Advances in bioinks and in vivo imaging of biomaterials for CNS applications.

Due to increasing life expectancy incidence of neurological disorders is rapidly rising, thus adding urgency to develop effective strategies for treatment. Stem cell-based therapies were considered highly promising and while progress in this field is evident, outcomes of clinical trials are rather disappointing. Suboptimal engraftment, poor cell survival and uncontrolled differentiation may be the reasons behind dismal results. Clearly, new direction is needed and we postulate that with recent progress in biomaterials and bioprinting, regenerative approaches for neurological applications may be finally successful. The use of biomaterials aids engraftment of stem cells, protects them from harmful microenvironment and importantly, it facilitates the incorporation of cell-supporting molecules. The biomaterials used in bioprinting (the bioinks) form a scaffold for embedding the cells/biomolecules of interest, but also could be exploited as a source of endogenous contrast or supplemented with contrast agents for imaging. Additionally, bioprinting enables patient-specific customization with shape/size tailored for actual needs. In stroke or traumatic brain injury for example lesions are localized and focal, and usually progress with significant loss of tissue volume creating space that could be filled with artificial tissue using bioprinting modalities. The value of imaging for bioprinting technology is advantageous on many levels including design of custom shapes scaffolds based on anatomical 3D scans, assessment of performance and integration after scaffold implantation, or to learn about the degradation over time. In this review, we focus on bioprinting technology describing different printing techniques and properties of biomaterials in the context of requirements for neurological applications. We also discuss the need for in vivo imaging of implanted materials and tissue constructs reviewing applicable imaging modalities and type of information they can provide. STATEMENT OF SIGNIFICANCE: Current stem cell-based regenerative strategies for neurological diseases are ineffective due to inaccurate engraftment, low cell viability and suboptimal differentiation. Bioprinting and embedding stem cells within biomaterials at high precision, including building complex multi-material and multi-cell type composites may bring a breakthrough in this field. We provide here comprehensive review of bioinks, bioprinting techniques applicable to application for neurological disorders. Appreciating importance of longitudinal monitoring of implanted scaffolds, we discuss advantages of various imaging modalities available and suitable for imaging biomaterials in the central nervous system. Our goal is to inspire new experimental approaches combining imaging, biomaterials/bioinks, advanced manufacturing and tissue engineering approaches, and stimulate interest in image-guided therapies based on bioprinting.

[1]  A. Abdanipour,et al.  Intraspinal transplantation of motoneuron-like cell combined with delivery of polymer-based glial cell line-derived neurotrophic factor for repair of spinal cord contusion injury , 2014, Neural regeneration research.

[2]  D. Cram,et al.  Mesenchymal Stem Cells for Treatment of CNS Injury , 2010, Current neuropharmacology.

[3]  Xiaoyou Ying,et al.  Assessment of in vivo degradation profiles of hyaluronic acid hydrogels using temporal evolution of chemical exchange saturation transfer (CEST) MRI. , 2018, Biomaterials.

[4]  F. Otero-Espinar,et al.  Positron Emission Tomography for the Development and Characterization of Corneal Permanence of Ophthalmic Pharmaceutical Formulations. , 2017, Investigative ophthalmology & visual science.

[5]  A. Fallah,et al.  Iranian Journal of Basic Medical Sciences Comparison of Human Adipose-derived Stem Cells and Chondroitinase Abc Transplantation on Locomotor Recovery in the Contusion Model of Spinal Cord Injury in Rats , 2022 .

[6]  Mi-Hee Kim,et al.  Biocompatible reduced graphene oxide prepared by using dextran as a multifunctional reducing agent. , 2011, Chemical communications.

[7]  Ibrahim T. Ozbolat,et al.  Bioprinting scale-up tissue and organ constructs for transplantation. , 2015, Trends in biotechnology.

[8]  Nirali Vora,et al.  The global burden of neurologic diseases , 2014, Neurology.

[9]  Study protocol of the TIRED study: a randomised controlled trial comparing either graded exercise therapy for severe fatigue or cognitive behaviour therapy with usual care in patients with incurable cancer , 2017, BMC Cancer.

