DE19849607C1 - Patient monitoring system; has workstations, each connected to sensors by medical terminals and to hierarchically superior central workstation by two inductively coupled network adapters - Google Patents

Abstract

The system has sensors (7) associated with each patient connected by at least one medical terminal (8) to a hierarchically superior medical workstation (9) forming a network node. The workstations are connected to a hierarchically superior central workstation (10) and each has associated network adapters, for connection to the medical terminal device and the central workstation. The adapters are voltage isolated and inductively coupled.

Description

The invention relates to a system for patient monitoring.

Such systems are preferably used in hospitals, around a large number of patients at the same time regarding their physiological Monitor the condition and the relevant treatment parameters and to be able to look after.

US 5,730,124 medical measuring devices, in particular for domestic patient monitoring with assigned evaluation devices. US 5,664,270 describes a central data processing device for a Patient bed for evaluating the measurement signals from several different ones Sensors for the measurement of physiological parameters.

According to EP 0 796 589 A1 and EP 0 796 590 A1, a system for patients Monitoring portable monitors for the acquisition and evaluation of measured physiological parameters and docking elements for connection to other portable monitors or with a data communication network in one Hospital.

A system for patient monitoring according to US 5,785,650 has one Data acquisition and processing unit, which by means of a cable connection with communicates with a central evaluation unit.

The system for patient monitoring presented in DE 197 47 353 A1 exists from patient terminals assigned to a patient, each with a central Data processing unit exchange data, each a patient treating person at the respective patient terminal by a Identification device must identify so that it can always be checked whether and when which treating person treated a particular patient.  

In the journal "Medical & Biological Engineering & Computing", September 1997, Pages 528 to 539, a so-called expert system for the monitoring of Patients in the field of intensive care described using the patient measured physiological parameters via a data communication network and Evaluation devices displays the evaluated data on the patient monitor.

Is the networking of different components in a system for Patient monitoring in hospitals is approved for approval by the Legislators provide evidence of security for the entire system or evidence of the separation / decoupling of individual components of the system is required.

The object of the invention is a system for patient monitoring to provide, on the one hand, flexible in terms of the number of connected Sensors is changeable and on the other hand the automatic configuration of  several medical workplaces in such a system at the same time early galvanic decoupling of those related to each patient Components of the system from the parent, for all patients of the System active components enabled.

The solution to the problem is obtained with the features of claim 1. The subclaims give advantageous designs of the system Claim 1.

A major advantage of the system according to claim 1 is the flexible Possibility to expand the number of patients used Sensors. So with an abrupt change in the state of health of patients an additional number of vital parameters by means of ent speaking sensors are detected and monitored in the system.

Here, the term “monitoring” is more general in the present application to understand and includes the terms acquisition, display, evaluation of physiological patient data and possibly also functional data of supply devices, dosing parameters for machine administration of medicinal products for treatment and similar parameters or measurands.

It is known that components of a system for electronic data processing work in different arrangements, depending on the application, ver be bound. Such an arrangement is called a network topology draws. The classification of a component in the network topology is about the configuration of the component and the existing connections defined to other components. Within the scope of the present invention is the topology of the system as a hierarchical network with two Hierarchy levels trained.

Components of the system can be clearly assigned to the hierarchy levels be classified.  

Components in the system exchange data. This data communication is subject to a protocol. The protocol is through a defined transmission sequence marked by information blocks. The sequence, size and meaning the information block is all communicating components of the system known. The protocol is here for all digital components of the system uniform in the network.

Direct communication between different patients related networks is not possible or excluded.

Communication across hierarchy boundaries is through network knot realized.

The following is an embodiment of the invention using the figures explained.

Show it

Fig. 1 shows schematically the network topology of an inventive system for patient monitoring and

Fig. 2 shows schematically the formation of a network node according to the invention in a system of FIG. 1.

The description of the system according to the invention according to FIG. 1 begins with the sensors 7 attached to the patient for measuring the physiological measurement variables relevant to a patient, which are also referred to below as vital parameters. Exemplary examples of such vital parameters are body temperature, pulse, blood pressure, respiratory rate.

The sensors 7 are the origin of the data generated in the system, and they generally output the measured values analogously. The power supply to the sensors 7 and the conversion of the analog measurement signals from the sensors 7 into digital data is carried out by means of the terminals 8 . The digital data generated in the terminals 8 as an example for a patient A or a patient B are each forwarded to a patient-related medical work station 9 via a hierarchical network. Each medical work station 9 is a network node in the hierarchical network. The first digital hierarchy level between the digital outputs of the terminals 8 and the medical workstations 9 designed as network nodes (in the case of several patients) is also referred to as the "Front End Network" (FEN). The data is generally transmitted via an electrical two-wire conductor. Alternatively, data transmission via glass fibers is also possible. At each medical work station 9 for patient monitoring, the measured values are assigned to the monitored patient and displayed.

Each medical work station 9 ( FIG. 2) consists of:

• a multitasking operating system 11 ,
• a microprocessor 12 ,
• a display 13 ,
• - manual controls 14 ,
• a permanent memory 15 ,
• a volatile working memory 16 ,
• a galvanically isolated FEN network adapter 17 ,
• - A galvanically isolated BEN network adapter 18 .

