A bulk dielectric polymer film with an intrinsic ultralow k value of 1.52 at 10 kHz has been successfully synthesized based on a novel polyimide FPTTPI. More importantly, such outstanding dielectric properties remain stable up to 280°C. The excellent ultralow dielectric properties are mainly because of the larger free volume (subnanoscale), which intrinsically exists in the amorphous region of polymeric materials. Meanwhile, FPTTPI also shows excellent thermal stability and mechanical properties, with a glass-transition temperature (T g ) of 280°C, 5 wt % loss temperature of 530°C, and a residual of 63% at 800°C under N 2 . It was soluble in common solvents, which made it possible to undergo simple spin-on or efficient, low-cost, and continuous roll-to-roll processes. ■ INTRODUCTIONWith the development of ultralarge-scale integration (ULSI) to high speed and high integration in the semiconductor industry, and with the continuing miniaturization in the dimensions of electronic devices utilized in ULSI circuits, an urgent need exists for high-performance low-k and ultralow-k dielectric materials (low-k: k ≤ 2.5; ultralow-k: k ≤ 2.0) has arisen. 1−4 Such dielectrics materials would reduce the capacitance between the metal interconnects, the resistance-capacitance delay, the line-to-line crosstalk noise, and the power dissipation; 5−7 these materials also have important application prospects in the fields of interlayer dielectric, semiconductor packaging (chips modules, etc.), and high-frequency, low-loss boards etc. So far, research of low-dielectric materials as an alternative to the workhorse dielectrics silicon dioxide (k = 3.9−4.3) are continually being pursued today, which mainly including organosilicates and organic polymers. 8−13 Compared with inorganic dielectric materials, organic polymer materials often have a lower dielectric constant, because of the lower materials density and lower individual bond polarizability. Moreover, they show distinct advantages, in terms of easy chemical and geometric structural design. 14−18 Thus, they have attracted much interest. Generally, by decreasing the dipole strength or the number of dipoles or a combination of both, the dielectric constant of full dense polymer materials can be lowered to 2.2−2.6. 5,19−22 The most common way is fluorination of dielectric materials or increasing the free volume by rearranging the material structure. 23−27 However, it seems that no true dielectric generational extendibility to the ultralow-k region can be achieved without embracing the concept of porosity, either for organosilicates or organic polymers. 28−32 The k-value of these porous materials can be less than 1.5, 33−39 but the method itself is complicated, difficult to control, and expensive. Moreover, the pore structure, the size, and the distribution would greatly affect the homogeneity of the materials, which makes this technique difficult for large-area applications. In addition, the porosity tends to dramatically reduce the mechanical strength and increase the permeability o...
Tribbles homolog 3 (TRIB3) was found to inhibit insulin-stimulated Akt phosphorylation and modulate gluconeogenesis in rodent liver. Currently, we examined a role for TRIB3 in skeletal muscle insulin resistance. Ten insulin-sensitive, ten insulin-resistant, and ten untreated type 2 diabetic (T2DM) patients were metabolically characterized by hyperinsulinemic euglycemic glucose clamps, and biopsies of vastus lateralis were obtained. Skeletal muscle samples were also collected from rodent models including streptozotocin (STZ)-induced diabetic rats, db/db mice, and Zucker fatty rats. Finally, L6 muscle cells were used to examine regulation of TRIB3 by glucose, and stable cell lines hyperexpressing TRIB3 were generated to identify mechanisms underlying TRIB3-induced insulin resistance. We found that 1) skeletal muscle TRIB3 protein levels are significantly elevated in T2DM patients; 2) muscle TRIB3 protein content is inversely correlated with glucose disposal rates and positively correlated with fasting glucose; 3) skeletal muscle TRIB3 protein levels are increased in STZ-diabetic rats, db/db mice, and Zucker fatty rats; 4) stable TRIB3 hyperexpression in muscle cells blocks insulin-stimulated glucose transport and glucose transporter 4 (GLUT4) translocation and impairs phosphorylation of Akt, ERK, and insulin receptor substrate-1 in insulin signal transduction; and 5) TRIB3 mRNA and protein levels are increased by high glucose concentrations, as well as by glucose deprivation in