[10]  Jiangyang Zhang,et al.  Transplanted human glial-restricted progenitors can rescue the survival of dysmyelinated mice independent of the production of mature, compact myelin , 2017, Experimental Neurology.

[11]  K. Kinzler,et al.  A diaCEST MRI approach for monitoring liposomal accumulation in tumors. , 2014, Journal of controlled release : official journal of the Controlled Release Society.

[12]  Shan-hui Hsu,et al.  3D bioprinting: A new insight into the therapeutic strategy of neural tissue regeneration , 2015, Organogenesis.

[13]  Lihong V. Wang,et al.  Photoacoustic Tomography: In Vivo Imaging from Organelles to Organs , 2012, Science.

[14]  Y. S. Zhang,et al.  Imaging Biomaterial-Tissue Interactions. , 2017, Trends in biotechnology.

[15]  Charles Tator,et al.  Bioengineered strategies for spinal cord repair. , 2006, Journal of neurotrauma.

[16]  Seung Yun Nam,et al.  Evaluation of gold nanotracers to track adipose-derived stem cells in a PEGylated fibrin gel for dermal tissue engineering applications , 2013, International journal of nanomedicine.

[17]  M A Rupnick,et al.  Three Dimensional OCT in the Engineering of Tissue Constructs: A Potentially Powerful Tool for Assessing Optimal Scaffold Structure. , 2009, The open tissue engineering and regenerative medicine journal.

[18]  A. Urtti,et al.  Technetium-99m-labeled nanofibrillar cellulose hydrogel for in vivo drug release. , 2014, European journal of pharmaceutical sciences : official journal of the European Federation for Pharmaceutical Sciences.

[19]  Cheri X Deng,et al.  Microscale characterization of the viscoelastic properties of hydrogel biomaterials using dual-mode ultrasound elastography. , 2016, Biomaterials.

[20]  J. Hilborn,et al.  Injectable hyaluronic acid hydrogels with the capacity for magnetic resonance imaging. , 2018, Carbohydrate polymers.

[21]  G. Bormans,et al.  A PET Brain Reporter Gene System Based on Type 2 Cannabinoid Receptors , 2011, The Journal of Nuclear Medicine.

[22]  P. Walczak,et al.  MRI-guided intrathecal transplantation of hydrogel-embedded glial progenitors in large animals , 2018, Scientific Reports.

[23]  LeeSe-Jun,et al.  Fabrication of a Highly Aligned Neural Scaffold via a Table Top Stereolithography 3D Printing and Electrospinning . , 2016 .

[24]  Jurgen Seidel,et al.  Noninvasive quantification and optimization of acute cell retention by in vivo positron emission tomography after intramyocardial cardiac-derived stem cell delivery. , 2009, Journal of the American College of Cardiology.

[25]  J. Bulte,et al.  Human glial‐restricted progenitors survive, proliferate, and preserve electrophysiological function in rats with focal inflammatory spinal cord demyelination , 2011, Glia.

[26]  Ibrahim T. Ozbolat,et al.  The bioink: A comprehensive review on bioprintable materials. , 2017, Biotechnology advances.

[27]  Anthony Tabet,et al.  Quantitative criteria to benchmark new and existing bio-inks for cell compatibility , 2017, Biofabrication.

[28]  Joon Hyung Park,et al.  Three-dimensional printing of complex biological structures by freeform reversible embedding of suspended hydrogels , 2015, Science Advances.

[29]  M. McMahon,et al.  Porous tantalum and tantalum oxide nanoparticles for regenerative medicine. , 2014, Acta neurobiologiae experimentalis.

[30]  J. Bulte,et al.  The survival of engrafted neural stem cells within hyaluronic acid hydrogels. , 2013, Biomaterials.

[31]  A. Salgado,et al.  Modulation of bone marrow mesenchymal stem cell secretome by ECM-like hydrogels. , 2013, Biochimie.

[32]  Ayesha Al-Sabah,et al.  Skin tissue engineering using 3D bioprinting: An evolving research field. , 2018, Journal of plastic, reconstructive & aesthetic surgery : JPRAS.

