Single use probe sterilizable by irradiation and method for the quality assurance of a single use probe

Abstract

A single use probe, sterilizable by irradiation, for a single use component for use in a biopharmaceutical process, comprises at least one sensor relevant for the biopharmaceutical process, an RFID tag and a memory rewritable in principle, in which data with respect to an integrity check of the single use probe are stored. A method for quality assurance of such a single use probe comprises: providing the probe with an RFID tag and a memory rewritable in principle, in particular a FeRAM memory as part of the RFID tag; defining a measurement-principle-specific quality parameter of the single use probe; defining a tolerance value for the parameter; performing an integrity check of the probe by first determining and writing into the memory values of the defined quality parameter before sterilization of the probe by irradiation; determining the values of the defined quality parameter after irradiation; and comparing the values of the quality parameter determined before radiation to those determined after.

Claims

1. An apparatus assembly, comprising: a single use probe, sterilizable by irradiation, for a single use component which is provided for use in a biopharmaceutical process, the single use probe comprising at least one sensor relevant for the biopharmaceutical process and/or for detecting certain events or ambient conditions, an RFID tag, and a memory rewritable in principle in which data with respect to an integrity check of the single use probe are stored; and an accumulator unit to be attached to a packaging outside the single use probe, which in a releasable way is electro-conductively connected to an electronic unit of the single use probe or to the RFID tag.

2. The apparatus assembly according to claim 1, characterized in that the memory is part of the RFID tag.

3. The apparatus assembly according to claim 1, characterized in that the memory comprises a ferroelectric random access memory chip.

4. The apparatus assembly according to claim 1, characterized in that product-relevant data are stored in the memory.

5. The apparatus assembly according to claim 1, characterized in that values of a measurement-principle-specific quality parameter of the single use probe determined before a radiation sterilization of the single use probe are stored in the memory.

6. The apparatus assembly according to claim 5, characterized in that values of the measurement-principle-specific quality parameter of the single use probe determined after a radiation sterilization of the single use probe are stored in the memory.

7. The apparatus assembly according to claim 6, characterized in that a specification of the single use probe corrected after a radiation sterilization of the single use probe is stored in the memory.

8. The apparatus assembly according to claim 1, characterized by a write protection which after activation prevents a deletion and overwriting of the data stored in the memory.

9. The apparatus assembly according to claim 8, characterized in that the memory includes a free, writable area and a blocked area that no longer is writable.

10. The apparatus assembly according to claim 1, characterized in that the RFID tag is provided with an internal battery.

11. The apparatus assembly according to claim 5, characterized in that it is a temperature probe based on ohmic resistance, whose measurement-principle-specific quality parameter is the ohmic resistance.

12. The apparatus assembly according to claim 5, characterized in that it is a pH probe based on voltammetry, whose measurement-principle-specific quality parameter is its electric potential in a defined aqueous environment.

13. The apparatus assembly according to claim 1, characterized in that the accumulator unit includes a device for wireless charging by an external energy source.

14. The apparatus assembly according to claim 1, characterized in that the accumulator unit is attached to an inner side of an outermost overwrap.

15. The apparatus assembly according to claim 1, comprising a writing device that is configured for wireless writing of data into the memory of the single use probe, and a reading device that is configured for wireless reading out of data stored in the memory.

16. The apparatus assembly according to claim 4, characterized in that the product-relevant data stored in the memory comprises one or more of a product identification code, a date of manufacture or a use-by date.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further features and advantages of the invention can be taken from the following description and from the attached drawing to which reference is made. In the drawing, the only FIGURE by way of example shows the life cycle of a single use probe according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

(2) With reference to the flow diagram shown in the Figure, a typical life cycle of a single use component with a single use probe will be described below, starting with the step 100 of manufacturing the single use component, for example a container (bag) for use in a bioreactor, and the single use probe. The single use probe includes a sensor relevant for a biopharmaceutical process and also is provided with an RFID tag (transponder) that in turn is provided with a memory rewritable in principle, in particular of the type FeRAM.

(3) In a next step 110, product-relevant data 120 are wirelessly written into the memory of the RFID tag by using a suitable writing device. The product-relevant data can comprise a product identification code, the date of manufacture and further details on the single use probe, such as calibration tables etc. The product-relevant data generally can relate to the single use probe and/or to the single use component.