muscle cells. These data identify TRIB3 induction as a novel molecular mechanism in human insulin resistance and diabetes. TRIB3 acts as a nutrient sensor and could mediate the component of insulin resistance attributable to hyperglycemia (i.e., glucose toxicity) in diabetes. glucose toxicity; type 2 diabetes; insulin signaling THE PREVALENCE OF TYPE 2 DIABETES MELLITUS (T2DM) is rapidly increasing in Westernized nations. Although it likely results from both genetic and environment factors, a key pathogenic characteristic of T2DM is insulin resistance, due to impaired stimulation of glucose uptake in skeletal muscle.To obtain a more comprehensive understanding of insulin resistance, we have performed cDNA microarray studies to systematically assess differential gene expression in skeletal muscle from insulin-sensitive (IS) vs. insulin-resistant (IR) humans (59, 60). These analyses identified Tribbles homolog 3 (TRIB3) as a gene with increased expression in patients with T2DM. Tribbles was first identified by Mata et al. (31) in 2000 as a regulator of germ-cell development in Drosophila (31). Tribbles inhibits mitosis and regulates DNA damage repair by promoting ubiquitination and proteasome-mediated degradation of specific cell cycle regulators early in development (17,31,46,49). Mammals express a family of three genes, TRIB1, TRIB2, and TRIB3, that are homologous to Tribbles. These family members are characterized by a variant kinase domain in the center of molecule with a high homology to serine/ threonine kinases (22). However, they app...
Androgens are critical for prostate development, growth, and functions. In general, they support proliferation and prevent cell death of prostatic epithelial cells. Here, we studied changes of gene expression after castration and testosterone replacement therapy in the rat ventral prostate using cDNA microarrays analysis. We could identify 230 genes that were regulated in either experimental condition. Using hierarchical clustering analysis, different groups of genes could be detected according to their expression pattern. This enabled us to distinguish the putative androgen-responsive genes from the secondary-responsive ones. Among genes that altered during castration and testosterone replacement, a set of oxidative stress-related genes, including thioredoxin, peroxiredoxin 5, superoxide dismutase 2, glutathione peroxidase 1, selenoprotein 15 kDa, microsomal glutathione-S-transferase, glutathione reductase, and epoxide hydrolase, were changed by castration. We hypothesize that modulation of redox status can be a factor of relevance in androgen withdrawal-induced prostate apoptosis. In selective cases, quantitative RT-PCR was used to confirm changes in gene expression. Immunohistochemistry was performed to detect thioredoxin and ezrin. Both of these were detected in the prostate and seem to be regulated in a similar manner as shown by gene expression analysis. In conclusion, gene expression profiling provides a unique opportunity for understanding the molecular mechanisms of androgen actions in prostate gland.
The aim of this study was to identify genes for hepatic fuel metabolism with a gender-differentiated expression and to determine which of these that might be regulated by the female-specific secretion of GH. Effects of gender and continuous infusion of GH to male rats were studied in the liver using cDNA microarrays representing 3200 genes. Sixty-nine transcripts displayed higher expression levels in females, and 177 displayed higher expression in males. The portion of GH-regulated genes was the same (30%) within the two groups of gender-specific genes. The male liver had a higher expression of genes involved in fuel metabolism, indicating that male rats might have a greater capacity for high metabolic turnover, compared with females. Most notable among the female-predominant transcripts was fatty acid translocase/CD36, with 18-fold higher mRNA levels in the female liver and 4-fold higher mRNA levels in males treated with GH, compared with untreated males. This gender-differentiated expression was confirmed at mRNA and protein levels in the rat and at the mRNA level in human livers. Although purely speculative, it is possible that higher levels of fatty acid translocase/CD36 in human female liver might contribute to the sexually dimorphic development of diseases resulting from or characterized by disturbances in lipid metabolism, such as arteriosclerosis, hyperlipidemia, and insulin resistance.
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