Described herein are methods and related compositions for inducing differentiation of human pluripotent stem cells (hPSCs) into hemogenic endothelium with pan-myeloid potential or restricted potential, by forced expression in the hPSCs of a combination of transcription factors as described herein.

Non-human animal cells and non-human animals comprising a humanized Asgr1 locus and methods of using such non-human animal cells and non-human animals are provided. Non-human animal cells or non-human animals comprising a humanized Asgr1 locus express a human ASGR1 protein or an Asgr1 protein, fragments of which are from human ASGR1. Methods are provided for using such non-human animals comprising a humanized Asgr1 locus to assess in vivo efficacy of human-ASGR1-mediated delivery of therapeutic molecules or therapeutic complexes to the liver and to assess the efficacy of therapeutic molecules or therapeutic complexes acting via human-ASGR1-mediated mechanisms.

Described herein are methods and related compositions for inducing differentiation of human pluripotent stem cells (hPSCs) into hemogenic endothelium with pan-myeloid potential or restricted potential, by forced expression in the hPSCs of a combination of transcription factors as described herein.

The present invention relates, inter alia, to processes for making modified fish zygotes or early-stage fish embryos (particularly salmon zygotes and salmon embryos). The invention also provides fish zygotes, fish embryos, juvenile fish, mature fish and sterile fish which are produced by the processes of the invention.

A urine-derived mesenchymal stem cell mitochondria as well as a transplantation method and use thereof. The urine-derived mesenchymal stem cell mitochondrion is extracted from urine to be used for improving the quality of oocytes. The transplantation method comprises: jointly injecting sperms and the urine-derived mesenchymal stem cell mitochondria into mature oocytes for blastaea culture during the intracytoplasmic sperm microinjection. The present disclosure has the beneficial effects: during the traditional ICSI in combination with the transplantation of the urine-derived mesenchymal stem cell mitochondria, the fertilization rate of human in-vitro fertilization and the quality of embryos are significantly improved; the urine-derived mesenchymal stem cell mitochondria of the present disclosure can be used for in-vitro fertilization of low-prognosis patients with infertility with a good treatment effect; the problem of an autologous mitochondrion source in the prior art is solved without involving the introduction of a third-party genetic material and ethical issues.

A method of producing the constituents of a therapeutic product from mammalian cells is described herein. Cells are isolated from a mammalian source. The cells are exposed to supercritical carbon dioxide (SCCO.sub.2) for 1 to 30 minutes, where the SCCO.sub.2 is maintained at a pressure of 1071 pounds per square inch (PSI) and a temperature of 31.1 to 45 degrees Celsius during the exposure. The exposure dissociates the cellular membranes of the cells to release intramembrane components therein to produce constituents of the therapeutic product. The mammalian cells may include at least one of platelets, stem cells, germ cells, and somatic cells. The methods described herein are particularly advantageous for releasing and capturing therapeutic intramembrane components from platelets and alpha-granules.

Described herein are methods and related compositions for inducing differentiation of human pluripotent stem cells (hPSCs) into hemogenic endothelium with pan-myeloid potential or restricted potential, by forced expression in the hPSCs of a combination of transcription factors as described herein.

The method for automated cell positioning can include: sampling a video of a scene having a gamete, tracking the gamete, and positioning the gamete within a target region. The method can optionally include: determining attribute values for the gamete, selecting the gamete, reorienting the gamete, and/or manipulating the gamete, and/or any suitable steps.

Disclosed are methods and compositions for in situ germline genome engineering. The disclosed methods and compositions may be utilized for germline genome engineering in a subject having a reproductive organ containing a fertilized zygote, via: (i) isolating or obtaining the reproductive organ from the subject after a time period following insemination of the subject; (ii) introducing a reagent composition into the reproductive organ, the reagent composition comprising a nuclease system and/or an exogeneous polynucleotide; and (iii) electroporating the reproductive organ.

An embryo, gamete or stem cell culture medium comprising: a) acetyl-carnitine at a concentration of about 5 to about 50 μM; and b) lipoic acid or a derivative thereof at a concentration of about 2.5 to about 40 μM. The culture medium may optionally further comprises acetyl-cysteine at a concentration of about 5 to about 50 μM.