[33]  M. Shoichet,et al.  Regenerative Therapies for Central Nervous System Diseases: a Biomaterials Approach , 2014, Neuropsychopharmacology.

[34]  Mark A Anastasio,et al.  X-ray imaging of poly(ethylene glycol) hydrogels without contrast agents. , 2010, Tissue engineering. Part C, Methods.

[35]  J. Hilborn,et al.  Injectable in situ forming hybrid iron oxide-hyaluronic acid hydrogel for magnetic resonance imaging and drug delivery. , 2014, Macromolecular bioscience.

[36]  Seung Yun Nam,et al.  Imaging strategies for tissue engineering applications. , 2015, Tissue engineering. Part B, Reviews.

[37]  L. Hanna,et al.  The Use of a Pressure-Indicating Sensor Film to Provide Feedback upon Hydrogel-Forming Microneedle Array Self-Application In Vivo , 2016, Pharmaceutical Research.

[38]  Yong-Eun Koo Lee,et al.  Polymer-Protein Hydrogel Nanomatrix for Stabilization of Indocyanine Green towards Targeted Fluorescence and Photoacoustic Bio-imaging. , 2013, Journal of materials chemistry. B.

[39]  Ritu Raman,et al.  3D printing enables separation of orthogonal functions within a hydrogel particle , 2016, Biomedical Microdevices.

[40]  Stephanie M. Willerth,et al.  3-D Bioprinting of Neural Tissue for Applications in Cell Therapy and Drug Screening , 2017, Front. Bioeng. Biotechnol..

[41]  A. Schatz,et al.  Efficacy of two different thiol-modified crosslinked hyaluronate formulations as vitreous replacement compared to silicone oil in a model of retinal detachment , 2017, PloS one.

[42]  F. Franconi,et al.  Evaluation of lauroyl-gemcitabine-loaded hydrogel efficacy in glioblastoma rat models. , 2018, Nanomedicine.

[43]  Xin Chen,et al.  Design of injectable agar-based composite hydrogel for multi-mode tumor therapy. , 2018, Carbohydrate polymers.

[44]  J. Fricain,et al.  Magnetic Resonance Imaging for tracking cellular patterns obtained by Laser-Assisted Bioprinting , 2018, Scientific Reports.

[45]  Biqin Dong,et al.  Fabricating customized hydrogel contact lens , 2016, Scientific Reports.

[46]  Effect of High-Intensity Focused Ultrasound on Drug Release from Doxorubicin-Loaded PEGylated Liposomes and Therapeutic Effect in Colorectal Cancer Murine Models. , 2016, Ultrasound in medicine & biology.

[47]  Hydrogel-based scaffolds to support intrathecal stem cell transplantation as a gateway to the spinal cord: clinical needs, biomaterials, and imaging technologies , 2018, npj Regenerative Medicine.

[48]  Rocky S Tuan,et al.  Application of visible light-based projection stereolithography for live cell-scaffold fabrication with designed architecture. , 2013, Biomaterials.

[49]  Y. C. Shin,et al.  Multiphoton imaging of myogenic differentiation in gelatin-based hydrogels as tissue engineering scaffolds , 2016, Biomaterials Research.

[50]  Jiangyang Zhang,et al.  Neural precursors exhibit distinctly different patterns of cell migration upon transplantation during either the acute or chronic phase of EAE: A serial MR imaging study , 2011, Magnetic resonance in medicine.

[51]  Arend Heerschap,et al.  Injectable hyaluronic acid hydrogel for 19F magnetic resonance imaging. , 2014, Carbohydrate polymers.

[52]  Savas Tasoglu,et al.  Bioprinting for Neural Tissue Engineering , 2018, Trends in Neurosciences.

[53]  A. Salgado,et al.  Influence of Different ECM-Like Hydrogels on Neurite Outgrowth Induced by Adipose Tissue-Derived Stem Cells , 2017, Stem cells international.

[54]  Jian Dong,et al.  The repair of large segmental bone defects in the rabbit with vascularized tissue engineered bone. , 2010, Biomaterials.

