There is described a method for extracting a target chemical compound from a cellular material in a sample. The method comprising the steps of: subjecting the sample to mechanical lysis to cause disruption of a cellular membrane in the cellular material; contacting the sample with an alkaline material to produce a lysate composition comprising the target chemical compound; and recovering the lysate composition from the sample. There is also described a method for producing a lysate composition comprising RNA from a mammalian bodily fluid sample comprising a cellular material. There is also described a method for extracting a nucleic acid from a cellular material in a bodily fluid or an inoculant derived therefrom.

Described herein are methods and compositions related to generation of induced pluripotent stem cells (iPSCs). Improved techniques for establishing highly efficient, reproducible reprogramming using non-integrating episomal plasmid vectors. Using the described reprogramming protocol, one is able to consistently reprogram non-T cells with close to 100% success from non-T cell or non-B cell sources. Further advantages include use of a defined reprogramming media E7 and using defined clinically compatible substrate recombinant human L-521. Generation of iPSCs from these blood cell sources allows for recapitulation of the entire genomic repertoire, preservation of genomic fidelity and enhanced genomic stability.

The present invention provides a cartilage regenerating composition including a fetal cartilage tissue-derived cell and an extracellular matrix derived from a fetal cartilage tissue, and a preparing method thereof. According to the present invention, the cartilage-regenerating composition may produce a three-dimensional tissue of a size suitable for use as a cartilage without a scaffold, may be easily transplantable regardless of the size and shape of the cartilage defect at the site of administration since it can be administered in the form of a gel, but has high application and adhesion, may exhibit a high binding ability to the host tissue, and may have a phenotype of mature cartilage tissue, thereby exhibiting an excellent cartilage regeneration effect.

Delivering a payload across a plasma membrane of a cell includes providing a population of cells and contacting the population of cells with a volume of an aqueous solution. The aqueous solution includes the payload and alcohol content greater than 5 percent concentration. The volume of the aqueous solution may be a function of exposed surface area of the population of cells, or may be a function of a number of cells in the population of cells. Related compositions, apparatus, systems, techniques, and articles are also described.

A method for producing an objective protein using animal cells as an expression host is provided. The objective protein is produced by culturing animal cells having an objective protein-producing ability under conditions where the phosphoric acid concentration and/or the potassium concentration in the culture medium is increased.

Provided a method for preparing a blastocyst. The method includes culturing a fertilized egg in a culture medium containing bubbles containing a reducing gas. The reducing gas may contain at least one selected from the group consisting of hydrogen, carbon monoxide, nitrogen monoxide, and hydrogen sulfide. The bubbles may have an average particle size of from 10 nm to 1,000 nm.

Disclosed is a method for culturing mesenchymal stem cells, comprising culturing mesenchymal stem cells in a medium containing calcium in a concentration of from 2.1 to 3.8 mM and magnesium in a concentration of from 1.0 to 3.0 mM under a hypoxic condition of 2 to 5% oxygen. The culturing method can increase the population of mesenchymal stem cells even with a small number of passages by improving mesenchymal stem cells in proliferative capacity and viability. In addition, the mesenchymal stem cells prepared by the culturing method are effectively used to treat or improve a pulmonary disease.

The present invention provides a process for controlling the production of ethanol by microbial fermentation of gaseous substrates. More specifically, a process is provided for controlling ethanol productivity through addition of vitamins and a low cell retention time. In accordance with the process, vitamins B1, B5 and B7 are added in amounts that increase specific ethanol productivity. Cell retention times are maintained at low levels.

The present invention refers to a method to convert H.sub.2 and CO.sub.2 into methane by methanogenic microorganisms in a bioreactor in a continuous production process for methane enriched gas compositions, while culturing the methanogenic microorganisms under cell retention conditions and continuously removing metabolic water in the cell culture medium.

A glass-ceramic composition includes a first crystalline phase including lithium disilicate; and a second crystalline phase comprising at least one of: zircon, zirconia, apatite, or a combination thereof.