Theoretical studies of the g factors and local structures of the Ni3+ centers in Na2 Zn(SO4 )2 ·4H2 O and K2 Zn(SO4 )2 ·6H2 O crystals.

The local structures and the g factors gi (i = x, y, z) for Ni3+ centers in Na2 Zn(SO4 )2 ·4H2 O (DPPH) and K2 Zn(SO4 )2 ·6H2 O (PHZS) crystals are theoretically studied by using the perturbation formulas of the g factors for a 3d7 ion with low spin (S = 1/2) in orthorhombically compressed octahedra. In these formulas, the contributions to g factors from both the spin-orbit coupling interactions of the central ion and ligands are taken into account, and the required crystal-field parameters are estimated from the superposition model and the local geometry of the systems. Based on the calculations, the Ni-O bonds are found to suffer the axial compression δz (or Δz) of about 0.111 Å (or 0.036 Å) along the z-axis for Ni3+ centers in DPPH (or PHZS) crystals. Meanwhile, the Ni-O bonds may experience additional planar bond length variation δx (≈0.015 Å) along x- and y-axes for the orthorhombic Ni3+ center in DPPH. The theoretical g factors agree well with the experimental data. The obtained local structural parameters for both Ni3+ centers are discussed.

Studying the drift of in line pH measurements in cell culture.

The culture of Chinese hamster ovary (CHO) cells to produce monoclonal antibodies (MAb) requires accurate measurement and control of pH. Unwanted pH drifts in cell culture can adversely affect process performance, product quality, and product yield. To measure and control pH throughout the length of a culture, most cell culture processes use traditional glass pH probes. Several variables can affect the design and performance of glass pH electrodes and lead to drift in the measurement. Understanding these variables and their effects on pH performance can lead to design improvements and potentially reduce the drift. In this study, a set of Rosemount Analytical glass pH probes was investigated in cell culture operations. Electrochemical properties of the probes were monitored throughout the experiments. Experimental results show that the glass membrane potential experiences the biggest change during cell culture operations. Changes in the reference electrode potential are small compared with the changes in glass membrane potential. The glass membranes are affected by the steam sterilization process and this is the main cause for drift in the probe sensing signal during cell culture operations. Steam sterilization can cause the potential of glass membranes to change by up to 15 mV (∼ 0.25 pH units). This change in membrane potential can be observed as an undesirable pH drift in bioreactors.

STS markers linked to the Rf1 fertility restorer gene of cotton.

Marker-assisted selection (MAS) can accelerate the process of plant breeding, and sequence-tagged site (STS) markers are highly specific for regions of DNA being used for MAS. The objective of this research was to develop STS markers tightly linked with Rf1, the fertility restoring gene for cytoplasmic male sterility (CMS) in cotton (Gossypium hirsutum L.). Bulked segregant analysis was employed to screen for Rf1-linked RAPD markers in a backcross population. Four RAPD markers were identified, three of which co-segregated with Rf1 (UBC147(1400), UBC607(500), and UBC679(700)). Another fragment, UBC169(800), co-segregated with the previously reported UBC169(700) in repulsion phase at a distance of 4.5 cM from Rf1. A marker published by others (UBC659(1500)) mapped to 2.7 cM from Rf1 and 1.8 cM from UBC169(800). Four sets of STS primer pairs were designed based on the RAPD fragment sequences. The primer pairs from the UBC147(1400) and UBC607(500) fragments both amplified a single fragment specific to fertile plants. The UBC679(700) and UBC659(1500) STS primer pairs each amplified one fragment specific to fertile plants and a monomorphic fragment. These four Rf1-linked STS markers were also present in the Rf1 donor species G. harknessii (D2-2). The three primer pairs that produced co-segregating STS markers also amplified fragments from G. trilobum (D8). However, the D8 fragment amplified by the UBC147(1400) STS primers was larger than that from D2-2, and G. trilobum does not restore fertility to CMS-D2-2 lines. These STS markers will be useful in the development of restorer parental lines in cotton CMS breeding efforts.