Microtopographical effects of natural scaffolding on cardiomyocyte function and arrhythmogenesis

A natural myocardial patch for heart regeneration derived from porcine urinary bladder matrix (UBM) was previously reported to outperform synthetic materials (Dacron and expanded polytetrafluoroethylene (ePTFE)) used in current surgical treatments. UBM, an extracellular matrix prepared from urinary bladder, has intricate three-dimensional architecture with two distinct sides: the luminal side with a smoother surface relief; and the abluminal side with a fine mesh of nano- and microfibers. This study tested the ability of this natural scaffold to support functional cardiomyocyte networks, and probed how the local microtopography and composition of the two sides affects cell function. Cardiomyocytes isolated from neonatal rats were seeded in vitro to form cardiac tissue onto luminal (L) or abluminal (Ab) UBM. Immunocytochemistry of contractile cardiac proteins demonstrated growth of cardiomyocyte networks with mature morphology on either side of UBM, but greater cell compactness was seen in L. Fluorescence-based imaging techniques were used to measure dynamic changes in intracellular calcium concentration upon electrical stimulation of L and Ab-grown cells. Functional differences in cardiac tissue grown on the two sides manifested themselves in faster calcium recovery (p < 0.04) and greater hysteresis (difference in response to increasing and decreasing pacing rates) for L vs Ab side (p < 0.03). These results suggest that surface differences may be leveraged to engineer the desired cardiomyocyte responses and highlight the potential of natural scaffolds for fostering heart repair.     

The cardiomyogenic differentiation of rat mesenchymal stem cells on silk fibroin–polysaccharide cardiac patches in vitro

Polysaccharides and proteins profoundly impact the development and growth of tissues in the natural extra-cellular matrix (ECM). To mimic a natural ECM, polysaccharides were incorporated to/or co-sprayed with silk fibroin (SF) to produce SF/chitosan (CS) or SF/CS–hyaluronic acid (SF/CS–HA) microparticles that were further processed by mechanical pressing and genipin cross-linking to produce hybrid cardiac patches. The ATR–FTIR spectra confirm the co-existence of CS or CS–HA and SF in microparticles and patches. For evaluating the cellular responses of rMSCs to the SF/CS and SF/CS–HA cardiac patches, the growth of rMSCs and cardiomyogenic differentiation of 5-aza inducing rMSCs cultured on patches was examined. First, the isolated rMSCs were identified with various positive and negative surface markers such as CD 44 and CD 31 by a flow cytometric technique, respectively. For examining the growth of rMSCs on the patches, MTT viability assay was performed, and the results demonstrated that the growth of rMSCs on SF and SF-hybrid patches significantly exceeded (P < 0.001) that on culture wells after seven days of cultivation. Additionally, the relative growth rates of rMSCs on SF/CS and SF/CS–HA hybrid patches were significantly better (P < 0.01) than that on SF patches that were also observed by using vimentin stain to the cells. For instance, the relative cell growth rates (%) in cell culture wells, SF, SF/CS and SF/CS–HA patches were 100%, 282.9 ± 6.5%, 337.0 ± 8.0% and 332.6 ± 6.6% (n = 6, for all), respectively. For investigating the effects of the hybrid patches on cardiomyogenic differentiation of 5-aza inducing rMSCs, the expressions of specific cardiac genes of cells such as Gata4 and Nkx2.5 were examined by real-time quantitative polymerase chain reaction (real-time PCR) analysis. The results of cardiomyogenic differentiation of induced rMSCs on SF/CS and SF/CS–HA hybrid patches significantly improved the expressions of cardiac genes of Gata4, Nkx2.5, Tnnt2 and Actc1 genes (all, P < 0.01 or better, n = 3) than those on SF patches and culture wells. Interestingly, the results of cardiac gene expressions of the cells on the SF/CS–HA hybrid patches were the most pronounced in promoting cardiomyogenic differentiations in this investigation. Furthermore, immunofluorescence staining of cardiac proteins such as cardiotin and connexin 43 for induced rMSCs cultured on SF/CS and SF/CS–HA hybrid patches were much pronounced compared with SF patches, indicating the improvements of cardiomyogenic differentiation on the hybrid patches. The results of this study demonstrate that the SF/CS and SF/CS–HA hybrid patches may be promising biomaterials for regenerating infarcted cardiac tissues.     