Each medical work station 9 designed as a network node generates data objects by assigning patient-specific and work station-specific data to the medical measured values. In a second digital hierarchy level, these data objects from various medical work stations 9 are brought together in a central work station 10 via a network. This second level of the hierarchical network between one or more medical work stations 9 and the central work station 10 is also called "back end network" (BEN). Each medical work station 9 is thus the interface and network node in the heterogeneous network. The separation between the FEN and BEN is implemented as a logical as well as a galvanic separation.

The system components according to the invention for monitoring patients are connected by a network for data transmission. The associated method uses a hierarchical network. FEN and BEN correspond to different hierarchy levels in the overall system. Medical workplaces 9 on the patient are designed as network nodes. The method uses a multitasking operating system 11 , in particular Windows NT®, for these medical workplaces 9 .

Each medical work station 9 is the interface between the two hierarchical levels FEN and BEN ( FIG. 2). The procedure assigns the FEN communication and the BEN communication to two separate processes. The microprocessor 12 of the network node executes the processes. The processes are separated by the multitasking operating system 11 . Execution instructions for the microprocessor 12 are stored in separate address areas of the volatile working memory 16 . Each communication process can be carried out independently. Each medical work station 9 is the interface between the two hierarchical levels FEN and BEN. The procedure assigns two separate processes to the FEN configuration and the BEN configuration. The processes are separated by the multitasking operating system 11 . To this end, the multitasking operating system 11 reserves a static address area in the volatile work memory 16 as long as the processes on the medical work stations 9 are available. The execution instructions characterizing the processes are copied from each permanent memory 15 into the associated volatile working memory 16 . The data assigned to a process are only stored in the same address area of the respective process. Each configuration process can be carried out independently. The architecture and implementation of this process do not provide for communication between these processes.

The data generated in the FEN go through at least one further process in order to be available in the BEN. Data generated in the BEN go through at least one further process in order to be available in the FEN. This further process clearly assigns a new, identical or expanded data object to each original data object that is to pass through the interface. Data of the original data object is transferred to the new data object by a transaction. This new data object is available for data transmission in the other hierarchy level. This further process, hereinafter also called the communication process, represents the logical separation of the two networks. The decoupling is achieved by the coexistence of exactly one active configuration process and exactly one passive configuration process and at least one communication process. The active configuration process here is the process when the number of connected sensors 7 is expanded, which is the origin of a dynamic configuration in a network. The passive configuration process is the process that is involved in the dynamic configuration of a network after activation by the active configuration process.

FEN network adapter 17 and BEN network adapter 18 are electrically isolated from one another, with a bidirectional inductive, electromagnetic coupling. The assembly for electrical isolation is at least part of the second, BEN network adapter 18 and optionally a second assembly is part of the first FEN network adapter 17 , and each assembly is located between the network connector and the network driver module. Each assembly consists of at least two coils in each transmission direction, which have a common coil core made of ferromagnetic material. Each module is usually designed as an integrated module.

The passive configuration process of the network node is assigned to the electronic assembly FEN network adapter 17 . The assignment is made by configuring the programming interface of the network adapter 17 or 18. The FEN and BEN are completely electrically and logically separated.

When the communication process is deleted, the data exchange across the logical interface in the medical work station 9 is completely prevented. Deleting the communication process has no effect on the availability of the FEN and the BEN. A data exchange between the two hierarchical levels at the medical work station 9 is only possible through a transaction of the communication process.

Claims (5)

1. Patient monitoring system with the following features:

• a) sensors ( 7 ) assigned to a particular patient are connected via at least one associated medical terminal ( 8 ) to exactly one hierarchically higher-level medical work station ( 9 ) designed as a network node,
• b) the medical workstations ( 9 ) of the system are connected to a hierarchically superordinate, central workstation ( 10 ) and
• c) each medical work station ( 9 ) has two assigned network adapters ( 17 , 18 ), the one network adapter ( 17 ) with the at least one assigned medical terminal ( 8 ) and the second network adapter ( 18 ) with the hierarchically superior central work station ( 10 ) and at least the second network adapter ( 18 ) is electrically isolated and inductively and electromagnetically coupled.

2. System for patient monitoring according to claim 1, characterized in that

• 1. each medical work station ( 9 ) has exactly one passive configuration process, which is assigned to the electronic assembly FEN network adapter ( 17 ) and communicates with each assigned terminal ( 8 ),
• 2. each medical work station ( 9 ) has exactly one active confi guration process, which is assigned to the electronic assembly BEN network adapter ( 18 ) and communicates with the central work station ( 10 ) and
• 3. each medical work station ( 9 ) has at least one process which assigns a new data object to each original data object and transfers the information from the original data object to the new data object, the data communication via hierarchy levels being completely interrupted when this process is deleted.

3. System for patient monitoring according to claim 1 or 2, characterized in that each medical work station ( 9 ) a multitasking operating system ( 11 ), a microprocessor ( 12 ), a display ( 13 ), manual controls ( 14 ), a permanent memory ( 15 ) and has a volatile working memory ( 16 ). 4. System for patient monitoring according to one of claims 1 to 3, characterized in that the sensors ( 7 ) are measuring sensors for vital parameters of the patients. 5. System for patient monitoring according to one of claims 1 to 4, characterized in that each medical terminal ( 8 ) has an analog-digital converter.