Natalia Higuita-Castro

miR-146a regulates mechanotransduction and pressure-induced inflammation in small airway epithelium

Mechanical ventilation generates biophysical forces, including high transmural pressures, which exacerbate lung inflammation. This study sought to determine whether microRNAs (miRNAs) respond to this mechanical force and play a role in regulating mechanically induced inflammation. Primary human small airway epithelial cells (HSAEpCs) were exposed to 12 h of oscillatory pressure and/or the proinflammatory cytokine TNF‐α. Experiments were also conducted after manipulating miRNA expression and silencing the transcription factor NF‐κB or toll‐like receptor proteins IRAK1 and TRAF6. NF‐κB activation, IL‐6/IL‐8/IL‐1 β cytokine secretion, miRNA expression, and IRAK1/TRAF6 protein levels were monitored. A total of 12 h of oscillatory pressure and TNF‐α resulted in a 5‐ to 7‐fold increase in IL‐6/IL‐8 cytokine secretion, and oscillatory pressure also resulted in a time‐dependent increase in IL‐6/IL‐8/IL‐1β cytokine secretion. Pressure and TNF‐α also resulted in distinct patterns of miRNA expression, with miR‐146a being the most deregulated miRNA. Manipulating miR‐146a expression altered pressure‐induced cytokine secretion. Silencing of IRAK1 or TRAF6, confirmed targets of miR‐146a, resulted in a 3‐fold decrease in pressure‐induced cytokine secretion. Cotransfection experiments demonstrate that miR‐146as regulation of pressure‐induced cytokine secretion depends on its targeting of both IRAK1 and TRAF6. MiR‐146a is a mechanosensitive miRNA that is rapidly up‐regulated by oscillatory pressure and plays an important role in regulating mechanically induced inflammation in lung epithelia.—Huang, Y., Crawford, M., Higuita‐Castro, N., Nana‐Sinkam, P., Ghadiali, S. N. miR‐146a regulates mechanotransduction and pressure‐induced inflammation in small airway epithelium. FASEB J. 26, 3351–3364 (2012). www.fasebj.org

Microfabricated mimics of in vivo structural cues for the study of guided tumor cell migration

Guided cell migration plays a crucial role in tumor metastasis, which is considered to be the major cause of death in cancer patients. Such behavior is regulated in part by micro/nanoscale topographical cues present in the parenchyma or stroma in the form of fiber-like and/or conduit-like structures (e.g., white matter tracts, blood/lymphatic vessels, subpial and subperitoneal spaces). In this paper we used soft lithography micromolding to develop a tissue culture polystyrene platform with a microscale surface pattern that was able to induce guided cell motility along/through fiber-/conduit-like structures. The migratory behaviors of primary (glioma) and metastatic (lung and colon) tumors excised from the brain were monitored via time-lapse microscopy at the single cell level. All the tumor cells exhibited axially persistent cell migration, with percentages of unidirectionally motile cells of 84.0 ± 3.5%, 58.3 ± 6.8% and 69.4 ± 5.4% for the glioma, lung, and colon tumor cells, respectively. Lung tumor cells showed the highest migratory velocities (41.8 ± 4.6 μm h(-1)) compared to glioma (24.0 ± 1.8 μm h(-1)) and colon (26.7 ± 2.8 μm h(-1)) tumor cells. This platform could potentially be used in conjunction with other biological assays to probe the mechanisms underlying the metastatic phenotype under guided cell migration conditions, and possibly by itself as an indicator of the effectiveness of treatments that target specific tumor cell motility behaviors.

Vacuum-assisted cell seeding in a microwell cell culture system.