Lipoteichoic acid from Staphylococcus aureus directly affects cardiomyocyte contractility and calcium transients

Lipoteichoic acid (LTA) is the key pathogenic factor of gram-positive bacteria and contributes significantly to organ dysfunction in sepsis, a frequent complication in critical care patients. We hypothesized that LTA directly affects cardiomyocyte function, thus contributing to cardiac failure in sepsis. This study was designed to evaluate the effects of LTA on contractile properties and calcium-transients of isolated adult rat cardiomyocytes.When myocytes were exposed to LTA for 1 h prior to analysis, the amplitudes of calcium-transients as well as sarcomere shortening increased to 130% and 142% at 1 Hz stimulation frequency. Relengthening of sarcomeres as well as decay of calcium-transients was accelerated after LTA incubation. Exposure to LTA for 24 h resulted in significant depression of calcium-transients as well as of sarcomere shortening compared to controls.One of the major findings of our experiments is that LTA most likely affects calcium-handling of the cardiomyocytes. The effect is exacerbated by reduced extracellular calcium, which resembles the clinical situation in septic patients. Functionally, an early stimulating effect of LTA with increased contractility of the cardiomyocytes may be an in vitro reflection of early hyperdynamic phases in clinical sepsis. Septic disorders have been shown to induce late hypodynamic states of the contractile myocardium, which is also supported at the single-cell level in vitro by results of our 24 h-exposure to LTA.     

Effects of late postconditioning on gene expression and cell death in neonatal rat cardiomyocyte cultures

The cell death and gene expression in neonatal cardiomyocyte cultures were investigated in a late postconditioning model. The primary cultures were subjected to a 30 min of anoxia followed by 60 min or 24 h of reoxygenation. Postconditioning was carried out in three cycles of 1 min reoxygenations followed by 1 min anoxia, respectively. After 24 h of reperfusion the percentages of living, necrotic, and apoptotic cells were determined by staining with bis-benzimide and propidium iodide. Anoxia–reoxygenation significantly increased the necrotic and apoptotic cells both at its first and second episodes. Postconditioning in remote period did not protect the cells from the second anoxia. Postconditioning decreased the anoxia–reoxygenation-induced increase of HSP70 and HSP90 mRNA expression. We observed a decrease of HIF-3alpha gene expression in remote postconditioning. The FRAP gene expression was leveled to control value. Thus, the changes of mRNA gene expression did not show cytoprotection of cardiomyocytes in remote postconditioning model.     

Cyclically stretching developing tissue in vivo enhances mechanical strength and organization of vascular grafts

Tissue-engineered vascular grafts must have qualities that rival native vasculature, specifically the ability to remodel, the expression of functional endothelial components and a dynamic and functional extracellular matrix (ECM) that resists the forces of the arterial circulation. We have developed a device that when inserted into the peritoneal cavity, attracts cells around a tubular scaffold to generate autologous arterial grafts. The device is capable of cyclically stretching (by means of a pulsatile pump) developing tissue to increase the mechanical strength of the graft. Pulsed (n = 8) and unpulsed (n = 8) devices were implanted for 10 days in Lovenaar sheep (n = 8). Pulsation occurred for a period of 5–8 days before harvest. Thick unadhered autologous tissue with cells residing in a collagen ECM was produced in all devices. Collagen organization was greater in the circumferential direction of pulsed tissue. Immunohistochemical labelling revealed the hematopoietic origin of >90% cells and a significantly higher coexpression with vimentin in pulsed tissue. F-actin expression, mechanical failure strength and strain were also significantly increased by pulsation. Moreover, tissue could be grafted as carotid artery patches. This paper shows that unadhered tissue tubes with increased mechanical strength and differentiation in response to pulsation can be produced with every implant after a period of 10 days. However, these tissue tubes require a more fine-tuned exposure to pulsation to be suitable for use as vascular grafts.     

