The invention relates to a method for in vitro characterization of a eukaryote biological microtissue by imaging by means of a phase measurement technique without a reference beam, and the use of this method in vitro characterization in particular for: monitoring the quality of a microtissue, measuring the increase of the biomass of a microtissue during its growth and/or its amplification following the differentiation and/or the organization of a microtissue during its maturation, determining the phenotype of cells of the microtissue, and/or confirming the absence of non-differentiated cells in the microtissue.

A device for treatment of cells with particles is disclosed. The device includes a semi-permeable membrane positioned between two plates, the first plate defining a first flow chamber and comprising a port, a flow channel, a transverse port, and a transverse flow channel, the first flow chamber constructed and arranged to deliver fluid in a transverse direction along the first side of the semi-permeable membrane, the second plate defining a second flow chamber and comprising a port. A method for transducing cells is disclosed. The method includes introducing a fluid with cells and viral particles into a flow chamber adjacent a semi-permeable membrane such that the cells and the viral particles are substantially evenly distributed on the semi-permeable membrane. The method also includes introducing a recovery fluid to suspend the cells and the viral particles, and separating the cells from the viral particles. A method of activating cells is disclosed.

A biological tissue forming device that ensures a cell-cell interaction and an exchange of liquid components between cell layers of a formed biological tissues with high efficiency can be provided. A biological tissue forming device for forming a biological tissue having a plurality of cell layers formed of adherent cells has both surfaces on which culture regions of the adherent cells are disposed, and includes a culture membrane arranged between the plurality of cell layers after the adherent cells are cultured and a plurality of flow passages divided by the culture membrane. The culture membrane is formed of a readily-soluble material.

Filter holders and membranes are provided that can be included within a bioreactor bag system. The filter holders and membranes include features that abut the bottom of the filter membrane and prevent or reduce sagging of the porous filter region during use.

The apparatuses described herein relate to preparation of a meat product. Apparatuses, systems comprising the apparatuses, and methods of making and use the systems and apparatuses are described herein. These are useful for controlling one or more of growth on and separation of a meat product from an enclosed substrate. The apparatuses and systems are configured to receive fluid and grow the meat product and/or separate the meat product from the substrate in a scalable manner.

The bioreactor can use a number of different culture growing structures for culturing cells including a lattice structure and a support matrix structure. The culture growing structure whether it be a support matrix using wicking and/or a lattice structure may be coated with a thermal responsive polymer. The material of interest growing on the culture growing structure can be removed by changing the temperature that the thermal responsive polymer on the surface of the culture growing structure is exposed to and thus in some cases release the thermal responsive polymer along with the material of interest from the remainder of the culture growing structure.

A device for simulating a function of a tissue includes a first structure, a second structure, and a membrane. The first structure defines a first chamber. The first chamber includes a matrix disposed therein and an opened region. The second structure defines a second chamber. The membrane is located at an interface region between the first chamber and the second chamber. The membrane includes a first side facing toward the first chamber and a second side facing toward the second chamber. The membrane separates the first chamber from the second chamber.

Provided herein relates to devices for simulating a function of a tissue and methods of using the same. In some embodiments, the devices can be used to simulate a function of a human liver tissue. In some embodiments, the devices can be used to simulate a function of a dog liver tissue. Endothelial cell culture media for long-term culture of endothelial cells are also described herein.

The disclosure relates to bioreactors, for example for biological treatment and, more specifically to bioreactor insert apparatus including biofilms and related methods. The bioreactor insert apparatus provides a means for circulation of reaction medium within the bioreactor, a biofilm support, and biological treatment of an inlet feed to die reactor/insert apparatus. The bioreactor insert apparatus has a high relative surface area for biofilm attachment and is capable of generating complex flow patterns and increasing treatment efficiency/biological conversion activity in a biologically-active reactor. The high surface area structure incorporates multiple biofilm support structures such as meshes at inlet and outlet portions of the structure. The biofilm support structures and biofilms thereon can increase overall reaction rate of the bioreactor and/or perform some solid/liquid separation in the treatment of the wastewater or other influent.

Described herein is a human, cardiovascular platform for assessing cardiotoxicity of novel/existing chemotherapeutic agents that takes advantage of microfluidic organ chip systems to examine interaction between hiPSC-derived cardiovascular cells in an integrated system. Human induced pluripotent stem cell derived cardiomyocytes (hiPSC-CMs) and human induced pluripotent stem cell derived endothelial cells (hiPSC-ECs) can serve as an in-vitro platform for assessing disease pathology, including infectious disease, evaluate drug efficacy, toxicity, cardiotoxicity and cardioprotection. This includes evaluating VEGFR2/PDGFR-inhibiting tyrosine kinase inhibitors and drug efficacy in a viral infection model, including coronaviruses. They are scalable, functionally-active cell types that mimic the cells comprising the myocardium and systemic vasculature.