We present a simple method to actively pattern individual cells and groups of cells in a polymer-based microdevice using vacuum-assisted cell seeding. Soft lithography is used to mold polymer microwells with various geometries on top of commercially available porous membranes. Cell suspensions are placed in a vacuum filtration setup to pull culture medium through the microdevice, trapping the cells in the microwells. The process is evaluated by determining the number of cells per microwell for a given cell seeding density and microwell geometry. This method is tested with adherent and nonadherent cells (NIH 3T3 fibroblasts, PANC-1 pancreatic ductal epithelial-like cells, and THP-1 monocytic leukemia cells). These devices could find applications in high-throughput cell screening, cell transport studies, guided formation of cell clusters, and tissue engineering.

Influence of airway wall compliance on epithelial cell injury and adhesion during interfacial flows

Interfacial flows during cyclic airway reopening are an important source of ventilator-induced lung injury. However, it is not known how changes in airway wall compliance influence cell injury during airway reopening. We used an in vitro model of airway reopening in a compliant microchannel to investigate how airway wall stiffness influences epithelial cell injury. Epithelial cells were grown on gel substrates with different rigidities, and cellular responses to substrate stiffness were evaluated in terms of metabolic activity, mechanics, morphology, and adhesion. Repeated microbubble propagations were used to simulate cyclic airway reopening, and cell injury and detachment were quantified via live/dead staining. Although cells cultured on softer gels exhibited a reduced elastic modulus, these cells experienced less plasma membrane rupture/necrosis. Cells on rigid gels exhibited a minor, but statistically significant, increase in the power law exponent and also exhibited a significantly larger height-to-length aspect ratio. Previous studies indicate that this change in morphology amplifies interfacial stresses and, therefore, correlates with the increased necrosis observed during airway reopening. Although cells cultured on stiff substrates exhibited more plasma membrane rupture, these cells experienced significantly less detachment and monolayer disruption during airway reopening. Western blotting and immunofluorescence indicate that this protection from detachment and monolayer disruption correlates with increased focal adhesion kinase and phosphorylated paxillin expression. Therefore, changes in cell morphology and focal adhesion structure may govern injury responses during compliant airway reopening. In addition, these results indicate that changes in airway compliance, as occurs during fibrosis or emphysema, may significantly influence cell injury during mechanical ventilation.

Portland cement for bone tissue engineering: Effects of processing and metakaolin blends

The need for a suitable scaffolding material for load bearing bone tissue engineering still has yet to be met satisfactorily. In this study, Portland cement and Portland cement/metakaolin (MK) blends were processed to render them biologically and mechanically suitable for such application. Portland cement was mixed with MK at different ratios. The slurries were hydrated under atmospheric (noncarbonated samples) and high-CO₂ conditions (carbonated samples). The mechanical properties were characterized via compressive tests. The bioactivity was analyzed in a simulated body fluid solution. Scanning electron microscopy and energy dispersive spectroscopy were used to evaluate sample morphology and chemistry. The cytocompatibility (direct contact assay, MTT test, and alkaline phosphatase activity) was tested using human osteoblast-like cells. Cell responses were observed via conventional and electron microscopy. The results showed that the implementation of MK did not significantly influence the mechanical properties. All the samples evidenced bioactive behavior. Cell experiments confirmed a highly cytotoxic response to the noncarbonated specimens. The introduction of MK as well as the CO₂ pretreatment significantly improved the cytocompatibility of the specimens. These results show that properly processed Portland cement and Portland cement/MK blends could present suitable properties for the development of load-bearing scaffolding structures in bone tissue-engineering applications.

Topical tissue nano-transfection mediates non-viral stroma reprogramming and rescue

Although cellular therapies represent a promising strategy for a number of conditions, current approaches face major translational hurdles, including limited cell sources and the need for cumbersome pre-processing steps (for example, isolation, induced pluripotency). In vivo cell reprogramming has the potential to enable more-effective cell-based therapies by using readily available cell sources (for example, fibroblasts) and circumventing the need for ex vivo pre-processing. Existing reprogramming methodologies, however, are fraught with caveats, including a heavy reliance on viral transfection. Moreover, capsid size constraints and/or the stochastic nature of status quo approaches (viral and non-viral) pose additional limitations, thus highlighting the need for safer and more deterministic in vivo reprogramming methods. Here, we report a novel yet simple-to-implement non-viral approach to topically reprogram tissues through a nanochannelled device validated with well-established and newly developed reprogramming models of induced neurons and endothelium, respectively. We demonstrate the simplicity and utility of this approach by rescuing necrotizing tissues and whole limbs using two murine models of injury-induced ischaemia.