Electrospun nanostructured scaffolds for bone tissue engineering

The current challenge in bone tissue engineering is to fabricate a bioartificial bone graft mimicking the extracellular matrix (ECM) with effective bone mineralization, resulting in the regeneration of fractured or diseased bones. Biocomposite polymeric nanofibers containing nanohydroxyapatite (HA) fabricated by electrospinning could be promising scaffolds for bone tissue engineering. Nanofibrous scaffolds of poly-l-lactide (PLLA, 860 ± 110 nm), PLLA/HA (845 ± 140 nm) and PLLA/collagen/HA (310 ± 125 nm) were fabricated, and the morphology, chemical and mechanical characterization of the nanofibers were evaluated using scanning electron microscopy, Fourier transform infrared spectroscopy and tensile testing, respectively. The in vitro biocompatibility of different nanofibrous scaffolds was also assessed by growing human fetal osteoblasts (hFOB), and investigating the proliferation, alkaline phosphatase activity (ALP) and mineralization of cells on different nanofibrous scaffolds. Osteoblasts were found to adhere and grow actively on PLLA/collagen/HA nanofibers with enhanced mineral deposition of 57% higher than the PLLA/HA nanofibers. The synergistic effect of the presence of an ECM protein, collagen and HA in PLLA/collagen/HA nanofibers provided cell recognition sites together with apatite for cell proliferation and osteoconduction necessary for mineralization and bone formation. The results of our study showed that the biocomposite PLLA/collagen/HA nanofibrous scaffold could be a potential substrate for the proliferation and mineralization of osteoblasts, enhancing bone regeneration.     

Heterogeneous micromechanical properties of the extracellular matrix in healthy and infarcted hearts

Infarcted hearts are macroscopically stiffer than healthy organs. Nevertheless, although cell behavior is mediated by the physical features of the cell niche, the intrinsic micromechanical properties of healthy and infarcted heart extracellular matrix (ECM) remain poorly characterized. Using atomic force microscopy, we studied ECM micromechanics of different histological regions of the left ventricle wall of healthy and infarcted mice. Hearts excised from healthy (n = 8) and infarcted mice (n = 8) were decellularized with sodium dodecyl sulfate and cut into 12 μm thick slices. Healthy ventricular ECM revealed marked mechanical heterogeneity across histological regions of the ventricular wall with the effective Young’s modulus ranging from 30.2 ± 2.8 to 74.5 ± 8.7 kPa in collagen- and elastin-rich regions of the myocardium, respectively. Infarcted ECM showed a predominant collagen composition and was 3-fold stiffer than collagen-rich regions of the healthy myocardium. ECM of both healthy and infarcted hearts exhibited a solid-like viscoelastic behavior that conforms to two power-law rheology. Knowledge of intrinsic micromechanical properties of the ECM at the length scale at which cells sense their environment will provide further insight into the cell–scaffold interplay in healthy and infarcted hearts.     

Electrically polarized HAp-coated Ti: In vitro bone cell–material interactions

Electrically polarized bulk sintered hydroxyapatite (HAp) compacts have been shown to accelerate mineralization and bone tissue ingrowth in vivo. In this work, a comprehensive study has been carried out to investigate the influence of surface charge and polarity on in vitro bone cell adhesion, proliferation and differentiation on electrically polarized HAp-coated Ti. Uniform and crack free sol–gel derived HAp coatings of 20 ± 1.38 μm thickness were polarized by application of an external d.c. field of 2.0 kV cm^?1 at 400 °C for 1h. In vitro bioactivity of polarized HAp coatings was evaluated by soaking in simulated body fluid, and bone cell–material interactions were studied by culturing with human fetal osteoblast cells (hFOB) for a maximum period of 11 days. Scanning electron microscopic observation showed that accelerated mineralization on negatively charged surfaces favored rapid cell attachment and faster tissue ingrowth over non-polarized HAp coating surfaces, while positive charge on HAp coating surfaces restricted apatite nucleation with limited cellular response. Immunochemistry and confocal microscopy confirmed that the cell adhesion and early stage differentiation were more pronounced on negatively charged coating surfaces as hFOB cells expressed higher vinculin and alkaline phosphatase proteins on negatively charged surface compared to cells grown on all other surfaces. Our results in this study are process independent and potentially applicable to any other commercially available coating techniques.     

