RESUMEN

Cell printing has been popularized over the past few years as a revolutionary advance in tissue engineering has potentially enabled heterogeneous 3-D scaffolds to be built cell-by-cell. This review article summarizes the state-of-the-art cell printing techniques that utilize fluid jetting phenomena to deposit 2- and 3-D patterns of living eukaryotic cells. There are four distinct categories of jetbased approaches to printing cells. Laser guidance direct write (LG DW) was the first reported technique to print viable cells by forming patterns of embryonic-chick spinal-cord cells on a glass slide (1999). Shortly after this, modified laser-induced forward transfer techniques (LIFT) and modified ink jet printers were also used to print viable cells, followed by the most recent demonstration using an electrohydrodynamic jetting (EHDJ) method. The low cost of some of these printing technologies has spurred debate as to whether they could be used on a large scale to manufacture tissue and possibly even whole organs. This review summarizes the published results of these cell printers (cell viability, retained genotype and phenotype), and also includes a physical description of the various jetting processes with a discussion of the stresses and forces that may be encountered by cells during printing. We conclude the review by comparing and contrasting the different jet-based techniques, while providing a map for future experiments that could lead to significant advances in the field of tissue engineering.

Asunto(s)

Impresión/métodos , Ingeniería de Tejidos/métodos , Animales , Técnicas de Cultivo de Célula , Supervivencia Celular , Células Cultivadas , Periféricos de Computador , Genotipo , Humanos , Tinta , Rayos Láser , Fenotipo

RESUMEN

Methods to print patterns of mammalian cells to various substrates with high resolution offer unique possibilities to contribute to a wide range of fields including tissue engineering, cell separation, and functional genomics. This manuscript details experiments demonstrating that BioLP Biological Laser Printing, can be used to rapidly and accurately print patterns of single cells in a noncontact manner. Human osteosarcoma cells were deposited into a biopolymer matrix, and after 6 days of incubation, the printed cells are shown to be 100% viable. Printing low numbers of cells per spot by BioLP is shown to follow a Poisson distribution, indicating that the reproducibility for the number of cells per spot is therefore determined not by the variance in printed volume per drop but by random sampling statistics. Potential cell damage during the laser printing process is also investigated via immunocytochemical studies that demonstrate minimal expression of heat shock proteins by printed cells. Overall, we find that BioLP is able to print patterns of osteosarcoma cells with high viability, little to no heat or shear damage to the cells, and at the ultimate single cell resolution.

Asunto(s)

Técnicas de Cultivo de Célula/métodos , Separación Celular/métodos , Periféricos de Computador , Osteosarcoma/metabolismo , Osteosarcoma/patología , Impresión/métodos , Ingeniería de Tejidos/métodos , Recuento de Células/métodos , Técnicas de Cultivo de Célula/instrumentación , Línea Celular Tumoral , Proliferación Celular , Separación Celular/instrumentación , Supervivencia Celular/fisiología , Proteínas de Choque Térmico/metabolismo , Respuesta al Choque Térmico , Humanos , Modelos Biológicos , Modelos Estadísticos , Estrés Oxidativo/fisiología , Impresión/instrumentación , Ingeniería de Tejidos/instrumentación

RESUMEN

A technique by which to print patterns and multilayers of scaffolding and living cells could be used in tissue engineering to fabricate tissue constructs with cells, materials, and chemical diversity at the micron scale. We describe here studies using a laser forward transfer technology to print single-layer patterns of pluripotent murine embryonal carcinoma cells. This report focuses on verifying cell viability and functionality as well as the ability to differentiate cells after laser transfer. We find that when cells are printed onto model tissue scaffolding such as a layer of hydrogel, greater than 95% of the cells survive the transfer process and remain viable. In addition, alkaline comet assays were performed on transferred cells, showing minimal single-strand DNA damage from potential ultraviolet-cell interaction. We also find that laser-transferred cells express microtubular associated protein 2 after retinoic acid stimulus and myosin heavy chain protein after dimethyl sulfoxide stimulus, indicating successful neural and muscular pathway differentiation. These studies provide a foundation so that laser printing may next be used to build heterogeneous multilayer cellular structures, enabling cell growth and differentiation in heterogeneous three-dimensional environments to be uniquely studied.

Asunto(s)

Carcinoma Embrionario/metabolismo , Diferenciación Celular/fisiología , Animales , Supervivencia Celular/fisiología , Daño del ADN/fisiología , Inmunohistoquímica , Ratones , Microscopía Fluorescente , Células Tumorales Cultivadas

RESUMEN

The absorption and emission spectra, excited-state lifetimes, quantum yields, and electrochemical measurements have been obtained for a new series of chiral complexes based on three different chiral 2,2':6',2' '-terpyridine ligands, (-)-ctpy, (-)-[ctpy-x-ctpy], and (-)-[ctpy-b-ctpy], with one, two, or multiple Ru metal centers. The room-temperature absorption and emission maxima of [[((-)-ctpy)Ru]-(-)-[ctpy-b-ctpy]-[Ru((-)-ctpy)]](PF(6))(4) and ((-)-[ctpy-b-ctpy])-[[Ru((-)-[ctpy-b-ctpy])](PF(6))(2)](n) were shifted to lower energies and also exhibited significantly longer luminescence lifetimes when compared to [Ru((-)-ctpy)(2)](PF(6))(2), [[((-)-ctpy)Ru]-(-)-[ctpy-x-ctpy]-[Ru((-)-ctpy)]](PF(6))(4), and ((-)-[ctpy-x-ctpy])-[[Ru((-)-[ctpy-x-ctpy])](PF(6))(2)](n). In terms of their electrochemical behavior, all of the complexes studied exhibited one Ru-centered and two ligand-centered redox waves and the [[((-)-ctpy)Ru]-(-)-[ctpy-x-ctpy]-[Ru((-)-ctpy)]](PF(6))(4), ((-)-[ctpy-x-ctpy])-[[Ru((-)-[ctpy-x-ctpy])](PF(6))(2)](n), and ((-)-[ctpy-b-ctpy])-[[Ru((-)-[ctpy-b-ctpy])](PF(6))(2)](n)() complexes were found to electrodeposit upon ligand-based reduction. The difference between the formal potentials of the Ru-centered and the first ligand-centered (least negative) waves corresponded linearly with the changes in the observed emission energies. The shifts in energy are discussed using a particle-in-a-box model, and the luminescence lifetimes are discussed in terms of the structure of the excited-state manifold.

RESUMEN

We have investigated the electrochemical, spectroscopic, and electroluminescent properties of a family of diimine complexes of Ru featuring various aliphatic side chains as well as a more extended pi-conjugated system. The performance of solid-state electroluminescent devices fabricated from these complexes using indium tin oxide (ITO) and gold contacts appears to be dominated by ionic space charge effects. Their electroluminescence efficiency was limited by the photoluminescence efficiency of the Ru films and not by charge injection from the contacts. The incorporation of di-tert-butyl side chains on the dipyridyl ligand was found to be the most beneficial substitution in terms of reducing self-quenching of luminescence.