EP0928155A1

EP0928155A1 - Monitoring system for the regular intake of a medicament

Info

Publication number: EP0928155A1
Application number: EP97936601A
Authority: EP
Inventors: Hans-Georg Batz
Original assignee: Roche Diagnostics GmbH
Current assignee: Roche Diagnostics GmbH
Priority date: 1996-08-16
Filing date: 1997-08-01
Publication date: 1999-07-14
Also published as: US6081734A; WO1998007364A1; DE19780856D2; JP2000516504A

Abstract

A monitoring system that checks the regular intake of a medicament by a patient. The system presents, as inter-coordinated components, a presentation form (1) of the medicament and a detector device (2) for non-invasive detection of a substance to be detected contained in the presentation form in the body of the patient (3). The detection device (2) is designed to enable direct reagent-free measurement of a physically measurable parameter correlating to the presence of the substance to be detected in the body of the patient.

Description

Control system for monitoring the regular intake of a drug

The invention relates to a control system for monitoring the regular intake of a drug in a patient and a pharmaceutical dosage form for such a control system.

The regular use of a drug is often of great importance for its effectiveness. With antibiotics, for example, an early termination leads to a new outbreak of the disease or to the development of resistance. Nevertheless, it often happens that medicines are not taken evenly according to the prescription or the intake is stopped too early. For this reason, in the case of some therapies that require regular medication use (e.g. TBC, HIV and other serious infectious diseases), the patient must be hospitalized in order to ensure regular administration of the drug through personal monitoring. A Such inpatient treatment, which is only used to control the intake of medication, can have disadvantages for the recovery process and leads to very high costs.

There is therefore an urgent need for a way to reliably control the regular intake of medication at a reasonable cost. A solution to this problem is not yet known. With some drug therapies to set the optimal active concentration, analytical tests of the concentration of the drug in the blood are sometimes carried out (so-called "drug tests"). However, such analytical methods are only available for a few medications and require a blood sample and a relatively complex analysis method for each examination. A control in the sense that the patient monitors himself or the doctor can check the regular medication intake without the patient's involvement is not achieved with drug tests.

To solve this problem, the invention proposes a control system which, as coordinated system components, comprises a dosage form of the medicament and a detection device for the non-invasive detection of a substance contained in the dosage form (hereinafter "detection substance") in the patient's body. The detection device is designed for the reagent-free direct measurement of a measured variable correlating with the presence of the detection substance in the patient's body.

In the most general form of the invention, the detection substance can be formed by the medicament itself, ie the therapeutically active substance. This is however, limited to cases in which the active substance is non-invasively detectable. Almost all chemotherapeutic agents have characteristic IR bands that can be used for a determination. Examples include: antibiotics such as tetracyclines, nitrofurones and nalidixic acid, the tuberculosis agents rifampicin and isonicotinic acid hydrazide, the antimalarial agent chloroquine, but also anticoagulants such as maramar and cardiovascular agents such as nitroglycerin and digoxin, which enable non-invasive detection.

In other cases, the typical IR bands are overlaid by the bands of the body's own substances. In such cases or when the concentration of the active substance is too low, a preferred embodiment of the invention is used, in which the non-invasively detectable substance contained in the dosage form is a non-toxic marking substance different from the medicament (active substance). The marking substance is specifically chosen so that it does not impair the pharmaceutical effectiveness of the active pharmaceutical ingredient on the one hand and also does not cause any negative effects in the patient's body (preferably it behaves inertly in the body) and on the other hand its presence in the patient's body is easily detectable. It is possible to optimize the labeling substance, particularly from the point of view of easy detection. According to a preferred embodiment of the invention, a toxic activity which is harmful to the body can, if necessary, be eliminated by encapsulation or incorporation into a macromolecular protective molecule structure, in particular a protective molecule from the group of the Dendri ere or Fullvalene. The invention is explained in more detail below with the use of a separate marking substance. However, this is not intended to limit the generality - for cases in which the active substance itself has the properties of a suitable detection substance.

Very different physically measurable quantities can serve as a measurement quantity. Examples are the intensity, the frequency or the phase position of an electromagnetic radiation (in particular of light in the IR range or also in the visible range), the intensity, frequency or phase position of a sound signal or the intensity or polarity of a magnetic field. It is crucial that the measured variable is influenced in a measurable manner by the presence of the marker substance in the patient's body, so that a change in the concentration of the marker substance associated with the use of the medicament can be detected with the aid of the measured variable by the detection device. Such a measured variable is referred to below as "parameter" in accordance with a term commonly used in the English language ("quantifiable parameter").