Quercetin-crosslinked porcine heart valve matrix: Mechanical properties,stability, anticalcification and cytocompatibility

Bioprosthetic heart valves, prepared by glutaraldehyde (GA) crosslinking, have some limitations due to poor durability, calcification and immunogenic reactions. The aim of this study was to evaluate the crosslinking effect of a natural product, quercetin, on decellularized porcine heart valve extracellular matrix (ECM). After crosslinking, the mechanical properties, stability, anticalcification and cytocompatibility were examined. The results showed that the tensile strength of quercetin-crosslinked ECM was higher than that of GA-crosslinked ECM. After crosslinking with quercetin, the thermal denaturation temperature of ECM was clearly increased. Quercetin-crosslinked ECM could be stored in D-Hanks solution for at least 30 days without any loss of ultimate tensile strength and elasticity. After soaking in D-Hanks solution for 36 days, there was only 11.55% non-crosslinked excess quercetin released and no further release thereafter. Cell culture study shows that no inhibition on proliferation of vascular endothelial cells occurred when the quercetin concentration was lower than 1 μg ml^?1. This non-cytotoxic concentration was 100 times higher than that of GA. The resistibility of quercetin-crosslinked ECM to in vitro enzymatic hydrolysis was comparable to that of GA-crosslinked ECM. An in vitro anticalcification experiment showed that quercetin crosslinking could protect ECM from deposition of minerals in simulated body fluid. The present study demonstrated that quercetin can crosslink porcine heart valve ECM effectively, which suggests that quercetin might be a new crosslinking reagent for the preparation of bioprosthetic heart valve xenografts and scaffolds for heart valve tissue engineering.     

A multilayered scaffold of a chitosan and gelatin hydrogel supported by a PCL core for cardiac tissue engineering

A three-dimensional scaffold composed of self-assembled polycaprolactone (PCL) sandwiched in a gelatin–chitosan hydrogel was developed for use as a biodegradable patch with a potential for surgical reconstruction of congenital heart defects. The PCL core provides surgical handling, suturability and high initial tensile strength, while the gelatin–chitosan scaffold allows for cell attachment, with pore size and mechanical properties conducive to cardiomyocyte migration and function. The ultimate tensile stress of the PCL core, made from blends of 10, 46 and 80 kDa (Mn) PCL, was controllable in the range of 2–4 MPa, with lower average molecular weight PCL blends correlating with lower tensile stress. Blends with lower molecular weight PCL also had faster degradation (controllable from 0% to 7% weight loss in saline over 30 days) and larger pores. PCL scaffolds supporting a gelatin–chitosan emulsion gel showed no significant alteration in tensile stress, strain or tensile modulus. However, the compressive modulus of the composite tissue was similar to that of native tissue (～15 kPa for 50% gelatin and 50% chitosan). Electron microscopy revealed that the gelatin–chitosan gel had a three-dimensional porous structure, with a mean pore diameter of ～80 μm, showed migration of neonatal rat ventricular myocytes (NRVM), maintained NRVM viability for over 7 days, and resulted in spontaneously beating scaffolds. This multi-layered scaffold has sufficient tensile strength and surgical handling for use as a cardiac patch, while allowing migration or pre-loading of cardiac cells in a biomimetic environment to allow for eventual degradation of the patch and incorporation into native tissue.     

Preparation and characterization of collagen-based ADSC-carrier sheets for cardiovascular application