[55]  Stanislav Y. Emelianov,et al.  In vivo Ultrasound and Photoacoustic Monitoring of Mesenchymal Stem Cells Labeled with Gold Nanotracers , 2012, PloS one.

[56]  Gordon G Wallace,et al.  Functional 3D Neural Mini‐Tissues from Printed Gel‐Based Bioink and Human Neural Stem Cells , 2016, Advanced healthcare materials.

[57]  Thomas Schmitz-Rode,et al.  Three-Dimensional Printing and Angiogenesis: Tailored Agarose-Type I Collagen Blends Comprise Three-Dimensional Printability and Angiogenesis Potential for Tissue-Engineered Substitutes. , 2017, Tissue engineering. Part C, Methods.

[58]  Wei Zhu,et al.  Gelatin methacrylamide hydrogel with graphene nanoplatelets for neural cell-laden 3D bioprinting , 2016, 2016 38th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[59]  Mark A Anastasio,et al.  Imaging challenges in biomaterials and tissue engineering. , 2013, Biomaterials.

[60]  Vineet Agrawal,et al.  Hydrogels derived from central nervous system extracellular matrix. , 2013, Biomaterials.

[61]  Sai Zhang,et al.  Magnetic resonance imaging-three-dimensional printing technology fabricates customized scaffolds for brain tissue engineering , 2017, Neural regeneration research.

[62]  J. Temenoff,et al.  Spatially localized recruitment of anti-inflammatory monocytes by SDF-1α-releasing hydrogels enhances microvascular network remodeling. , 2016, Biomaterials.

[63]  Fabien Guillemot,et al.  In vivo bioprinting for computer- and robotic-assisted medical intervention: preliminary study in mice , 2010, Biofabrication.

[64]  K. Hong,et al.  Photothermal-modulated drug delivery and magnetic relaxation based on collagen/poly(γ-glutamic acid) hydrogel , 2017, International journal of nanomedicine.

[65]  Gary J Hooper,et al.  Bio-resin for high resolution lithography-based biofabrication of complex cell-laden constructs , 2018, Biofabrication.

[66]  Robert E Lenkinski,et al.  CEST: from basic principles to applications, challenges and opportunities. , 2013, Journal of magnetic resonance.

[67]  J. Bulte,et al.  Long-Term MRI Cell Tracking after Intraventricular Delivery in a Patient with Global Cerebral Ischemia and Prospects for Magnetic Navigation of Stem Cells within the CSF , 2014, PloS one.

[68]  Piotr Walczak,et al.  Personalized nanomedicine advancements for stem cell tracking. , 2012, Advanced drug delivery reviews.

[69]  K Miller,et al.  Mechanical properties of brain tissue in-vivo: experiment and computer simulation. , 2000, Journal of biomechanics.

[70]  Michel Modo,et al.  Non-invasive imaging of transplanted human neural stem cells and ECM scaffold remodeling in the stroke-damaged rat brain by (19)F- and diffusion-MRI. , 2012, Biomaterials.

[71]  Robert E Guldberg,et al.  In vivo bioluminescent tracking of mesenchymal stem cells within large hydrogel constructs. , 2014, Tissue engineering. Part C, Methods.

[72]  S. Badylak,et al.  Diamagnetic chemical exchange saturation transfer (diaCEST) affords magnetic resonance imaging of extracellular matrix hydrogel implantation in a rat model of stroke. , 2017, Biomaterials.

[73]  S. Hsu,et al.  3D bioprinting of neural stem cell-laden thermoresponsive biodegradable polyurethane hydrogel and potential in central nervous system repair. , 2015, Biomaterials.

[74]  M. Shoichet,et al.  A covalently modified hydrogel blend of hyaluronan–methyl cellulose with peptides and growth factors influences neural stem/progenitor cell fate , 2012 .

[75]  J. Winter,et al.  Imaging Cell-Matrix Interactions in 3D Collagen Hydrogel Culture Systems. , 2017, Macromolecular bioscience.