In the case of the invention, it is generally not necessary to quantitatively determine the concentration of the marking substance in the patient's body. Rather, the detection device preferably has means for determining the change in the parameter over time. Such electronic means for differentiating or for forming difference quotients from a measurement signal are known. An increase or decrease in the parameter measurement signal is preferably used as an indication of the intake of the medicament, ie an output signal corresponding to the "detection" of the labeling substance is generated when the parameter rameter measurement signal with a minimum change rate predetermined as a limit value increases or decreases.

The invention is suitable for a wide variety of pharmaceutical dosage forms. It is of particular importance for oral administration (tablets, capsules and the like), but it can also be used for other dosage forms, such as suppositories or injections, insofar as monitoring of the regular administration of the medication is necessary. Of course, the marking substance must be brought into a galenical form suitable for the respective dosage form.

As mentioned, the invention can have different mechanisms of action, i.e. on the basis of very different interactions between the marking substance and the detection device. Some preferred examples are explained below.

In a first embodiment, the marking substance has dye properties, preferably in the IR region of the light spectrum. A detection device tuned to this radiates light of the appropriate wavelength through the skin into the patient's body and measures the light emerging from the body after interaction with the constituents contained therein (and thus also with the marking substance). The system components are expediently coordinated with one another in such a way that a possible high intensity of the incident light lies in a spectral range in which the marking substance has an absorption maximum. This wavelength is preferably chosen so that it is outside the absorption maxima of optically absorbing substances contained in the patient's body (in particular in his skin) in high concentration Substances lie, especially outside the absorption bands of water and hemoglobin.

In addition to the choice of the labeling substance and the associated detection wavelength, previously known methods for the detection of components in the body, in particular in human skin, can be used. Such methods are known in particular for the non-invasive analysis of the analytes essential for the oxygenation balance of humans (hemoglobin, deoxyhemoglobin and cytochrome a and a ^). Reference is made, for example, to US Pat. No. 5,028,787 (Rosenthal et al.) With numerous references to previous publications and US Pat. No. 5,285,783 (Secker).

With such IR detection methods, the light is usually irradiated in several wavelengths and the spectral dependence of the measured parameter of the light is used to detect the substance sought. In the case of the present invention, too, preferably several wavelengths are used in order to detect the marking substance spectroscopically.

A particularly suitable mechanism of action is based on the use of a fluorescent dye as a labeling substance, the detection device being designed for in vivo detection of the fluorescence. For this purpose, it radiates light, the wavelength of which corresponds to the absorption wavelength of the fluorescent dye, into the patient's body. Lasers are particularly suitable as the light source for this. The resulting fluorescence radiation is detected in a wavelength-selective manner. Fluorescent dyes are preferably used which emit in the long-wave range of visible light and in the near infrared. Wavelengths are particularly preferred. lengths between about 600 nm and about 800 nm. Despite the low intensity of the emitted fluorescent light, this action mechanism proves to be particularly suitable for the purposes of the invention, because the superimposition of the useful signal with interference signals is relatively small and therefore a good comparison with other methods Signal / noise ratio results.

In some previously known methods for the non-invasive detection of the analyte in the human body, which are also suitable for the present invention, light is radiated into the body at different irradiation sites and / or light emerging from the skin at different detection sites is detected so that the light is reflected different ways from the respective irradiation site to the detection site. The measurement signals measured for the different light paths are further processed to the desired analytical information. The aim of this procedure is to target the analysis to specific layers within the skin tissue. Such a method is described, for example, in US Pat. No. 4,867,557 (Takatani) and in US Pat. No. 5,057,695 (Hirao).

In another known method of non-invasive analysis, so-called "frequency domain spectroscopic measurements" are carried out, in which the incident light is modulated with a radio frequency. The frequency shift or the degree of modulation of the detected light in relation to the incident light is used as a parameter correlating with the presence of the analyte. Reference is made to Chance's US Pat. No. 5,187,672, the publications cited therein, and WO 95/32 416. Such a procedure can also be used advantageously in the context of the present invention.