The use of scaffolds composed of natural biodegradable matrices represents an attractive strategy to circumvent the lack of cell engraftment, a major limitation of stem cell therapy in cardiovascular diseases. Bovine-derived non-porous collagen scaffolds with different degrees of cross-linking (C0, C2, C5 and C10) were produced and tested for their mechanical behavior, in vitro biocompatibility with adipose-derived stem cells (ADSCs) and tissue adhesion and inflammatory reaction. Uniaxial tensile tests revealed an anisotropic behavior of collagen scaffolds (2 × 0.5 cm) and statistically significant differences in the mechanical behavior between cross-linked and non-cross-linked scaffolds (n = 5). In vitro, ADSCs adhered homogenously and showed a similar degree of proliferation on all four types of scaffolds (cells × 10³ cm^?2 at day 7: C0: 94.7 ± 37.1; C2: 91.7 ± 25.6; C5: 88.2 ± 6.8; C10: 72.8 ± 10.7; P = n.s.; n = 3). In order to test the in vivo biocompatibility, a chronic myocardial infarction model was performed in rats and 1.2 × 1.2 cm size collagen scaffolds implanted onto the heart 1 month post-infarction. Six animals per group were killed 2, 7 and 30 days after transplant. Complete and long-lasting adhesion to the heart was only observed with the non-cross-linked scaffolds with almost total degradation 1 month post-transplantation. After 7 and 30 days post-implantation, the degree of inflammation was significantly lower in the hearts treated with non-cross-linked scaffolds (day 7: C0: 10.2 ± 2.1%; C2: 16.3 ± 2.9%; C5: 15.9 ± 4.8%; C10: 17.4 ± 4.1%; P < 0.05 vs. C0; day 30: C0: 1.3 ± 1.3%; C2: 9.4 ± 3.0%; C5: 7.0 ± 2.1%; C10: 9.8 ± 2.5%; P < 0.01 vs. C0). In view of the results, the non-cross-linked scaffold (C0) was chosen as an ADSC-carrier sheet and tested in vivo. One week post-implantation, 25.3 ± 7.0% of the cells transplanted were detected in those animals receiving the cell-carrier sheet whereas no cells were found in animals receiving cells alone (n = 3 animals/group).We conclude that the biocompatibility and mechanical properties of the non-cross-linked collagen scaffolds make them a useful cell carrier that greatly favors tissue cell engraftment and may be exploited for cell transplantation in models of cardiac disease.     

Inhibiting accelerated rejection mediated by alloreactive CD4+ memory T cells and prolonging allograft survival by 1α,25-dihydroxyvitamin D3 in nude mice

Donor-reactive memory T cells are major barriers to long-term survival of transplanted organs due to their capacity to accelerate rejection. In this study we investigated the ability of 1α,25-dihydroxyvitamin D₃ [1,25(OH)₂D₃] to inhibit accelerated rejection mediated by alloreactive CD4⁺ memory T cells and to prolong cardiac allograft survival in an adoptive T cell memory/heart transplant model of nude mice. In vitro, the proliferation of CD4⁺ memory T cells was significantly inhibited by 1,25(OH)₂D₃ and was restored following addition of exogenous IL-2. Compared with the control group, the mean survival time of cardiac allografts in the 1,25(OH)₂D₃ group was prolonged from 6.5 ± 0.3 to 20.2 ± 0.8 days in vivo. Five days after transplantation, the levels of IL-2 and IFN-γ were reduced in the grafts and the recipient sera by 1,25(OH)₂D₃ treatment, while that of IL-10 increased. The proportions of CD4⁺ memory T cells and CD4⁺Foxp3⁺ T cells, both in recipient spleen and lymph nodes, were lowered by 1,25(OH)₂D₃ treatment when compared with the control group. Our data suggests that 1,25(OH)₂D₃ inhibits expansion of CD4⁺ memory T cells, possibly by inducing clonal anergy and/or clonal deletion, resulting in prolongation of cardiac allograft survival in nude mice. These results may provide a rational basis for exploiting 1,25(OH)₂D₃ as a novel immunosuppressant targeting CD4⁺ memory T cells.     

Effect of silicon content on the sintering and biological behaviour of Ca10(PO4)6-x(SiO4)x(OH)2-x ceramics

Silicated hydroxyapatite powders (Ca₁₀(PO₄)_6-x(SiO₄)_x(OH)_2-x; Si_xHA) were synthesized using a wet precipitation method. The sintering of Si_xHA ceramics with 0 ? x ? 1 was investigated. For 0 ? x ? 0.5, the sintering rate and grain growth decreased slightly with the amount of silicate. For larger amounts, the sintering behaviour differed with the formation of secondary phases before total densification. Sintering parameters (temperature and time) were adjusted to each composition to produce dense materials having similar microstructure without formation of these secondary phases. Dense ceramics made of pure hydroxyapatite and Si_xHA containing various amounts of silicate (up to x = 0.6) were biologically tested in vitro with human osteoblast-like cells. The proliferation of cells on the surface of the ceramics increased up to 5 days of culture, indicating that the materials were biocompatible. However, the silicon content did not influence the cell proliferation.     