(4) The single use component with the single use probe, possibly together with further SU system components, is packed in step 130 and in step 140 sterilized by irradiation, in particular by gamma irradiation, as a complete unit, i.e. including the packaging. A FeRAM memory in generally survives a sterilization by irradiation, i.e. the data stored in the memory can still be read out after the sterilization process.

(5) In step 150, the sterilized unit is collected (inventorized) and stored, before in step 160 it is shipped to a customer in due course.

(6) The one-time use of the single use component with the single use probe at the customer is represented by step 170.

(7) The outlined life cycle by no means is to be understood in a limiting sense and of course can include further steps.

(8) After the step 140 of irradiating and before the step 160 of shipment to the customer, the integrity of the single use probe can be checked at any time on the part of the manufacturer, as will yet be explained in detail below. In addition, the product-relevant data can be read out from the memory of the RFID tag at any time by means of a suitable reading device and be evaluated in connection with an inventory or quality check or the like. Finally, additional data also can wirelessly be written into the memory of the RFID tag when necessary.

(9) In the following, the performance, documentation and storage of the test or test results of a single use probe integrity check will be described more exactly. The fundamental principle of the check is a comparison of the measurement-principle-specific quality parameters of the respective type of sensor of the single use probe before and after the radiation sterilization. For this purpose, certain sensor-specific quality parameters are selected in advance for the respective type of sensor, which are regarded as suitable for the quality control after the radiation sterilization. In addition, a tolerable change of each sensor-specific quality parameter is defined according to the properties of the respective type of sensor.

(10) In a first part of the integrity check the previously defined measurement-principle-specific quality parameters of the single use probe are determined by a commonly used quality control method before the radiation sterilization. For this purpose, as far as possible, a contactless method is chosen (e.g. optical, electromagnetic-inductive or radioactive). In this case, the quality control can still be carried out when the single use component is packed already. The determined values are written into the memory of the RFID tag of the single use probe.

(11) In a second part of the integrity check the same quality parameters are determined again after the radiation sterilization, preferably again in a contactless way, so that the single use component need not be unpacked. These values then are compared with the values stored in the memory of the RFID chip, which are read out by means of a suitable reading device, and an evaluation is made. If the change of the quality parameters caused by the radiation sterilization lies within the defined tolerance, the quality parameters determined after the radiation sterilization are stored in the memory of the RFID chip as a further data set for monitoring the life cycle. Thereafter, the single use component is cleared for delivery to the customer. In case the change of the quality parameters however lies outside the defined tolerance, the single use component to which the single use probe is attached receives no clearance for delivery.

(12) As mentioned already, the second part of the integrity check can be carried out directly after the radiation sterilization and/or during the storage and/or directly before the planned delivery to a customer.

(13) Furthermore, the date of the performance of the integrity check, of the storage, the storage conditions (place, temperature, etc.) can each be written into the memory of the RFID tag as information. From these data, conclusions as to the current state can be made later on and statements can be made as to whether and possibly how long the single use probe still is suitable for the intended use.

(14) In the following, two concrete examples for the quality assurance of a single use probe will be described.

(15) In the first example, the single use probe shall be a temperature probe based on the ohmic resistance. Hence, the measurement-principle-specific quality parameter here is the ohmic resistance that is to be determined before and after the radiation sterilization at the same ambient temperature as far as possible. For example, before the radiation sterilization a resistance of 107.79 Ohm is measured at a constant temperature of 20° C. and along with the associated measurement conditions written into the memory of the RFID tag.

(16) After the radiation sterilization of the single use component by means of the temperature probe the ohmic resistance of the temperature probe is determined again at the same constant temperature. When the change of the resistance value is greater than a previously defined tolerance value, e.g. +/−0.3 Ohm, the single use component is discarded, as the zero point and the steepness as calibration parameters of the temperature probe have changed so much due to the radiation sterilization that an acceptable temperature measurement at the customer no longer is ensured.

(17) Alternatively, the temperature probe can be subjected to further measurements at other temperatures in order to newly determine the changed zero point and the changed steepness of the single use probe and store it in the memory of the RFID tag. For example, the single use component can be brought to a constant temperature of 5° C. and a constant temperature of 45° C. by means of the temperature probe, and the resistance of the temperature probe at these temperatures can each be measured. The specification of the temperature probe can thereby be corrected and the temperature probe with the corrected specification can be delivered to a customer.

(18) To provide for a contactless measurement of the ohmic resistance, a digital temperature probe can be equipped with a coil for an inductive voltage transmission. From the determinable consumed electric power of the voltage source the ohmic resistance of the temperature probe is inferred.