Suitable labeling substances can be, for example, molecules that have been developed as marker molecules for diagnostic purposes. Examples include:

Fluorescent labeling substances, in particular fluorescein and fluorescent metal complex compounds, as are mentioned in WO 96/03410.

Detection substances developed for immunological detection methods and DNA diagnostics, as mentioned in WO 96/03650.

Absorption or fluorescent dyes, for example according to EP-B-0567 622.

Under certain circumstances, ferromagnetic microparticles, the magnetic effect of which can be detected through the skin, can also be used as the marking substance.

Electromagnetic radiation with a wavelength outside the spectrum of light, preferably in the radio and microwave range, can also be used as a probe for detecting the presence of a labeling substance in the patient's body. In this case, substances with diode properties can in particular be used as the marking substance. Details of this are described in WO 92/15 013. The marking substance has a pn junction which causes a diode behavior, ie in the electric field the substance is conductive in one field direction, while it has a high resistance in the other field direction. Such semiconductor diodes can be manufactured in micro-miniaturized form so that they act as marking sub- are generally suitable in a medication. The detection is carried out by influencing a high-frequency signal, preferably in the MHz range, as explained in the aforementioned WO 92/15 013.

The invention is explained in more detail below with reference to the figures, in which an embodiment of the invention is shown; show it:

1 is a schematic representation of the system components,

Fig. 2 is a block diagram of a detection device and an external interrogation unit and

Fig. 3 is a graphical representation of a spectrum in an embodiment of the invention.

The control system consists of a pharmaceutical dosage form 1 (here a tablet) which contains a marking substance symbolically identified by an asterisk and a detection device 2 which, in the preferred embodiment shown, is designed as a wristwatch worn by the patient 3. Such a detection device, which is usually in the form of a device worn on the body, fulfills its control function in an inconspicuous manner that is not burdensome for the patient. In general, the control device should be so small and light that it can be carried easily.

The essential components of the detection device 2 are shown in the form of a block diagram in FIG. It contains irradiation and detection means 4 and 5, for example in the form of light-emitting diodes and semiconductor light receivers. The signals of the detection means are transmitted through a measuring and evaluation circuit 6 (for example processed by means of one of the methods described in the cited publications) into data on the presence of the marking substance in the body of the patient 3. A time measuring device 9 is provided in order to query the measuring time and also to store it in the memory 8.

In comparison to the previously known methods for the non-invasive analysis of substances in the human body, the detection device can be constructed relatively simply because no absolute concentration has to be determined. It is sufficient to demonstrate the increase in the concentration of the labeling substance associated with the drug intake. This can be done in terms of measurement technology, for example by means of a threshold value or (preferably) by determining the change in the parameter over time (i.e. formation of the first derivative of the measurement signal). Complex calibration procedures are not necessary.

The data stored in the memory 8 can be further processed in the usual manner by the microprocessor-controlled measuring and evaluation unit. In particular, this can contain a program by which control measurements are initiated at certain predetermined times (for example once a day) in order to check whether the Patient has taken the medication and therefore evidence of the medication is possible. The program can also provide that in the event of a negative result of the check, a warning signal is generated by which an acoustic signal generator 11 is activated in order to inform the patient of the medication being taken. This can be varied in different ways. For example, it can be provided to remind the patient of the medication in each case by a tone without prior checking and to check the ingestion within a defined period afterwards by detecting the marking substance with the aid of the detection device 2.

In order to facilitate long-term control of the regular intake by the patient himself and / or by the attending doctor, it is provided that the data on the detection of the marking substance and on the measuring times are transmitted from the detection device 2 to an external interrogation unit 12. This external interrogation unit can be with the patient himself or with the doctor. Of course, the same or different query units can also be available to the doctor and the patient. In general, the detection device 2 and the interrogation unit 12 should be designed such that the patient cannot delete or manipulate the data on the detection of the marking substance.

In the preferred embodiment shown, the data is transmitted wirelessly from the detection device 2 to the external interrogation unit 12, the detection device 2 having a transmitter 13 and the interrogation unit 12 having a receiver 14, and the transmission being carried out, for example, with infrared rays or with FM radio signals . Alternatively, a data interface for wired transmission can also be provided on the detection device 2, to which the external interrogation unit 12 is connected from time to time by means of a cable.

