Abstract: The present invention includes methods for effecting phenotype conversion in a cell by transfecting the cell with phenotype-converting nucleic acid. Expression of the nucleic acids results in a phenotype conversion in the transfected cell. Preferably the phenotype-converting nucleic acid is a transcriptome, and more preferably an mRNA transcriptome.

Abstract: The present invention includes methods for effecting phenotype conversion in a cell by transfecting the cell with phenotype-converting nucleic acid. Expression of the nucleic acids results in a phenotype conversion in the transfected cell. Preferably the phenotype-converting nucleic acid is a transcriptome, and more preferably an mRNA transcriptome.

Abstract: The present invention includes methods for transferring a multigenic phenotype to a cell by transfecting, preferably by phototransfection, and locally transfecting a cell or a cellular process with a laser while the cell is bathed in a fluid medium comprising two or more nucleic acids, thereby introducing the nucleic acid into the interior of the cell. Expression of the nucleic acids results in a multigenic phenotype in the transfected cell.

Abstract: The present invention includes methods for effecting phenotype conversion in a cell by transfecting the cell with phenotype-converting nucleic acid. Expression of the nucleic acids results in a phenotype conversion in the transfected cell. Preferably the phenotype-converting nucleic acid is a transcriptome, and more preferably an mRNA transcriptome.

Abstract: The present invention includes methods for transferring a multigenic phenotype to a cell by transfecting, preferably by phototransfection, and locally transfecting a cell or a cellular process with a laser while the cell is bathed in a fluid medium comprising two or more nucleic acids, thereby introducing the nucleic acid into the interior of the cell. Expression of the nucleic acids results in a multigenic phenotype in the transfected cell.

Abstract: The present invention includes methods for transferring a multigenic phenotype to a cell by transfecting, preferably by phototransfection, and locally transfecting a cell or a cellular process with a laser while the cell is bathed in a fluid medium comprising two or more nucleic acids, thereby introducing the nucleic acid into the interior of the cell. Expression of the nucleic acids results in a multigenic phenotype in the tranfected cell.

Abstract: Disclosed herein is a data synchronization between a client computing device's local store and another data store, such as a data store that is remote to the client computing device. The other data store may comprise a cloud data store. The existence, or absence, of a causal relationship between the local and remote data stores for a given data item is used to determine whether or not a conflict exists and/or whether a requested operation may be performed. The casual relationship may be determined using a previous commit's hash value, referred to as a hash_base value, and a hash value, both of which are associated with the data item.

Abstract: Disclosed herein is a data synchronization between a client computing device's local store and another data store, such as a data store that is remote to the client computing device. The other data store may comprise a cloud data store. The existence, or absence, of a causal relationship between the local and remote data stores for a given data item is used to determine whether or not a conflict exists and/or whether a requested operation may be performed. The causal relationship may be determined using a previous commit's hash value, referred to as a hash_base value, and a hash value, both of which are associated with the data item.

Abstract: Disclosed herein is a data synchronization between a client computing device's local store and another data store, such as a data store that is remote to the client computing device. The other data store may comprise a cloud data store. The existence, or absence, of a causal relationship between the local and remote data stores for a given data item is used to determine whether or not a conflict exists and/or whether a requested operation may be performed. The causal relationship may be determined using a previous commit's hash value, referred to as a hash_base value, and a hash value, both of which are associated with the data item.

Abstract: Disclosed herein is a data synchronization between a client computing device's local store and another data store, such as a data store that is remote to the client computing device. The other data store may comprise a cloud data store. The existence, or absence, of a causal relationship between the local and remote data stores for a given data item is used to determine whether or not a conflict exists and/or whether a requested operation may be performed. The causal relationship may be determined using a previous commit's hash value, referred to as a hash_base value, and a hash value, both of which are associated with the data item.

Abstract: The present invention includes methods for effecting phenotype conversion in a cell by transfecting the cell with phenotype-converting nucleic acid. Expression of the nucleic acids results in a phenotype conversion in the transfected cell. Preferably the phenotype-converting nucleic acid is a transcriptome, and more preferably an mRNA transcriptome.

Abstract: The present invention includes methods for transferring a multigenic phenotype to a cell by transfecting, preferably by phototransfection, and locally transfecting a cell or a cellular process with a laser while the cell is bathed in a fluid medium comprising two or more nucleic acids, thereby introducing the nucleic acid into the interior of the cell. Expression of the nucleic acids results in a multigenic phenotype in the tranfected cell.

Abstract: The present invention includes methods for transferring a multigenic phenotype to a cell by transfecting, preferably by phototransfection, and locally transfecting a cell or a cellular process with a laser while the cell is bathed in a fluid medium comprising two or more nucleic acids, thereby introducing the nucleic acid into the interior of the cell. Expression of the nucleic acids results in a multigenic phenotype in the tranfected cell.

Abstract: The present invention includes methods for effecting phenotype conversion in a cell by transfecting the cell with phenotype-converting nucleic acid. Expression of the nucleic acids results in a phenotype conversion in the transfected cell. Preferably the phenotype-converting nucleic acid is a transcriptome, and more preferably an mRNA transcriptome.

Abstract: Fresh human hematopietic stem cells (HSC) obtained from umbilical cord blood, bone marrow, liver or other human tissues are directly injected into peritoneal cavity of fetal goat at 45-55 day gestation age under B-type ultrasonographic scan. Human HSC expands for up to 1000-10,000 fold in circulatory blood of recipient goats and the human HSC phenotype with non-differentiation remains stable up to over 10 months. The human cells can also grow and propagate in liver and other tissues of the recipient goats. The stored stem cells can be used for disease treatment, organ transplantation and in vivo assays of drugs.