Abstract: A pulsatile perfusion bioreactor for culturing one or more engineered blood vessels having a lumen and a wall is provided. The bioreactor includes a chamber for holding the engineered blood vessel and cell culture media; a mechanical property monitoring system for measuring axial tensile stress and strain, circumferential tensile stress and strain, and/or shear stress imparted on the vessel wall; and a pump system for delivering cell culture media through the vessel lumen, wherein the vessel is exposed to a composite pressure waveform and a composite flow waveform as the media is delivered there through. The pump system includes a steady flow and peristaltic pumps. Further, the composite pressure and flow waveforms each include a mean component, a fundamental frequency component, and a second harmonic frequency component. The bioreactor also includes a computer interface for monitoring and adjusting the composite waveforms to maintain a predetermined stress level.

Abstract: A pulsatile perfusion bioreactor for culturing one or more engineered blood vessels having a lumen and a wall is provided. The bioreactor includes a chamber for holding the engineered blood vessel and cell culture media; a mechanical property monitoring system for measuring axial tensile stress and strain, circumferential tensile stress and strain, and/or shear stress imparted on the vessel wall; and a pump system for delivering cell culture media through the vessel lumen, wherein the vessel is exposed to a composite pressure waveform and a composite flow waveform as the media is delivered there through. The pump system includes a steady flow and peristaltic pumps. Further, the composite pressure and flow waveforms each include a mean component, a fundamental frequency component, and a second harmonic frequency component. The bioreactor also includes a computer interface for monitoring and adjusting the composite waveforms to maintain a predetermined stress level.

Abstract: A pulsatile perfusion bioreactor for culturing one or more engineered blood vessels having a lumen and a wall is provided. The bioreactor includes a chamber for holding the engineered blood vessel and cell culture media; a mechanical property monitoring system for measuring axial tensile stress and strain, circumferential tensile stress and strain, and/or shear stress imparted on the vessel wall; and a pump system for delivering cell culture media through the vessel lumen, wherein the vessel is exposed to a composite pressure waveform and a composite flow waveform as the media is delivered there through. The pump system includes a steady flow and peristaltic pumps. Further, the composite pressure and flow waveforms each include a mean component, a fundamental frequency component, and a second harmonic frequency component. The bioreactor also includes a computer interface for monitoring and adjusting the composite waveforms to maintain a predetermined stress levels.

Abstract: A pulsatile perfusion bioreactor for culturing one or more engineered blood vessels having a lumen and a wall is provided. The bioreactor includes a chamber for holding the engineered blood vessel and cell culture media; a mechanical property monitoring system for measuring axial tensile stress and strain, circumferential tensile stress and strain, and/or shear stress imparted on the vessel wall; and a pump system for delivering cell culture media through the vessel lumen, wherein the vessel is exposed to a composite pressure waveform and a composite flow waveform as the media is delivered there through. The pump system includes a steady flow and peristaltic pumps. Further, the composite pressure and flow waveforms each include a mean component, a fundamental frequency component, and a second harmonic frequency component. The bioreactor also includes a computer interface for monitoring and adjusting the composite waveforms to maintain a predetermined stress levels.

Abstract: A modular fluid unit for cooling heat sources located on a rack, the modular fluid unit comprising: a heat exchanger in fluid communication a pump; and wherein the modular fluid unit is mountable within the rack and is configurable to be in fluid communication with a cold plate return manifold, a cold plate supply manifold, and an end-user fluid supply. A method for cooling electronic components in a rack, the method comprising: circulating a first liquid from a cold plate to one of a plurality of heat exchangers mounted within the rack; circulating a second liquid from a second liquid supply to the one of a plurality of heat exchangers; and transferring heat from the first liquid to the second liquid at the one of a plurality of heat exchangers.