17 research outputs found
I329L protein-based indirect ELISA for detecting antibodies specific to African swine fever virus
African swine fever (ASF) is a disease that causes severe economic losses to the global porcine industry. As no vaccine or drug has been discovered for the prevention and control of ASF virus (ASFV), accurate diagnosis and timely eradication of infected animals are the primary measures, which necessitate accurate and effective detection methods. In this study, the truncated ASFV I329L (amino acids 70–237), was induced using IPTG and expressed in Escherichia coli cells. The highly antigenic viral protein I329L was used to develop an indirect enzyme-linked immunosorbent assay (iELISA), named I329L-ELISA, which cut-off value was 0.384. I329L-ELISA was used to detect 186 clinical pig serum samples, and the coincidence rate between the indirect ELISA developed here and the commercial kit was 96.77%. No cross-reactivity was observed with CSFV, PRRSV, PCV2, or PRV antibody-positive pig sera, indicating good specificity. Both intra- assay and inter-assay coefficients were below 10%, and the detection sensitivity of the iELISA reached 1:3200. In this study, an iELISA for ASFV antibody detection was developed based on the truncated ASFV I329L protein. Overall, the I329L-ELISA is a user-friendly detection tool that is suitable for ASFV antibody detection and epidemiological surveillance
Microsite Determines the Soil Nitrogen and Carbon Mineralization in Response to Nitrogen Addition in a Temperate Desert
Nitrogen deposition can change the soil in N and C cycling processes. However, a general understanding of how N deposition changes C and N mineralization has not yet been reached. Soil organic C and N mineralization beneath the dominant shrubs of Haloxylon ammodendron and between the shrubs in response to two levels of N addition (2.5 gN m−2 and 5 gN m−2 per year) were investigated in the 1st, 4th, and 9th year of N addition in a temperate desert of northern China. N addition promoted soil N mineralization (RmN), and the nitrification rate (RNN) increased C mineralization in the interplant and decreased it beneath shrubs. N addition increased soil microbial biomass C (Cmic), N (Nmic), and PLFAs in the interplant, and decreased it beneath shrubs. RmN and RNN were related to Nmic, and RCM was related to Cmic and the total PLFAs. N addition increased the fungal biomass alongside the ratio of fungal to bacterial PLFAs in the interplants while decreasing them beneath shrubs. Our results support how N addition can increase soil N mineralization and nitrification, but the effects on soil C mineralization are dependent on the amount of nitrogen addition, the soil’s available carbon content, and water. Finally, the divergent responses of microbial communities to N addition between microsites suggest that the “fertile islands” effects on nutrients and microbial biomass are important when estimating feedbacks of C and N cycling to projected N deposition in the desert ecosystem
Multistate Reaction Coordinate Model for Charge and Energy Transfer Dynamics in the Condensed Phase
Constructing multistate
model Hamiltonians from all-atom electronic
structure calculations and molecular dynamics simulations is crucial
for understanding charge and energy transfer dynamics in complex condensed
phases. The most popular two-level system model is the spin-boson
Hamiltonian, where the nuclear degrees of freedom are represented
as shifted normal modes. Recently, we proposed the general multistate
nontrivial extension of the spin-boson model, i.e., the multistate
harmonic (MSH) model, which is constructed by extending the spatial
dimensions of each nuclear mode so as to satisfy the all-atom reorganization
energy restrictions for all pairs of electronic states. In this work,
we propose the multistate reaction coordinate (MRC) model with a primary
reaction coordinate and secondary bath modes as in the Caldeira-Leggett
form but in extended spatial dimensions. The MRC model is proven to
be equivalent to the MSH model and offers an intuitive physical picture
of the nuclear-electronic feedback in nonadiabatic processes such
as the inherent trajectory of the reaction coordinate. The reaction
coordinate is represented in extended dimensions, carrying the entire
reorganization energies and bilinearly coupled to the secondary bath
modes. We demonstrate the MRC model construction for photoinduced
charge transfer in an organic photovoltaic caroteniod-porphyrin-C60 molecular triad dissolved in tetrahydrofuran as well as
excitation energy transfer in a photosynthetic light-harvesting Fenna-Matthews-Olson
complex. The MRC model provides an effective and robust platform for
investigating quantum dissipative dynamics in complex condensed-phase
systems since it allows a consistent description of realistic spectral
density, state-dependent system-bath couplings, and heterogeneous
environments due to static disorder in reorganization energies
Multistate Reaction Coordinate Model for Charge and Energy Transfer Dynamics in the Condensed Phase
Constructing multistate
model Hamiltonians from all-atom electronic
structure calculations and molecular dynamics simulations is crucial
for understanding charge and energy transfer dynamics in complex condensed
phases. The most popular two-level system model is the spin-boson
Hamiltonian, where the nuclear degrees of freedom are represented
as shifted normal modes. Recently, we proposed the general multistate
nontrivial extension of the spin-boson model, i.e., the multistate
harmonic (MSH) model, which is constructed by extending the spatial
dimensions of each nuclear mode so as to satisfy the all-atom reorganization
energy restrictions for all pairs of electronic states. In this work,