[76]  Ibrahim T. Ozbolat,et al.  Application areas of 3D bioprinting. , 2016, Drug discovery today.

[77]  N. Elvassore,et al.  3D high-resolution two-photon crosslinked hydrogel structures for biological studies. , 2017, Acta biomaterialia.

[78]  J. Bulte,et al.  Gene expression profiling reveals early cellular responses to intracellular magnetic labeling with superparamagnetic iron oxide nanoparticles , 2010, Magnetic resonance in medicine.

[79]  Ralph Weissleder,et al.  A novel polyacrylamide magnetic nanoparticle contrast agent for molecular imaging using MRI. , 2003, Molecular imaging.

[80]  Wei Zhu,et al.  3D bioprinting of functional tissue models for personalized drug screening and in vitro disease modeling. , 2018, Advanced drug delivery reviews.

[81]  Jae Young Lee,et al.  Cell-laden 3D bioprinting hydrogel matrix depending on different compositions for soft tissue engineering: Characterization and evaluation. , 2017, Materials science & engineering. C, Materials for biological applications.

[82]  Daniele Dini,et al.  Cryogenic 3D Printing of Super Soft Hydrogels , 2017, Scientific Reports.

[83]  Cheri X Deng,et al.  Noninvasive, quantitative, spatiotemporal characterization of mineralization in three-dimensional collagen hydrogels using high-resolution spectral ultrasound imaging. , 2012, Tissue engineering. Part C, Methods.

[84]  Yi Hong,et al.  Non-invasive characterization of polyurethane-based tissue constructs in a rat abdominal repair model using high frequency ultrasound elasticity imaging. , 2013, Biomaterials.

[85]  I. Hutchings,et al.  Adult rat retinal ganglion cells and glia can be printed by piezoelectric inkjet printing , 2013, Biofabrication.

[86]  Elise M. Stewart,et al.  3D printing of layered brain-like structures using peptide modified gellan gum substrates. , 2015, Biomaterials.

[87]  Malcolm Xing,et al.  3D bioprinting for biomedical devices and tissue engineering: A review of recent trends and advances , 2018, Bioactive materials.

[88]  Hao-Wei Han,et al.  Using 3D bioprinting to produce mini-brain , 2017, Neural regeneration research.

[89]  Piotr Walczak,et al.  Tracking stem cells using magnetic nanoparticles. , 2011, Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology.

[90]  Jennifer L. West,et al.  Three-dimensional micropatterning of bioactive hydrogels via two-photon laser scanning photolithography for guided 3D cell migration. , 2008, Biomaterials.

[91]  Ying Zheng,et al.  Formation of microvascular networks in vitro , 2013, Nature Protocols.

[92]  J. Bulte,et al.  Label-free imaging of gelatin-containing hydrogel scaffolds. , 2015, Biomaterials.

[93]  Ibrahim T. Ozbolat,et al.  Current advances and future perspectives in extrusion-based bioprinting. , 2016, Biomaterials.

[94]  T. Meade,et al.  DNA-gadolinium-gold nanoparticles for in vivo T1 MR imaging of transplanted human neural stem cells. , 2016, Biomaterials.

[95]  Dhruv R. Seshadri,et al.  A Review of Three-Dimensional Printing in Tissue Engineering. , 2016, Tissue engineering. Part B, Reviews.

[96]  Ali Khademhosseini,et al.  Bioinks for 3D bioprinting: an overview. , 2018, Biomaterials science.

[97]  Wojciech G. Lesniak,et al.  A Distinct Advantage to Intraarterial Delivery of 89Zr-Bevacizumab in PET Imaging of Mice With and Without Osmotic Opening of the Blood–Brain Barrier , 2018, The Journal of Nuclear Medicine.

[98]  S. Saavedra,et al.  Label-free detection and identification of protein ligands captured by receptors in a polymerized planar lipid bilayer using MALDI-TOF MS , 2015, Analytical and Bioanalytical Chemistry.

[99]  X. Jia,et al.  Novel multi-drug delivery hydrogel using scar-homing liposomes improves spinal cord injury repair , 2018, Theranostics.

