Disclosed are an in-vitro cardiopulmonary combined perfusion system and perfusion method. The in-vitro cardiopulmonary combined perfusion system includes an organ cabin, a circulation cabin, a control cabin, a simple breathing cabin, a display and control panel, and a base. The organ cabin is connected with the circulation cabin, the control cabin and the simple breathing cabin. The control cabin is connected with the display and control panel. The organ cabin, the circulation cabin, the control cabin, the simple breathing cabin, and the display and control panel are mounted on the base.

Biological tissue is packaged to be regenerated before grafting in a vial sealed under vacuum and comprising a biological tissue matrix. A method for producing said vial includes placing a treated ex-vivo tissue sample in an open rigid vial and placing the vial in a lyophilizer. A lyophilization process is performed under vacuum to convert the treated ex-vivo tissue sample into a biological tissue matrix. The vial is hermetically sealed with closing means, inside the lyophilizer under vacuum. The sealed vial is then removed from the lyophilizer.

A lyophilization nest and method of using the same is described herein. In various embodiments, the lyophilization nest includes a base and first and second covers and is configured to support one or more receptacles each supporting one or more substances within interior spaces of the lyophilization nest. The interior spaces may be in fluid communication with the exterior of the lyophilization nest through one or more vent holes extending through the first and second covers. Each of the one or more vent holes have a corresponding sealing element configured to selectively form an air-tight seal within the vent holes, such that a controlled environment may be maintained within the interior spaces when the ambient conditions surrounding the lyophilization nest are not lyophilization conditions. The one or more sealing elements may be operable while the lyophilization nest is positioned within a sealed lyophilizer by depressing the sealing elements into corresponding vent holes to form the air-tight seal.

Methods are disclosed for viable preservation of biomaterials including both prokaryotic and eukaryotic cells/materials such as human cells and tissues at subzero and suprazero temperatures. One embodiment provides a method wherein initial desiccation and subsequent cooling of the biological samples is below their glass transition temperature (Tg) to achieve a stable glassy state without exposing the biomaterials to excessive osmotic/chemical stresses for long periods of time. Another embodiment provides a method that includes combining the initial desiccation with subsequent freeze-drying to achieve a glassy state of biomaterials. Another embodiment provides a desiccation medium with low salt, high osmolyte/glass former content and desiccation of biomaterials in a spherical droplet to avoid the edge effect.

Provided is a loading tray assembly for housing a lyophilization container and a related system and method. The loading tray assembly includes a chassis including a contact void configured to facilitate direct contact between the attached lyophilization container and a lyophilizer shelf. The method includes securing a multi-part lyophilization container including a peelable seal on a lyophilization loading tray assembly, inputting a liquid into a non-breathable section of the lyophilization container, loading the tray assembly into a lyophilizer, freezing the liquid, applying heat energy and a vacuum, the vacuum causing an opening of the peelable seal and occluding the lyophilization container to isolate the frozen liquid.

Disclosed are an in-vitro cardiopulmonary combined perfusion system and perfusion method. The in-vitro cardiopulmonary combined perfusion system includes an organ cabin, a circulation cabin, a control cabin, a simple breathing cabin, a display and control panel, and a base. The organ cabin is connected with the circulation cabin, the control cabin and the simple breathing cabin. The control cabin is connected with the display and control panel. The organ cabin, the circulation cabin, the control cabin, the simple breathing cabin, and the display and control panel are mounted on the base.

The present disclosure provides methods of improving microbe viability after preservation comprising subjecting a population of target microbial cells to one or more preservation challenges and preparing a product using the population of preserved viability-enhanced microbial cells produced from said methods. The present disclosure further provides products comprising preserved viability-enhanced microbial cells produced by the methods described herein.

A method of making infused bone fibers employs the following steps: cutting or shaving whole bone into bone fibers, washing the bone fibers, demineralizing or decalcifying at least partially the whole bone or bone fibers and infusing the bone fibers with a supernatant of biologic material or a polyampholyte cryoprotectant or a combination of both to create infused bone fibers. The step of infusing includes exposing the bone fibers to a negative pressure or vacuum to draw the supernatant and/or the polyampholyte cryoprotectant into the bone fibers, or alternatively, exposing the demineralized whole bone to a positive pressure to drive the supernatant and/or the polyampholyte cryoprotectant into the bone. The resultant method creates an infused bone grafting composition having bone fibers taken from whole bone, demineralized or decalcified at least partially and infused with one or more of a supernatant of biologic material or a polyampholyte cryoprotectant or both.

A method for platelet preservation comprising placing a composition comprising platelets in a gas mixture comprising xenon and oxygen under pressure of about 0-10 Bars at a first temperature of about 18° C.-37° C. for a first period of time, and then subsequently cooling the composition to a second temperature of about 0,1° C.-6° C., and holding the composition under the pressure and in the second temperature for a second period of time.