we propose the multistate reaction coordinate (MRC) model with a primary
reaction coordinate and secondary bath modes as in the Caldeira-Leggett
form but in extended spatial dimensions. The MRC model is proven to
be equivalent to the MSH model and offers an intuitive physical picture
of the nuclear-electronic feedback in nonadiabatic processes such
as the inherent trajectory of the reaction coordinate. The reaction
coordinate is represented in extended dimensions, carrying the entire
reorganization energies and bilinearly coupled to the secondary bath
modes. We demonstrate the MRC model construction for photoinduced
charge transfer in an organic photovoltaic caroteniod-porphyrin-C60 molecular triad dissolved in tetrahydrofuran as well as
excitation energy transfer in a photosynthetic light-harvesting Fenna-Matthews-Olson
complex. The MRC model provides an effective and robust platform for
investigating quantum dissipative dynamics in complex condensed-phase
systems since it allows a consistent description of realistic spectral
density, state-dependent system-bath couplings, and heterogeneous
environments due to static disorder in reorganization energies
Synthesis and Application of Hexamethyl-1,1′-spirobiindane-Based Phosphine-Oxazoline Ligands in Ni-Catalyzed Asymmetric Arylation of Cyclic Aldimines
With the vastly increasing applications
of chiral phosphine-oxazoline
(PHOX) hybrid ligands in various transition-metal-catalyzed reactions,
novel PHOX ligands bearing innovative backbones are highly valuable
and in great demand. This study describes the development of a new
type of chiral PHOX ligands based on a hexamethyl-1,1′-spirobiindane
scaffold and incorporating both a phosphine and an oxazoline moiety.
The optimal ligand provided high yields and excellent enantioselectivities
for the Ni-catalyzed asymmetric arylation of cyclic <i>N</i>-sulfonyl imines with arylboronic acids leading to chiral amines
Synthesis and Application of Hexamethyl-1,1′-spirobiindane-Based Phosphine-Oxazoline Ligands in Ni-Catalyzed Asymmetric Arylation of Cyclic Aldimines
With the vastly increasing applications
of chiral phosphine-oxazoline
(PHOX) hybrid ligands in various transition-metal-catalyzed reactions,
novel PHOX ligands bearing innovative backbones are highly valuable
and in great demand. This study describes the development of a new
type of chiral PHOX ligands based on a hexamethyl-1,1′-spirobiindane
scaffold and incorporating both a phosphine and an oxazoline moiety.
The optimal ligand provided high yields and excellent enantioselectivities
for the Ni-catalyzed asymmetric arylation of cyclic <i>N</i>-sulfonyl imines with arylboronic acids leading to chiral amines
Integrated technology of design, construction and management for wharf engineering based on BIM A case study of the liquefied hydrocarbon wharf in Jiangsu
With the development of technology, BIM can be gradually applied in the wharf engineering, but due to the specialties coexistence, there are still some problems. Based on the liquefied hydrocarbon wharf in Jiangsu, it is explored and summarized the application of BIM in wharf engineering design, construction and management, so it solves the problems of collaborative design, simulation construction, real-time sharing of the collaborative platform, etc. It provides a set of effective schemes and reference cases for the application of BIM in wharf engineering
Efficacy of pediatric dermatology Extension for Community Healthcare Outcomes (ECHO) sessions on augmenting primary care providers\u27 confidence and abilities.
Due to the shortage of pediatric dermatologists and the abundance of skin disorders presenting in childhood, general pediatricians shoulder the management of many pediatric dermatologic disorders and would benefit from additional dermatology-specific training. To address this educational gap, general pediatricians were enrolled in a pediatric dermatology-specific Project Extension for Community Healthcare Outcomes (ECHO) program and surveyed to assess the efficacy of the program in increasing providers\u27 ability and confidence in managing pediatric dermatologic conditions. Providers unanimously reported increased confidence and abilities in assessment and management of pediatric dermatologic conditions. Pediatric dermatology Project ECHO demonstrated high efficacy in improving general practitioners\u27 comfort and knowledge on dermatology-specific topics and may be used as an education model for enhancing primary care providers\u27 knowledge and management of common disorders
Allocation of ecological water rights considering ecological networks in arid watersheds : A framework and case study of Tarim River basin
A robust water supply system is significant to the local ecosystem of riparian vegetation in the arid basin. Considering the elasticity and relative importance of ecological water use in different regions of the basin, this study defines the ecological water rights on a multi-year scale, divides the priority of those rights based on the ecological network, and proposes a rights allocation method. The application of the method to the mainstream watershed of Tarim River in China shows that when the overall available ecological water is only 77% of the ecological water demand, it can ensure that the ecological water demand of vegetation in important areas is fully met and the growth condition is good. However, the demand in non-important areas must be less than 50% and the growth condition will deteriorate. This method expands the existing definition and distribution of water rights, and the approach of coupling ecological networks can be used for the efficient management of ecological water supply in other arid basins