An animal experiment was carried out to test the detectability of a suitable labeling substance in vivo. Mice became the FDA approved

Food dye Brilliant Blue FCF lined. The Fluorescence of this fluorescent dye was measured in vivo in the ears of the mice. The excitation was carried out using a helium-neon laser with a power of approximately 1.5 mW and a wavelength of 632.8 nm. The fluorescent radiation was recorded with a fiber optic on the ear of the mice and focused on the emission monochromator of a fluorescence spectrometer. The resulting spectrum, normalized to the maximum value, is shown in FIG. 3, the intensity I (in each case based on the maximum value) being plotted against the wavelength in nm. The measurement curve 16 shows the result of the in vivo measurements on the ear (measurement points as triangles). For comparison, the measurement curve 17 shows the results of an in vitro measurement of the spectrum of the dye, likewise normalized to the maximum value, using the same spectrometer. It can be seen that the in vivo measurement agrees very well with the in vitro measurement. From this it can be concluded that it is possible to reliably detect changes in the concentration of a physiologically harmless dye in vivo at a suitable wavelength (in particular in the range of the maximum of the emission spectrum) using relatively simple means.

Claims

claims

1. Control system for monitoring the regular intake of a drug in a patient, characterized in that it is a coordinated system components, a dosage form (1) of the drug and a detection device (2) for non-invasive detection of a substance contained in the dosage form in the patient's body (3), the detection device (2) being designed for the reagent-free direct measurement of a physically measurable parameter that correlates with the presence of the substance in the patient's body.

2. Control system according to claim 1, characterized in that the non-invasively detectable substance contained in the dosage form is a non-toxic marker substance different from the medicament.

3. Control system according to one of claims 1 or 2, characterized in that the medicament or the marking substance measurably influences an electromagnetic radiation radiated into the body and the detection device irradiation means (4) for irradiating electromagnetic radiation into the patient's body and detection means (5 ) for measuring a measured variable of the interaction of the electromagnetic radiation with the medicament or of the marking substance emerging radiation as parameters correlating with their presence in the body.

Control system according to claim 3, characterized in that the electromagnetic radiation is light, in particular in the visible or infrared region of the light spectrum.

Control system according to Claim 4, characterized in that the irradiation means (4) are designed to irradiate a plurality of wavelengths of the electromagnetic radiation and the spectral dependency of the parameter is used to detect the marking substance.

Control system according to one of claims 3 to 5, characterized in that the detection device has irradiation means (4) for irradiating the electromagnetic radiation at several different irradiation locations and / or detection means for detecting the electromagnetic radiation at several different detection locations and the dependency of the detected parameter of the measuring distance between the respective irradiation site and the respective detection site is used to detect the marking substance.

Control system according to one of claims 3 or 4, characterized in that the medicament or the marking substance contains a fluorescent dye and the detection device is designed for in vivo detection of the fluorescence as parameters correlating with the presence of the marking substance in the body.

8. Control system according to one of the preceding claims, characterized in that the detection device has means for determining the temporal change in the parameters and an increase or decrease in the parameter is used to detect the intake of the medicament.

9. Control system according to one of the preceding claims, characterized in that the detection device (2) has a wearable sensor unit.

10. Control system according to one of the preceding claims, characterized in that the detection device

(2) in the form of a device usually worn on the body, such as a wristwatch in particular.

11. Control system according to one of the preceding claims, characterized in that the detection device has a time measuring device (9) and a memory (8) for storing data on the detection of the marking substance.

12. Control system according to claim 11, characterized in that the detection device (2) generates a warning signal if no marker substance in the patient's body within a predetermined period

(3) is detectable.

13. Control system according to one of the preceding claims, characterized in that the detection device has an interface for transmitting the data to an external interrogation unit.

14. Control system according to claim 11, characterized in that the detection device has a transmitter (13) for wireless transmission of the data to an external interrogation unit.

15. Pharmaceutical dosage form for a control system according to one of claims 2 to 14, characterized in that it contains, in addition to an active ingredient, a non-toxic marking substance, the presence of which can be measured non-invasively in the patient's body with the detection device.

16. Pharmaceutical dosage form according to claim 15, characterized in that the marking substance contains a fluorescent dye.

17. Pharmaceutical dosage form according to claim 15, characterized in that the marking substance is made non-toxic by wrapping or incorporation into a macromolecular protective molecule structure.

18. Pharmaceutical dosage form according to claim 17, characterized in that the macromolecular protective - molecular structure belongs to the group of dendrimers or fullvalenes.