Reinforced Portland cement porous scaffolds for load‐bearing bone tissue engineering applications

Modified Portland cement porous scaffolds with suitable characteristics for load-bearing bone tissue engineering applications were manufactured by combining the particulate leaching and foaming methods. Non-crosslinked polydimethylsiloxane was evaluated as a potential reinforcing material. The scaffolds presented average porosities between 70 and 80% with mean pore sizes ranging from 300 μm up to 5.0 mm. Non-reinforced scaffolds presented compressive strengths and elastic modulus values of 2.6 and 245 MPa, respectively, whereas reinforced scaffolds exhibited 4.2 and 443 MPa, respectively, an increase of ∼62 and 80%. Portland cement scaffolds supported human osteoblast-like cell adhesion, spreading, and propagation (t = 1-28 days). Cell metabolism and alkaline phosphatase activity were found to be enhanced at longer culture intervals (t ≥ 14 days). These results suggest the possibility of obtaining strong and biocompatible scaffolds for bone repair applications from inexpensive, yet technologically advanced materials such as Portland cement.

Gene delivery to cultured embryonic stem cells using nanofiber-based sandwich electroporation.

Multiple gene transfections are often required to control the differentiation of embryonic stem cells. This is typically done by removing the cells from the culture substrate and conducting gene transfection via bulk electroporation (in suspension), which is then followed by further culture. Such repetitive processes could affect the growth and behavior of delicate/scarce adherent cells. We have developed a novel nanofiber-based sandwich electroporation device capable of in situ and in culture gene transfection. Electrospinning was used to deposit poly(ε-caprolactone)/gelatin nanofibers on the Al(2)O(3) nanoporous support membrane, on top of which a polystyrene microspacer was thermally bonded to control embryonic stem cell colony formation. The applicability of this system was demonstrated by culturing and transfecting mouse embryonic stem cells. Measurements of secreted alkaline phosphatase protein and metabolic activity showed higher transfection efficacy and cell viability compared to the conventional bulk electroporation approach.

Micropatterned Coatings for Guided Tissue Regeneration in Dental Implantology

Dento-alveolar trauma and congenital absences are the most important causes of edentulism that are not associated with bacteria. However, the World Health Organization reports show that dental caries and periodontitis, two conditions of bacterial origin, are the most frequent oral diseases in humans [1]. These conditions might be avoided if an adequate oral preventive health policy is implemented, including preventive and educational measures that, regardless of the population s socioeconomic factors, have shown their effectiveness. Despite these facts, tooth extraction1, defined as the surgical removal of a tooth, is currently the most frequent surgical procedure in the world [1].

Lab-on-a-Chip Platforms for Biophysical Studies of Cancer with Single-Cell Resolution

Recent cancer research has more strongly emphasized the biophysical aspects of tumor development, progression, and microenvironment. In addition to genetic modifications and mutations in cancer cells, it is now well accepted that the physical properties of cancer cells such as stiffness, electrical impedance, and refractive index vary with tumor progression and can identify a malignant phenotype. Moreover, cancer heterogeneity renders population-based characterization techniques inadequate, as individual cellular features are lost in the average. Hence, platforms for fast and accurate characterization of biophysical properties of cancer cells at the single-cell level are required. Here, we highlight some of the recent advances in the field of cancer biophysics and the development of lab-on-a-chip platforms for single-cell biophysical analyses of cancer cells.