kynurenine generate anti-inflammatory T cell responses in collagen induced arthritis mouse model.

Author

Mohan Chandra Sekhar Jaggarapu, Madhan, Thumsi, Abhirami, Nile, Richard, D Ridenour, Brian, Khodaei, Taravat, P Suresh, Abhirami, Esrafili, Arezoo, Jin, Kailong, and P Acharya, Abhinav

Subjects

*KYNURENINE, *LABORATORY mice, *ANIMAL disease models, *T cells, *SMALL molecules, *COLLAGEN-induced arthritis, *BIOMATERIALS

Abstract

Covalent organic framework (COF) crystalline biomaterials have great potential for drug delivery since they can load large amounts of small molecules (e.g. metabolites) and release them in a controlled manner, as compared to their amorphous counterparts. Herein, we screened different metabolites for their ability to modulate T cell responses in vitro and identified Kynurenine (KyH) as a key metabolite that not only decreases frequency of pro-inflammatory RORgt + T cells but also supports frequency of anti-inflammatory GATA3+ T cells. Moreover, we developed a methodology to generate imine-based TAPB-PDA COF at room temperature and loaded these COFs with KyH. KyH loaded COFs (COF-KyH) were able to then release KyH in a controlled manner for 5 days in vitro. Notably, COF-KyH when delivered orally in mice induced with collagen-induced rheumatoid arthritis (CIA) were able to increase frequency of anti-inflammatory GATA3+CD8+ T cells in the lymph nodes and decrease antibody titers in the serum as compared to the controls. Overall, these data demonstrate that COFs can be an excellent drug delivery vehicle for delivering immune modulating small molecule metabolites. [ABSTRACT FROM AUTHOR]

Published

2023

47. Biomaterials for reliable wearable health monitoring: Applications in skin and eye integration.

Author

Hong, Seokkyoon, Yu, Tianhao, Wang, Ziheng, and Lee, Chi Hwan

Subjects

*WEARABLE technology, *HYBRID materials, *EARLY diagnosis, *CLINICAL medicine, *HYDROGELS

Abstract

Recent advancements in biomaterials have significantly impacted wearable health monitoring, creating opportunities for personalized and non-invasive health assessments. These developments address the growing demand for customized healthcare solutions. Durability is a critical factor for biomaterials in wearable applications, as they must withstand diverse wearing conditions effectively. Therefore, there is a heightened focus on developing biomaterials that maintain robust and stable functionalities, essential for advancing wearable sensing technologies. This review examines the biomaterials used in wearable sensors, specifically those interfaced with human skin and eyes, highlighting essential strategies for achieving long-lasting and stable performance. We specifically discuss three main categories of biomaterials—hydrogels, fibers, and hybrid materials—each offering distinct properties ideal for use in durable wearable health monitoring systems. Moreover, we delve into the latest advancements in biomaterial-based sensors, which hold the potential to facilitate early disease detection, preventative interventions, and tailored healthcare approaches. We also address ongoing challenges and suggest future directions for research on material-based wearable sensors to encourage continuous innovation in this dynamic field. This review paper focuses on recent advancements in biomaterials, including hydrogels, fibers, and hybrid materials, with an emphasis on durability for skin- or eye-interfaced health monitoring applications. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2025

48. Macrophage microRNA-146a is a central regulator of the foreign body response to biomaterial implants.

Author

Mahanty, Manisha, Dutta, Bidisha, Ou, Wenquan, Zhu, Xiaoping, Bromberg, Jonathan S., He, Xiaoming, and Rahaman, Shaik O.

Subjects

*ATOMIC force microscopy, *FOREIGN bodies, *DRUG target, *BIOMATERIALS, *MACROPHAGES

Abstract

Host recognition and immune-mediated foreign body response (FBR) to biomaterials can adversely affect the functionality of implanted materials. FBR presents a complex bioengineering and medical challenge due to the lack of current treatments, making the detailed exploration of its molecular mechanisms crucial for developing new and effective therapies. To identify key molecular targets underlying the generation of FBR, here we perform analysis of microRNAs (miR) and mRNAs responses to implanted biomaterials. We found that (a) miR-146a levels inversely affect macrophage accumulation, foreign body giant cell (FBGC) formation, and fibrosis in a murine implant model; (b) macrophage-derived miR-146a is a crucial regulator of the FBR and FBGC formation, as confirmed by global and cell-specific knockout of miR-146a; (c) miR-146a modulates genes related to inflammation, fibrosis, and mechanosensing; (d) miR-146a modulates tissue stiffness near the implant during FBR as assessed by atomic force microscopy; and (e) miR-146a is linked to F-actin production and cellular traction force induction as determined by traction force microscopy, which are vital for FBGC formation. These novel findings suggest that targeting macrophage miR-146a could be a selective strategy to inhibit FBR, potentially improving the biocompatibility of biomaterials. [ABSTRACT FROM AUTHOR]

Published

2025

49. Retraction notice to "Synergistic anticancer effect of RNAi and photothermal therapy mediated by functionalized single-walled carbon nanotubes" [Biomaterials 34/1 (2013) 14383].

Author

Wang, Lei, Shi, Jinjin, Zhang, Hongling, Li, Haixia, Gao, Yan, Wang, Zhenzhen, Wang, Honghong, Li, Lulu, Zhang, Chaofeng, Chen, Chengqun, Zhang, Zhenzhong, and Zhang, Yun

Subjects

*PHOTOTHERMAL effect, *ANTINEOPLASTIC agents, *BIOMATERIALS

Published

2025

50. Corrigendum to "Tumor microenvironment immunomodulation by nanoformulated TLR 7/8 agonist and PI3k delta inhibitor enhances therapeutic benefits of radiotherapy" [Biomaterials 312 (2025) 122750.

Author

Yazdimamaghani, Mostafa, Kolupaev, Oleg V., Lim, Chaemin, Hwang, Duhyeong, Laurie, Sonia J., Perou, Charles M., Kabanov, Alexander V., and Serody, Jonathan S.

Subjects

*TOLL-like receptor agonists, *TUMOR microenvironment, *PHOSPHATIDYLINOSITOL 3-kinases, *IMMUNOREGULATION, *BIOMATERIALS

Published

2025