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Title:
UROFLOWMETRY SYSTEMS, DEVICES, AND METHODS
Document Type and Number:
WIPO Patent Application WO/2018/036664
Kind Code:
A1
Abstract:
Provided are systems, devices and methods in the field of uroflowmetry, more specifically in the field of home uroflowmetry. In one aspect, provided is a pee hat for holding a uroflowmeter comprising a rim for positioning the pee hat on a toilet and a holder for holding the uroflowmeter; the rim being circumferentially disposed around the holder; the holder comprising a base and one or more side walls; the base comprising a hole and an edge for supporting a uroflowmeter.

Inventors:
SAGEDER JOSEF (AT)
VERMEULEN JIRI (BE)
Application Number:
PCT/EP2017/054486
Publication Date:
March 01, 2018
Filing Date:
February 27, 2017
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
MINZE NV (BE)
International Classes:
A61B5/20; A47K13/00; A61B10/00
Domestic Patent References:
WO2015173726A12015-11-19
WO2011010311A22011-01-27
Foreign References:
US6212698B12001-04-10
EP2016070180W2016-08-26
Attorney, Agent or Firm:
PAPPAERT, Kris et al. (BE)
Download PDF:
Claims:
CLAIMS

1 . Pee hat (100) for holding a uroflowmeter comprising a rim (120) for positioning the pee hat on a toilet and a holder (1 10) for holding the uroflowmeter;

the rim (120) being circumferentially disposed around the holder (1 10);

the holder (1 10) comprising a base (1 1 1 ) and one or more side walls (1 12);

the base (1 1 1 ) comprising a uroflowmeter holding means.

2. The pee hat (100) according to claim 1 wherein the uroflowmeter holding means is a hole and an edge for supporting the uroflowmeter.

3. The pee hat (100) according to claim 2, wherein the hole is circular and/or the edge is ring-shaped.

4. The pee hat (100) according to any one of claims 1 to 3, wherein the rim (120) comprises a rounded portion (122) and a flattened portion (121 ), the rim being thinner on average at the flattened portion (121 ) than at the rounded portion (122).

5. The pee hat (100) according to any one of claims 1 to 4, wherein the one or more side walls (1 12) have a length at least 5.0 cm and at most 15.0 cm, for example 6.0 cm, for example 14.0 cm; preferably between 7.0 cm and 13.0 cm, for example 8.0 cm, for example 12.0 cm; most preferably between 9.0 cm and 1 1 .0 cm, for example 9.5 cm, for example 10.0 cm, for example 10.5 cm.

6. Uroflowmetry system comprising a uroflowmeter and a pee hat (100) according to any one of claims 1 to 5, wherein the holder (1 10) of said pee hat (100) supports the uroflowmeter.

7. The uroflowmetry system according to claim 6, wherein the uroflowmeter comprises a core unit (200) and a receptacle (300).

8. The uroflowmetry system according to claim 7, wherein the core unit (200) rests on the base (1 1 1 ), and wherein the receptacle (300) rests on the core unit (310).

9. The uroflowmetry system according to claim 7 or 8, wherein the core unit (200) and the receptacle (300) comprise a flat surface having a lateral border, the lateral border centering the receptacle on top of the core unit.

10. The uroflowmetry system according to any one of claims 7 to 9, wherein the receptacle (300) comprises a base comprising a plurality of protrusions; preferably rounded protrusions.

1 1 . Uroflowmetry assembly comprising a sitting toilet (400), and a uroflowmetry system according to any one of claims 6 to 10, the sitting toilet (400) comprising a toilet bowl comprising an toilet bowl edge, wherein the rim (120) of the pee hat (100) rests on the toilet bowl edge.

