Provided is a temporary treatment medium for inhibiting embryo developmental arrest due to manipulation of an embryo or the like. A temporary treatment medium according to the present invention reduces damage to an in-vitro culture due to manipulation thereof, said in-vitro culture containing one of pluripotent stem cells, reproductive cells, a fertilized egg, and an embryo or any combination thereof. For this purpose, the temporary treatment medium contains a cytoskeleton regulator and/or an apoptosis inhibitor. The cytoskeleton regulator and/or the apoptosis inhibitor is preferably an Rho kinase inhibitor. Specifically, a Rock inhibitor can be used as the Rho kinase inhibitor. The Rock inhibitor is, for example, Y-27632. The temporary treatment medium is used for treating an in-vitro culture for a specific period before and/or after manipulation involving damage thereto.

The present disclosure provides multispecific antigen-binding molecules capable of binding to CD3 and CD137 (4-1BB) but not binding to CD3 and CD137 at the same time, and capable of binding to CLDN6. The multispecific antigen-binding molecules of the present disclosure exhibit enhanced T-cell dependent cytotoxicity activity in a CLDN6-dependent manner through binding to the CD3/CD37 and CLDN6. The present invention provides multi-specific antigen-binding molecules and pharmaceutical compositions thereof that can be used for targeting cells expressing CLDN6, for use in immunotherapy for treating various cancers, especially those associated with CLDN6 such as CLDN6-positive cancers.

Regimens useful in reducing the frequency of apheresis in a human patient having familial hypercholesterolemia are described. The method involves administering to the human subject via a peripheral vein by infusion of a suspension of replication deficient recombinant adeno-associated virus (rAAV).

Disclosed herein are compositions and in vitro and in vivo methods for reprogramming post-natal (adult and juvenile) tissue into insulinogenic cells. These compositions and methods are useful for a variety of purposes, including the development of diabetes therapies.

Compositions and methods are provided for creating and promoting biallelic targeted modifications to genomes within cells and for producing non-human animals comprising the modified genomes. Also provided are compositions and methods for modifying a genome within a cell that is heterozygous for an allele to become homozygous for that allele. The methods make use of Cas proteins and two or more guide RNAs that target different locations within the same genomic target locus. Also provided are methods of identifying cells with modified genomes.

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.

In order to develop tools and methods useful in a variety of applications, including the research and development of medical treatments which involve the modification of collagen protein and use of the same, the present invention provides a modified collagen protein expressed in a transformed cell and capable of forming collagen fibers outside of the cell, wherein the transformation is performed by introducing, into the cell, polynucleotides coding the modified collagen protein.

The present invention relates to a system for screening personalized anticancer agents, a method for screening personalized anticancer agents using the system, and an apparatus for screening personalized anticancer agents. When the inventive system for screening personalized anticancer agents is used, an anticancer agent showing an optimal anticancer activity against cancer cells collected from a patient can be selected from a variety of anticancer agents, and it is possible to previously examine a therapeutic response that can appear when the selected anticancer agent is administered into the patient. Thus, the risk of trial and error in cancer therapy can be reduced, and the cost and time required for cancer therapy can be reduced.

The present invention provides Factor IX fusion proteins with higher specific activity and a longer useful clotting function relative to wild type or non-modified Factor IX protein.

Residual, refractory or relapsed cancer is treated by immunostimulation in the presence of allogeneic immune effector cells, optimally in combination with radiation therapy. The methods of the disclosure induce a systemic allogeneic anti-tumor immune response that results in tumor regression in untreated sites of disease, i.e. non-injected, non-irradiated, etc.