Abstract: A mitochondria extraction apparatus provided in the present invention includes a container used for holding a mixture fluid and a diafiltration assembly disposed in the container and used for isolating mitochondria. A basement of the mitochondria extraction apparatus is disposed in the container. During a circular motion of the mitochondria extraction apparatus, a centrifugal force in the mitochondria extraction apparatus acts on the mixture fluid in a hole-shaped microfluidic channel included in the diafiltration assembly, so as to provide a pushing force for the mixture fluid, enabling the mixture fluid to rapidly flow in the microfluidic channel for diafiltration.

Abstract: The present invention relates to a method using a cell penetrating peptide (Pep-1) for labeling and delivering mitochondria separated from healthy cells to replace damaged mitochondria. At present, microinjection of mitochondria into cells can only process one cell at a time, and therefore, this technique is limited to embryo related research and relevant applications. The advantages of the said peptide-mediated mitochondrial delivery system (PMD) include less steps with more efficiency, where a number of cells can be treated following one labeling process; the delivery process can be easily controlled, there is no cell toxicity after delivery under appropriate conditions, and delivery efficiency is over 80% depending on different cell types. Mitochondria delivered by the PMD system will move to the original mitochondrial location in the cells and will not be catalyzed in lysosomes; thus, the therapeutic effects can last at least one week.

Abstract: The present invention relates to a method using a cell penetrating peptide (Pep-1) for labeling and delivering mitochondria separated from healthy cells to replace damaged mitochondria. At present, microinjection of mitochondria into cells can only process one cell at a time, and therefore, this technique is limited to embryo related research and relevant applications. The advantages of the said peptide-mediated mitochondrial delivery system (PMD) include less steps with more efficiency, where a number of cells can be treated following one labeling process; the delivery process can be easily controlled, there is no cell toxicity after delivery under appropriate conditions, and delivery efficiency is over 80% depending on different cell types. Mitochondria delivered by the PMD system will move to the original mitochondrial location in the cells and will not be catalyzed in lysosomes; thus, the therapeutic effects can last at least one week.

Abstract: The present invention relates to a method using a cell penetrating peptide (Pep-1) for labeling and delivering mitochondria separated from healthy cells to replace damaged mitochondria. At present, microinjection of mitochondria into cells can only process one cell at a time, and therefore, this technique is limited to embryo related research and relevant applications. The advantages of the said peptide-mediated mitochondrial delivery system (PMD) include less steps with more efficiency, where a number of cells can be treated following one labeling process; the delivery process can be easily controlled, there is no cell toxicity after delivery under appropriate conditions, and delivery efficiency is over 80% depending on different cell types. Mitochondria delivered by the PMD system will move to the original mitochondrial location in the cells and will not be catalyzed in lysosomes; thus, the therapeutic effects can last at least one week.

Abstract: A method for evaluating the cure level of a stroke patient comprises following steps: (1) obtaining isolated blood sample from said stroke patient; (2) determining the concentration of serum granulocyte colony-stimulating factor (G-CSF) of said blood sample; (3) comparing the relationship between said concentration of granulocyte colony-stimulating factor (G-CSF) and the stroke severity ranking of said stroke patient; wherein United State National Institute of Health Stroke Scale (NIHSS) or modified Ranking Scale (mRS) is used in said stroke severity ranking ; and (4) Using said concentration of granulocyte colony-stimulating factor (G-CSF) to predict the possible cure level of said stroke patient. The invention further provide a prognosis biomarker for evaluating the cure level of a stroke patient, and a kit containing said prognosis biomarker.

Abstract: A method for evaluating the cure level of a stroke patient comprises following steps: (1) obtaining isolated blood sample from said stroke patient; (2) determining the concentration of serum granulocyte colony-stimulating factor (G-CSF) of said blood sample; (3) comparing the relationship between said concentration of granulocyte colony-stimulating factor (G-CSF) and the stroke severity ranking of said stroke patient; wherein United State National Institute of Health Stroke Scale (NIHSS) or modified Ranking Scale (mRS) is used in said stroke severity ranking; and (4) Using said concentration of granulocyte colony-stimulating factor (G-CSF) to predict the possible cure level of said stroke patient. The invention further provides a prognosis biomarker for evaluating the cure level of a stroke patient, and a kit containing said prognosis biomarker.