12. The uroflowmetry assembly according to claim 1 1 , wherein the holder is positioned in the toilet bowl.

13. The uroflowmetry assembly according to claim 1 1 , wherein the holder is positioned above the toilet bowl.

14. Method for performing a uroflowmetry measurement comprising the steps:

providing a pee hat (100) according to any one of claims 1 to 4;

positioning the pee hat on a toilet (400) comprising a toilet bowl and a toilet seat;

optionally, clamping the rim (120) between the toilet bowl and the toilet seat; positioning a uroflowmeter on the holder, the uroflowmeter comprising a receptacle (300); and,

urinating in the receptacle.

15. Use of a pee hat according to any one of claims 1 to 4 for holding a uroflowmeter.

Description:
UROFLOWMETRY DEVICES, SYSTEMS, AND METHODS

FIELD OF THE INVENTION

Provided are systems, devices and methods in the field of uroflowmetry, more specifically in the field of home or clinical uroflowmetry. In one aspect, provided is a pee hat for holding a uroflowmeter comprising a rim for positioning the pee hat on a toilet and a holder for holding the uroflowmeter; the rim being circumferentially disposed around the holder; the holder comprising a base and one or more side walls; the base comprising a hole and an edge for supporting a uroflowmeter.

BACKGROUND

Uroflowmetry is a simple, non-invasive diagnostic procedure in which the flow rate of urine is measured over time. The information obtained in uroflowmetry tests helps evaluating the function of the lower urinary tract and/or it may help determining whether normal urine flow is obstructed.

Being simple and non-invasive, uroflowmetry is generally included in the initial work-up of incontinent subjects. In particular, uroflowmetry is generally performed as a diagnostic prior to any urethral instrumentation.

Many different factors determine the reliability of uroflowmetry tests. A first factor is the "fullness" of the bladder prior to urination. Ideally, patients should void with a "comfortably full bladder". Since filling of the bladder is an involuntary process which can only be influenced indirectly through the consumption of foods and beverages, letting patients void with a comfortably full bladder can be challenging indeed when operating in a clinical setting.

Indeed, the most practical setting for performing uroflowmetry tests would be in the privacy and comfort of a patient's home. However, due to limited oversight by a physician, interpreting the validity of home uroflowmetry tests may be more challenging compared to interpreting the validity of uroflowmetry tests taken in a clinical setting. Also, patient compliance with taking uroflowmetry tests may be less at home compared to in a clinical setting.

Accordingly, there is a need for uroflowmetry systems which allow reliably performing uroflowmetry at home while facilitating satisfactory patient compliance. SUMMARY OF THE INVENTION

The presently disclosed systems, devices and methods address one or more problems of the art in the field of uroflowmetry, more specifically in the field of home or clinical uroflowmetry.

In particular, a pee hat is provided. Whereas existing pee hats are devices for collecting urine (in some cases stool as well) in a sitting position, the present pee hat is essentially a holder for a uroflowmeter and a receptacle. Accordingly, a pee hat according to the present disclosure is not, by itself, a device for collection of urine or stool, though evidently it allows collection of urine when used in conjunction with a uroflowmeter. The present pee hats facilitate uroflowmetry measurements in the comfort of a patient's own home since they are compatible with conventional toilets. Furthermore, the pee hat might also be used in a clinical setting, such as on the bedroom toilet of a hospital, or in a (healthcare) professional setting, such as on a public toilet in a physician's private practice. Emulating a natural setting increases the feeling of voiding, which has a beneficial impact on the quality and/or quantity of collected urine. The pee hats have a unisex design; they are suitable for male and female. Accordingly, pee hats according to the present disclosure allow performing many uroflowmetry measurements in an efficient way which in turn allows gathering urological data such as the amount of measurements, the frequency and the maximum flow rate (Qmax) versus voided volume (V.V.) data for all measurements in a single graph, allowing easy analysis of the data.

In particular, the present invention provides a pee hat for holding a uroflowmeter comprising a rim for positioning the pee hat on a toilet and a holder (1 10) for holding the uroflowmeter;

the rim (120) being circumferentially disposed around the holder (1 10);

the holder (1 10) comprising a base (1 1 1 ) and one or more side walls (1 12);

the base (1 1 1 ) comprising a uroflowmeter holding means. Preferably, the uroflowmeter holding means is a hole and an edge for supporting the uroflowmeter.

