Jin Ping Deng scite author profile

Experiments were conducted to determine the effects of feeding different starch sources on piglets. Four diets were formulated with maize, brown rice, sticky rice and Hi-Maize 1043 as starch sources, with resistant starch (RS) contents of 2.3%, 0.9%, 0.0%, 20.6%, and amylose and amylopectin ratio of 0.23%, 0.21%, 0.18%, 0.06% respectively. Fifty-six pigs weaned at 28 days of age were randomly assigned to one of the four diets. In Exp. 1, six piglets in each group were fitted with an indwelling jugular catheter. After 25 days of feeding trial, venous blood samples were obtained at time zero and every 1 h for 4 h. In Exp. 2, the remaining piglets were used to determine the effects of different starch sources on the fractional synthesis rate (FSR). The results indicated that feeding the Hi-Maize 1043 diet decreased (p < 0.05) plasma contents of glucose, insulin, lactic acid and T(3), while sticky rice increased plasma contents of glucose and insulin. The insulin contents in piglets fed the sticky rice diet was 69.2 microIU/ml at 1 h post-feeding which was highest among the starch diets. The FSR in the pancreas, spleen, duodenum, jejunum, ileum and colon in the corn group were much higher (p < 0.05) than that in the sticky rice group. These results suggest that RS is potentially beneficial for improving insulin sensitivity in young pigs and that the ratio of amylose and amylopectin have significantly effects on the FSR in splanchnic tissues in weaned piglets. Another finding of this study indicated maize with a ratio of amylose and amylopectin of 0.23 has the best starch sources for pig production.

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Ultrastable red-emitting phosphor-in-glass for superior high-power artificial plant growth LEDs

Deng

Zhang

et al. 2018

J. Mater. Chem. C

103

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Nitrate improves ammonia incorporation into rumen microbial protein in lactating dairy cows fed a low-protein diet

Wang

Ungerfeld

et al. 2018

Journal of Dairy Science

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Generation of ammonia from nitrate reduction is slower compared with urea hydrolysis and may be more efficiently incorporated into ruminal microbial protein. We hypothesized that nitrate supplementation could increase ammonia incorporation into microbial protein in the rumen compared with urea supplementation of a low-protein diet fed to lactating dairy cows. Eight multiparous Chinese Holstein dairy cows were used in a crossover design to investigate the effect of nitrate or an isonitrogenous urea inclusion in the basal low-protein diet on rumen fermentation, milk yield, and ruminal microbial community in dairy cows fed a low-protein diet in comparison with an isonitrogenous urea control. Eight lactating cows were blocked in 4 pairs according to days in milk, parity, and milk yield and allocated to urea (7.0 g urea/kg of dry matter of basal diet) or nitrate (14.6 g of NO/kg of dry matter of basal diet, supplemented as sodium nitrate) treatments, which were formulated on 75% of metabolizable protein requirements. Nitrate supplementation decreased ammonia concentration in the rumen liquids (-33.1%) and plasma (-30.6%) as well as methane emissions (-15.0%) and increased dissolved hydrogen concentration (102%), microbial N (22.8%), propionate molar percentage, milk yield, and 16S rRNA gene copies of Selenomonas ruminantium. Ruminal dissolved hydrogen was positively correlated with the molar proportion of propionate (r = 0.57), and negatively correlated with acetate-to-propionate ratio (r = -0.57) and estimated net metabolic hydrogen production relative to total VFA produced (r = -0.58). Nitrate reduction to ammonia redirected metabolic hydrogen away from methanogenesis, enhanced ammonia incorporation into rumen microbial protein, and shifted fermentation from acetate to propionate, along with increasing S. ruminantium 16S rRNA gene copies, likely leading to the increased milk yield.

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Eu³⁺‐Doped Phosphor‐in‐Glass: A Route toward Tunable Multicolor Materials for Near‐UV High‐Power Warm‐White LEDs

Deng

Zhang

et al. 2017

Advanced Optical Materials

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A novel route toward tunable multicolor materials through phosphor‐in‐glass (PiG) technology is proposed in this work. Before that, an ultrastable Eu3+‐doped precursor luminescent glass frit without thermal quenching in the temperature range of 80–480 K is developed to serve as an encapsulant that not only protects the embedded phosphor but also provides the red‐emitting component for the PiG. By adjusting the mass ratio of Sr4Al14O25:Eu2+ phosphor to glass frit, a series of tunable multicolor Eu3+‐doped PiG is obtained and exhibits a good resistance to the harsh conditions. Meanwhile, the luminescent color of Eu3+‐doped PiG can be modified by changing the excitation wavelength or ambient temperature. Finally, corresponding Eu3+‐doped PiG encapsulated high‐power light‐emitting diodes are further fabricated, especially the warm white‐light‐emitting diodes (WLEDs), showing good color stability under different drive currents and with different periods of operating time. All these results indicate that Eu3+‐doped PiG is a potential color converter applied in the high‐power warm‐WLEDs and the route above opens up a facile and potential approach to obtain multicolor materials.

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Jin Ping Deng

Dietary amylose and amylopectin ratio and resistant starch content affects plasma glucose, lactic acid, hormone levels and protein synthesis in splanchnic tissues

Ultrastable red-emitting phosphor-in-glass for superior high-power artificial plant growth LEDs

Nitrate improves ammonia incorporation into rumen microbial protein in lactating dairy cows fed a low-protein diet

Eu³⁺‐Doped Phosphor‐in‐Glass: A Route toward Tunable Multicolor Materials for Near‐UV High‐Power Warm‐White LEDs

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Jin Ping Deng

Dietary amylose and amylopectin ratio and resistant starch content affects plasma glucose, lactic acid, hormone levels and protein synthesis in splanchnic tissues

Ultrastable red-emitting phosphor-in-glass for superior high-power artificial plant growth LEDs

Nitrate improves ammonia incorporation into rumen microbial protein in lactating dairy cows fed a low-protein diet

Eu3+‐Doped Phosphor‐in‐Glass: A Route toward Tunable Multicolor Materials for Near‐UV High‐Power Warm‐White LEDs

Contact Info

Product

Resources

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Eu³⁺‐Doped Phosphor‐in‐Glass: A Route toward Tunable Multicolor Materials for Near‐UV High‐Power Warm‐White LEDs