[100]  D. Arifin,et al.  MRI-detectable pH nanosensors incorporated into hydrogels for in vivo sensing of transplanted cell viability , 2012, Nature materials.

[101]  Ibrahim T. Ozbolat,et al.  Evaluation of bioprinter technologies , 2017 .

[102]  Wonhye Lee,et al.  Bio-printing of collagen and VEGF-releasing fibrin gel scaffolds for neural stem cell culture , 2010, Experimental Neurology.

[103]  D. Kaplan,et al.  3D in vitro modeling of the central nervous system , 2015, Progress in Neurobiology.

[104]  Ali Khademhosseini,et al.  Direct 3D bioprinting of perfusable vascular constructs using a blend bioink. , 2016, Biomaterials.

[105]  Wei Zhu,et al.  Biomimetic 3D-printed scaffolds for spinal cord injury repair , 2019, Nature Medicine.

[106]  I-Chih Tan,et al.  Lymphatic imaging in humans with near-infrared fluorescence. , 2009, Current opinion in biotechnology.

[107]  S. Duan,et al.  NIR-Responsive Polycationic Gatekeeper-Cloaked Hetero-Nanoparticles for Multimodal Imaging-Guided Triple-Combination Therapy of Cancer. , 2017, Small.

[108]  Mallory R. Busso,et al.  Digital micromirror device (DMD)-based 3D printing of poly(propylene fumarate) scaffolds. , 2016, Materials science & engineering. C, Materials for biological applications.

[109]  Michel Modo,et al.  Biodegradation of ECM hydrogel promotes endogenous brain tissue restoration in a rat model of stroke. , 2018, Acta biomaterialia.

[110]  K. Williams,et al.  In vivo characterisation of a therapeutically relevant self‐assembling 18F‐labelled β‐sheet forming peptide and its hydrogel using positron emission tomography , 2017, Journal of labelled compounds & radiopharmaceuticals.

[111]  J. Bulte,et al.  MR Monitoring of Minimally Invasive Delivery of Mesenchymal Stem Cells into the Porcine Intervertebral Disc , 2013, PloS one.

[112]  E. Kuhl,et al.  Mechanical properties of gray and white matter brain tissue by indentation. , 2015, Journal of the mechanical behavior of biomedical materials.

[113]  M. Anastasio,et al.  X-ray Phase Contrast Allows Three Dimensional, Quantitative Imaging of Hydrogel Implants , 2015, Annals of Biomedical Engineering.

[114]  John A Jansen,et al.  Micro-computed tomographical imaging of soft biological materials using contrast techniques. , 2009, Tissue engineering. Part C, Methods.

[115]  Hai-bin Wang,et al.  Real-time tracking of adipose tissue-derived stem cells with injectable scaffolds in the infarcted heart , 2013, Heart and Vessels.

[116]  M. Morbidelli,et al.  Longitudinal Tracking of Human Fetal Cells Labeled with Super Paramagnetic Iron Oxide Nanoparticles in the Brain of Mice with Motor Neuron Disease , 2012, PloS one.

[117]  Beom Suk Lee,et al.  Long-term theranostic hydrogel system for solid tumors. , 2012, Biomaterials.

[118]  Elliot S. Bishop,et al.  3-D bioprinting technologies in tissue engineering and regenerative medicine: Current and future trends , 2017, Genes & diseases.

[119]  J. Bulte,et al.  Pre- and postmortem imaging of transplanted cells , 2015, International journal of nanomedicine.

[120]  Jonathan D. Suever,et al.  Cellular Encapsulation Enhances Cardiac Repair , 2013, Journal of the American Heart Association.

[121]  Micah J. Guthrie,et al.  The effects of cross-linked thermo-responsive PNIPAAm-based hydrogel injection on retinal function. , 2011, Biomaterials.

[122]  E. Ahrens,et al.  Fluorine-containing nanoemulsions for MRI cell tracking. , 2009, Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology.

[123]  R. Samanipour,et al.  A simple and high-resolution stereolithography-based 3D bioprinting system using visible light crosslinkable bioinks , 2015, Biofabrication.