Receptor changes in brain tissue of rats treated as neonates with capsaicin

Capsaicin, the hot chemical in chillies, administered to neonatal rats, causes destruction of polymodal nociceptive primary afferent neurons by acting on TRPV1 receptors causing intrinsic somatosensory deprivation. Although the effects of neonatal capsaicin treatment in the periphery have been extensively investigated, less is known about the brain networks to which the capsaicin sensory neurons are relayed. In the present study the effect of neonatal capsaicin treatment on brain receptors that have been shown to interact with TRPV1 was examined. Wistar rats were treated on neonatal day 2 with capsaicin and at 15–16 weeks of age, brains were processed to measure levels of muscarinic M₁/M₂ and M₂/M₄, serotonin 5HT_2A, cannabinoid CB₁, dopamine D₁, D₂ receptors and dopamine transporter. Overall increases in levels of muscarinic M₁/M₄ (F = 8.219, df = 1, p = 0.005), muscarinic M₂/M₄ (F = 99.759, df = 1, p < 0.0001), serotonin 5HT_2A (F = 28.892, df = 1, p < 0.0001), dopamine D₁ (F = 8.726, df = 1, p = 0.008) and cannabinoid CB₁ (F = 25.084, df = 1, p < 0.0001) receptors were found in the brains of capsaicin-treated rats, although significant regional changes occurred only in muscarinic M₂/M₄ and serotonin 5HT_2A receptors. The results of the present study suggest that neonatal intrinsic somatosensory deprivation may have a significant impact on substrates at the central nervous system that manifest as changes in central cholinergic, monaminergic and cannabinoid systems in the adult animal.     

Mesenchymal stem cell proliferation and differentiation on an injectable calcium phosphate – Chitosan composite scaffold

Calcium phosphate cement (CPC) can be molded or injected to form a scaffold in situ, has excellent osteoconductivity, and can be resorbed and replaced by new bone. However, its low strength limits CPC to non-stress-bearing repairs. Chitosan could be used to reinforce CPC, but mesenchymal stem cell (MSC) interactions with CPC-chitosan scaffold have not been examined. The objective of this study was to investigate MSC proliferation and osteogenic differentiation on high-strength CPC-chitosan scaffold. MSCs were harvested from rat bone marrow. At CPC powder/liquid (P/L) mass ratio of 2, flexural strength (mean ± sd; n = 5) was (10.0 ± 1.1) MPa for CPC-chitosan, higher than (3.7 ± 0.6) MPa for CPC (p < 0.05). At P/L of 3, strength was (15.7 ± 1.7) MPa for CPC-chitosan, higher than (10.2 ± 1.8) MPa for CPC (p < 0.05). Percentage of live MSCs attaching to scaffolds increased from 85% at 1 day to 99% at 14 days. There were (180 ± 37) cells/mm² on scaffold at 1 day; cells proliferated to (1808 ± 317) cells/mm² at 14 days. SEM showed MSCs with healthy spreading and anchored on nano-apatite crystals via cytoplasmic processes. Alkaline phosphatase activity (ALP) was (557 ± 171) (pNPP mM/min)/(μg DNA) for MSCs on CPC-chitosan, higher than (159 ± 47) on CPC (p < 0.05). Both were higher than (35 ± 32) of baseline ALP for undifferentiated MSCs on tissue-culture plastic (p < 0.05). In summary, CPC-chitosan scaffold had higher strength than CPC. MSC proliferation on CPC-chitosan matched that of the FDA-approved CPC control. MSCs on the scaffolds differentiated down the osteogenic lineage and expressed high levels of bone marker ALP. Hence, the stronger CPC-chitosan scaffold may be useful for stem cell-based bone regeneration in moderate load-bearing maxillofacial and orthopedic applications.     

