A biological sterilization indicator is disclosed that in some embodiments comprises a housing having a first enclosure and a second enclosure, an ampule containing a liquid growth medium, and an insert disposed at least partially in the first enclosure. A portion of the ampule may be disposed inside the first enclosure. The insert may have a platform including a top surface, an abutment surface, and a side surface, as well as a first void disposed in the platform and configured to allow passage of a first volume of the liquid growth medium into the second enclosure and a second void disposed through at least a portion of the side surface and configured to allow passage of a second volume of the liquid growth medium into the second enclosure. The second void of the insert may be an angled cut through the abutment surface and the side surface, which may be disposed entirely beneath the top surface. In some embodiments, stress concentrators and other features are included to reduce the force required to activate the biological sterilization indicator.

The invention relates to the validation of decontamination processes and in particular to new surrogate organisms and mixtures of said microorganisms used for validating the decontamination processes.

A process for determining the viability of a biological indicator includes exposing the biological indicator to a viability detection medium, the biological indicator including test microorganisms, the exposing the biological indicator to the viability detection medium producing a gaseous reaction product when one or more of the test microorganisms are viable. The presence or absence of the gaseous reaction product produced by the biological indicator combined with the viability detection medium is detected with a sensing device, the sensing device comprising a capacitive sensor, an electro-mechanical sensor, or a resistive sensor, wherein the presence of the gaseous reaction product indicates the presence of viable test microorganisms and the absence of the gaseous reaction product indicates the absence of viable test microorganisms. A sterilization detection device includes a container configured to contain the biological indicator, a viability detection medium, and the sensing device.

A biological indicator for testing the efficacy of sterilization or disinfection processes of closed environments or confined spaces, the biological indicator comprising a carrier; biological material supported on or embedded in the carrier; and a carrier container comprising a body and a cap. The carrier is fixed within an inner space of the cap, the cap being able to be placed in an open position completely exposing the carrier and the biological material to the closed environment or confined space to be disinfected. A method for determine the efficacy of a process of sterilization or disinfection of closed environments or confined spaces, preferably by means of an enzyme and a fluorescence compound, using said biological indicator.

A self-contained biological sterilization indicator is provided. The self-contained biological sterilization indicator includes an outer container having at least one liquid-impermeable wall and an interior volume; a sealed, openable, liquid-impermeable inner container enclosing a predetermined volume of an aqueous medium; a dry coating that comprises i) a plurality of viable test microorganisms useful to detect exposure to an oxidative sterilant and ii) an effective amount of a sterilant-resistance modulator; and a pathway that permits vapor communication between the interior volume and an atmosphere outside the outer container. The inner container and the dry coating are disposed in the interior volume. The modulator comprises an amino acid. The effective amount causes an increase in sensitivity of the test microorganisms to the oxidative sterilant relative to an otherwise-identical dry coating that lacks the effective amount.

An apparatus to simulate biocide performance in crude oil pipeline conditions is disclosed. The apparatus includes: a reactor to simulate a two-phase crude oil pipeline which includes a crude oil phase above a water phase. The reactor has an agitator to control a flow of the water phase in the reactor in response to a motor that drives an agitation rate of the agitator. A crude oil inlet supplies crude oil to the reactor for the crude oil phase. A water inlet supplies water to the reactor for the water phase. A control circuit is configured by code to control a proportion of the water to the crude oil supplied to the reactor and to control the motor to drive a desired agitation rate of the agitator. A biocide inlet supplies biocide to the reactor. A water sample outlet enables sampling of the water phase of the reactor.

Automated systems and methods for low-pH viral inactivation include adding an elution pool to a first vessel with an acid. Once first vessel pH probes measure sufficiently low pH, the pool is transferred to a second vessel, where the pH is checked again, and the pool is held for a time sufficient to reduce virus concentration to a safe level, and neutralized, filtered, and transferred to a third vessel. Meanwhile, the first vessel is filled with a known-pH buffer, which is checked against readings from first vessel pH probes to determine whether recalibration is needed. After the pool is transferred to the third vessel, the second vessel is filled with a knownpH buffer, which is checked against readings from second vessel pH probes to determine whether recalibration is needed. The process repeats when the known-pH buffer is dumped and a new elution pool is added to the first vessel.

A sterilization system includes a vial, a carrier of microorganisms disposed in the vial, and a fluid management system having an output connectable to the vial for delivering a liquid chemical sterilant and a neutralizer thereto. Additionally, a growth medium may be delivered to the vial such that the vial and growth medium may assessed for a change to a visual characteristic indicative of sterilization inefficacy.

A biological sterilization indicator includes a housing having a first enclosure and a second enclosure, an ampule containing a liquid growth medium, and an insert disposed at least partially in the first enclosure. A portion of the ampule may be disposed inside the first enclosure. The insert may have a platform including a top surface, an abutment surface, and a side surface, as well as a first void disposed in the platform and configured to allow passage of a first volume of the liquid growth medium into the second enclosure and a second void disposed through at least a portion of the side surface and configured to allow passage of a second volume of the liquid growth medium into the second enclosure.

A configurable device (10) for the flexible provision of connections and/or functions in a biopharmaceutical process comprises a body (20) in which predefined pipe sections (22) and plug-in locations (24) are formed by recesses in the material of the body (20). The configurable device (10) further comprises a plurality of functional elements (26) which are adapted to be inserted into the plug-in locations (24).