Optimization of cryopreservation of stem cells cultured as neurospheres: comparison between vitrification, slow-cooling and rapid cooling freezing protocols

We compared cryopreservation of mammalian neural stem cells (NSCs) cultured as neurospheres by slow-cooling (1 C/min) in 10% (v/v) DMSO and cryopreservation by immersion into liquid nitrogen in ethylene glycol (EG)-sucrose solutions that support vitrification (40% (v/v) EG, 0.6 M sucrose) or that do not (37% v/v) EG, 0.6 M sucrose and 30% (v/v) EG, 0.6 M sucrose); the concentration of penetrating cryoprotectant in the last two solutions was lowered with the intention to reduce their toxicity towards NSCs. To protect against contamination a straw-in-straw technique was employed. Vitrification offered the best combination of preservation of structural integrity of neurospheres, cell viability (>96%), multipotency and karyotype. Rapid cooling in 37% (v/v) EG, 0.6 M sucrose afforded good viability but did not preserve structural integrity. Rapid cooling in 30% (v/v) EG, 0.6 M sucrose additionally reduced cell viability to 77%. Slow-cooling reduced cell viability to 65% and damaged the neurospheres. This study suggests that, in contrast to freezing, vitrification has immense potential for the cryopreservation of stem cells cultured as neurospheres or in other structured cultures.     

The use of variable temperature 13C solid-state MAS NMR and GIPAW DFT calculations to explore the dynamics of diethylcarbamazine citrate

Experimental ¹³C solid-state magic-angle spinning (MAS) Nuclear Magnetic Resonance (NMR) as well as Density-Functional Theory (DFT) gauge-including projector augmented wave (GIPAW) calculations were used to probe disorder and local mobility in diethylcarbamazine citrate, (DEC)⁺(citrate)⁻. This compound has been used as the first option drug for the treatment of filariasis, a disease endemic in tropical countries and caused by adult worms of Wuchereria bancrofti, which is transmitted by mosquitoes. We firstly present 2D ¹³C─¹H dipolar-coupling-mediated heteronuclear correlation spectra recorded at moderate spinning frequency, to explore the intermolecular interaction between DEC and citrate molecules. Secondly, we investigate the dynamic behavior of (DEC)⁺(citrate)⁻ by varying the temperature and correlating the experimental MAS NMR results with DFT GIPAW calculations that consider two (DEC)⁺ conformers (in a 70:30 ratio) for crystal structures determined at 293 and 235 K. Solid-state NMR provides insights on slow exchange dynamics revealing conformational changes involving particularly the DEC ethyl groups.     

Inverse freezing in the Hopfield fermionic Ising spin glass with a transverse magnetic field

The Hopfield fermionic Ising spin glass (HFISG) model in the presence of a magnetic transverse field Γ is used to study the inverse freezing transition. The mean field solution of this model allows introducing a parameter a that controls the frustration level. Particularly, in the present fermionic formalism, the chemical potential μ and the Γ provide a magnetic dilution and quantum spin flip mechanism, respectively. Within the one step replica symmetry solution and the static approximation, the results show that the reentrant transition between the spin glass and the paramagnetic phases, which is related to the inverse freezing for a certain range of μ, is gradually suppressed when the level of frustration a is decreased. Nevertheless, the quantum fluctuations caused by Γ can destroy this inverse freezing for any value of a.     

Hydrogen as a cause of doping in zinc oxide

Zinc oxide, a wide-band-gap semiconductor with many technological applications, typically exhibits n-type conductivity. The cause of this conductivity has been widely debated. A first-principles investigation, based on density functional theory, produces strong evidence that hydrogen acts as a source of conductivity: it can incorporate in high concentrations and behaves as a shallow donor. This behavior is unexpected and very different from hydrogen's role in other semiconductors, in which it acts only as a compensating center and always counteracts the prevailing conductivity. These insights have important consequences for control and utilization of hydrogen in oxides in general.