Maternal–fetal metabolic gene–gene interactions and risk of neural tube defects

Single-gene analyses indicate that maternal genes associated with metabolic conditions (e.g., obesity) may influence the risk of neural tube defects (NTDs). However, to our knowledge, there have been no assessments of maternal–fetal metabolic gene–gene interactions and NTDs. We investigated 23 single nucleotide polymorphisms among 7 maternal metabolic genes (ADRB3, ENPP1, FTO, LEP, PPARG, PPARGC1A, and TCF7L2) and 2 fetal metabolic genes (SLC2A2 and UCP2). Samples were obtained from 737 NTD case-parent triads included in the National Birth Defects Prevention Study for birth years 1999–2007. We used a 2-step approach to evaluate maternal–fetal gene–gene interactions. First, a case-only approach was applied to screen all potential maternal and fetal interactions (n = 76), as this design provides greater power in the assessment of gene–gene interactions compared to other approaches. Specifically, ordinal logistic regression was used to calculate the odds ratio (OR) and 95% confidence interval (CI) for each maternal–fetal gene–gene interaction, assuming a log-additive model of inheritance. Due to the number of comparisons, we calculated a corrected p-value (q-value) using the false discovery rate. Second, we confirmed all statistically significant interactions (q < 0.05) using a log-linear approach among case-parent triads. In step 1, there were 5 maternal–fetal gene–gene interactions with q < 0.05. The “top hit” was an interaction between maternal ENPP1 rs1044498 and fetal SLC2A2 rs6785233 (interaction OR = 3.65, 95% CI: 2.32–5.74, p = 2.09 × 10^− 8, q = 0.001), which was confirmed in step 2 (p = 0.00004). Our findings suggest that maternal metabolic genes associated with hyperglycemia and insulin resistance and fetal metabolic genes involved in glucose homeostasis may interact to increase the risk of NTDs.     

Subchronic inhalation of coal dust particulate matter 10 induces bronchoalveolar hyperplasia and decreases MUC5AC expression in male Wistar rats

Coal dust is a pollutant found in coal mines that are capable of inducing oxidative stress and inflammation, but the effects on lung metaplasia as an early step of carcinogenesis remain unknown. The purpose of the present study was to evaluate the effects of PM₁₀ coal dust on lung histology, MUC5AC expression, epidermal growth factor (EGF) expression, and epidermal growth factor receptor (EGFR) expression. An experimental study was done on male Wistar rats, which were divided into the following groups: control groups exposed to coal dust for 14 days (at doses of 6.25 mg/m³, 12.5 mg/m³, and 25 mg/m³), and the groups exposed to coal dust for 28 days (at doses of 6.25 mg/m³, 12.5 mg/m³, and 25 mg/m³). EGF expressions in rat lungs were measured by ELISA. EGFR and MUC5AC were measured by a confocal laser scanning microscope. The bronchoalveolar epithelial image of the group exposed to coal dust for 14 and 28 days showed a epithelial rearrangement, hyperplastic (metaplastic) goblet cells, and scattered massive inflammatory cells. The pulmonary parenchymal image of the group of exposed to coal dust for 14 and 28 days showed scattered inflammatory cells filling up the pulmonary alveolar networks, leading to an appearance of thickened parenchymal alveoli until emphysema-like structure. There was no significant difference in MUC5AC, EGF, and EGFR expressions for 14-d exposure (p > 0.05). There was no significant difference in EGF and EGFR expressions for 28-d exposure (p > 0.05), but there was a significant difference in MUC5AC expression (p < 0.05). We concluded that subchronic inhalation of coal dust particulate matter 10 induces bronchoalveolar reactive hyperplasia and rearrangement of epithelial cells which accompanied by decrease expression MUC5AC in male rats.     

Local micromechanical properties of decellularized lung scaffolds measured with atomic force microscopy

Bioartificial lungs re-engineered from decellularized organ scaffolds are a promising alternative to lung transplantation. Critical features for improving scaffold repopulation depend on the mechanical properties of the cell microenvironment. However, the mechanics of the lung extracellular matrix (ECM) is poorly defined. The local mechanical properties of the ECM were measured in different regions of decellularized rat lung scaffolds with atomic force microscopy. Lungs excised from rats (n = 11) were decellularized with sodium dodecyl sulfate (SDS) and cut into ～7 μm thick slices. The complex elastic modulus (G¹) of lung ECM was measured over a frequency band ranging from 0.1 to 11.45 Hz. Measurements were taken in alveolar wall segments, alveolar wall junctions and pleural regions. The storage modulus (G′, real part of G¹) of alveolar ECM was ～6 kPa, showing small changes between wall segments and junctions. Pleural regions were threefold stiffer than alveolar walls. G′ of alveolar walls and pleura increased with frequency as a weak power law with exponent 0.05. The loss modulus (G″, imaginary part of G¹) was 10-fold lower and showed a frequency dependence similar to that of G′ at low frequencies (0.1–1 Hz), but increased more markedly at higher frequencies. Local differences in mechanical properties and topology of the parenchymal site could be relevant mechanical cues for regulating the spatial distribution, differentiation and function of lung cells.