Disclosed are a biomimic system simulating lung tissue, a method for manufacturing same, and a microfluidic control method using same, wherein the biomimic system comprises lung epithelial cells and lung fibroblasts, which are isolated from human lungs, and commercially available vascular endothelial cells, and wherein a microfluid flows through the biomimic system. Each chamber inside the corresponding system can allow a fluid, which contains gas and a medium, to flow therethrough and simulate respiration-like movement, wherein all of the three types of cells can survive inside the system even when one week or more have elapsed after through-flow of the fluid. In addition, the pH and pO.sub.2 in the chamber can be monitored by using a pH sensor and a gas partial pressure sensor inside the system, and thus the three types of cells inside the system can be exposed to external environments, drugs, and the like under the same conditions as in the lungs in vivo. Therefore, a wide range of studies including modeling of lung diseases by harmful substances and testing of therapeutic drug efficacy can be conducted, and further, the utilization to in vitro disease modeling, customized medicine prescriptions, and the like can also be made.

Provided herein are materials and methods for the preparation of blood products. In one aspect, provided herein is a composition including platelets or platelet derivatives and an aqueous medium, wherein the aqueous medium has a protein concentration less than 50% of the protein concentration of donor apheresis plasma.

A composition and a method for culturing cells. The composition includes a plurality of buoyant hollow particles, the buoyant hollow particles comprising a siliceous surface; and a plurality of mammalian cells attached to the siliceous surface of the buoyant hollow particles; wherein the buoyant hollow particles are less dense than a media; and wherein the average seeding density is 3-50 adherent cells/buoyant hollow particle.

The present disclosure relates to improved methods serum free stem cell culture, particularly 3D culture in bioreactors as well as cell culture medium and compositions for use in the same. Such methods may be particularly suitable for large scale cell manufacture.

A cell culture substrate includes: a first layer that includes a first gel in which gold nanoparticles dispersed; and a second layer that includes a second gel in which the gold nanoparticles are not present or are present in a lower concentration in comparison with the first layer.

The present invention relates to a process for producing a composition comprising an aqueous medium and, disposed in the aqueous medium, a first volume of a first hydrogel, which process comprises: (i) providing a composition comprising a first hydrophobic medium and, disposed in the first hydrophobic medium, a first volume of a first hydrogel; (ii) disposing a volume of an aqueous composition comprising a hydrogel compound around the first volume of the first hydrogel; (iii) allowing the aqueous composition comprising the hydrogel compound to form a gel and thereby forming a hydrogel object, which hydrogel object comprises the first volume of the first hydrogel and a second volume of a second hydrogel, which second volume of the second hydrogel is disposed around the first volume of the first hydrogel; and (iv) transferring the hydrogel object from the first hydrophobic medium to an aqueous medium and thereby producing the composition comprising the aqueous medium and, disposed in the aqueous medium, the first volume of the first hydrogel. The invention further provides a hydrogel object, which hydrogel object comprises a first volume of a first hydrogel and a second volume of a second hydrogel, which second volume of the second hydrogel is disposed around the first volume of the first hydrogel.

Disclosed are methods of producing organoids in the absence of any exogenous extracellular matrix or in the presence of an exogenous extracellular matrix at a concentration lower than gelling concentration, using microcontainers sealed with a hydrogel lid as well as organoids produced by this technique.

Provided are methods of controlling disassociation of cells from a carrier, compositions, and methods of collecting cells. The methods of controlling disassociation of cells from a carrier may include contacting a polymeric carrier with one or more digesting agents to disassociate at least a portion of a plurality of cells from the polymeric carrier. The polymeric carrier may be crosslinked with a crosslinker including at least one of a redox sensitive moiety, a UV light sensitive moiety, a pH sensitive moiety, and a temperature sensitive moiety.

Described herein are nanostraw well insert apparatuses (e.g., devices and systems) that include nanotubes extending through and out of a membrane so that a material can pass through the membrane from a fluid reservoir depot and into a cell grown onto the nanotubes when electrical energy (e.g., electroporation energy) is applied. In particular, the device, systems and methods described herein may be adapted for cell growth viability and transfection efficiency (e.g., >70%). These apparatuses may be readily integratable into cell culturing processes for improved transfection efficiency, intracellular transport, and cell viability.

Provided herein are materials and methods for the preparation of blood products. In one aspect, provided herein is a composition including platelets or platelet derivatives and an aqueous medium, wherein the aqueous medium has a protein concentration less than 50% of the protein concentration of donor apheresis plasma.