(19) In the second example, the single use probe shall be a pH probe based on voltammetry. The measurement-principle-specific quality parameter in this case is the electric potential of the pH probe in a defined aqueous environment, which shall be determined before and after the radiation sterilization. For a better understanding it should be noted that the pH probe based on voltammetry must be stored in a potassium chloride solution (KCl) in order to avoid the desiccation of the electrolyte in the probe. In a pH probe, the KCl dissolved in pure water causes an electric potential of 0 mV. On the condition of the storage with such a defined KCl solution, the electric potential therefore can be used as a quality parameter for the pH probe.

(20) For example, before the radiation sterilization an electric potential of the pH probe of 0 mV is measured and along with the associated measurement conditions written into the memory of the RFID tag. After the radiation sterilization of the single use component with the pH probe, the electric potential of the pH probe is again determined under the same measurement conditions. When the change of the electric potential is greater than a previously defined tolerance value, e.g. +/−0.4 mV, the single use component is discarded, as the zero point and the steepness as calibration parameters of the temperature probe have changed so much due to the radiation sterilization that an acceptable measurement of the pH value at the customer no longer is ensured.

(21) Similar to the first example, it is possible in principle under certain conditions to correct the specification of the pH probe with reference to the measurement value determined after the radiation sterilization and possibly further measurement values and to deliver the pH probe with a corrected specification to a customer.

(22) To provide for a contactless measurement of the electric potential, commonly used electromagnetic-inductive methods can be employed.

(23) Before shipment to the customer a write protection of the memory can be activated in the RFID tag in order to protect from manipulations or inadvertent deletion of data that are stored in the memory. It thereby is ensured that the correct data are permanently available.

(24) The customer can read out the product-relevant data and the calibration information when necessary and correspondingly use the same for his purposes.

(25) Optionally, the single use probe can additionally be equipped with a battery arranged in the RFID tag, which at best is partly damaged by irradiation with gamma rays or other rays used for sterilization. The battery in particular serves to supply an electronic unit required for the proper operation of the single use probe with electricity so that the sensor of the single use probe can be used properly and measurement data possibly can be written into the memory when no electricity is available from outside via cables or cableless systems.

(26) In addition, the single use probe can be completed by a rechargeable electric energy source (accumulator). An accumulator unit electroconductively connected to the electronic unit of the single use probe or its RFID tag via a cable or the like is attached for example to the inner side of a carton of an outermost overwrap of the single use component and is provided with a device for wireless charging, such as a suitable near field communication (NFC) antenna. Thus, if necessary, the accumulator unit can be charged in a contactless way by a suitable external energy source.

(27) The use of such an accumulator unit allows to document relevant events and ambient conditions in the history of the single use probe in the memory of the RFID tag over time, in particular before a delivery to a customer. This requires that the single use probe be provided with one or more suitable sensors for detecting the events and/or ambient conditions, such as a temperature sensor, a humidity sensor and/or a radiation sensor.

(28) Upon completion or at a later time before the radiation sterilization the accumulator unit is charged. From this time, the relevant events such as the radiation itself and the radiation dose as well as the ambient temperature and room humidity can be determined in regular or irregular intervals and be written into the memory of the single use probe. These data can be read out in a contactless way at any time by means of a suitable reading device.

(29) Due to the radiation sterilization the accumulator unit can however suffer a partial damage, which leads to a complete or partial discharge. If the energy of the accumulator unit no longer is sufficient for said tasks, this point in time is documented, i.e. written into the memory, and the internal battery of the RFID tag takes over the further power supply.

(30) Owing to the device for wireless charging it is possible in principle, if necessary, to again charge the accumulator in a contactless way from outside by an external energy source after the radiation sterilization, as is shown in the Figure by step 180. Possibly, the frequency of storing and reading out the stored sensor data can also be decreased or adapted in order to ensure the coverage of a desired minimum period of time.

(31) The electrically conductive connection between the RFID tag or the electronic unit of the single use probe and the accumulator unit ideally is designed such that upon opening of the overwrap, upon removal of the content of the overwrap (single use component) or in the case of a defined concussion, the line is interrupted. The internal battery of the RFID tag then takes over the further energy supply. The time of the interruption is documented, i.e. written into the memory, and can be interpreted as an indication that the single use probe is unpacked and utilized or that the integrity of the single use probe no longer is given.