Preferably, the hole is circular and/or the edge is ring-shaped.

Preferably, the rim (120) comprises a rounded portion (122) and a flattened portion (121 ), the rim being thinner on average at the flattened portion (121 ) than at the rounded portion (122).

Preferably, the one or more side walls (1 12) have a length between at least 5.0 cm and at most 15.0 cm, for example 6.0 cm, for example 14.0 cm; preferably between 7.0 cm and 13.0 cm, for example 8.0 cm, for example 12.0 cm; most preferably between 9.0 cm and 1 1 .0 cm, for example 9.5 cm, for example 10.0 cm, for example 10.5 cm.

Preferably, the holder (1 10) of said pee hat (100) supports the uroflowmeter.

Preferably, the uroflowmeter comprises a core unit (200) and a receptacle (300).

Preferably, the core unit (200) rests on the base (1 1 1 ), and wherein the receptacle (300) rests on the core unit (310).

Preferably, the core unit (200) and the receptacle (300) comprise a flat surface having a lateral border, the lateral border centering the receptacle on top of the core unit.

Preferably, the receptacle (300) comprises a base comprising a plurality of protrusions. Preferably, the protrusions comprise rounded protrusions.

The present invention also provides a uroflowmetry assembly comprising a sitting toilet (400) and a uroflowmetry system, the sitting toilet (400) comprising a toilet bowl comprising an toilet bowl edge, wherein the rim (120) of the pee hat (100) rests on the toilet bowl edge.

Preferably, the holder is positioned in the toilet bowl.

Preferably, the holder is positioned above the toilet bowl.

The present invention also provides a method for performing a uroflowmetry measurement comprising the steps:

providing a pee hat (100) according to any one of aspects 1 to 4; positioning the pee hat on a toilet (400) comprising a toilet bowl and a toilet seat;

optionally, clamping the rim (120) between the toilet bowl and the toilet seat; - positioning a uroflowmeter on the holder, the uroflowmeter comprising a receptacle (300); and,

urinating in the receptacle.

The present invention also provides a use of a pee hat holding a uroflowmeter.

These and further aspects and embodiments of the invention are explained in more detail in the sections below and in the claims, and are illustrated by the non-limitative examples. BRIEF DESCRIPTION OF THE DRAWINGS

The following description of the figures of specific embodiments of the invention is merely exemplary in nature and is not intended to limit the present teachings, their application or uses. Throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features.

Figure 1 shows how a pee hat (100) can be used for uroflowmetry measurements in a seated position.

Figure 2 shows how a pee hat (100) can be used for uroflowmetry measurements in a standing position.

Figure 3 shows top- and cross sectional views of a uroflowmetry system. In particular, panel A shows a top- and cross sectional view of a uroflowmetry system configured for uroflowmetry measurements in a seated position and panel B shows a top- and cross sectional view of a uroflowmetry system configured for uroflowmetry measurements in a standing position.

Figure 4 shows a top- and cross sectional view of a uroflowmetry system configured for uroflowmetry measurements in a seated position.

Figure 5 shows top- and bottom views of a holder (1 10) according to an embodiment of the present invention.

Figure 6 shows top- and bottom views of a receptacle (300) according to an embodiment of the present invention.

Figure 7 shows a top- and cross sectional view of a uroflowmetry system configured for uroflowmetry measurements in a seated position. In particular, the panels show a detailed view of a contact point (350).

Figure 8 shows a side and cross sectional view of a uroflowmetry system configured for uroflowmetry measurements in a seated position. In particular, the panel shows a detailed view of a contact point and a draft angle.

Figure 9 shows a detailed cross-sectional view of a uroflowmetry system for use in a seated position.

Figure 10 shows a detailed cross-sectional view of a uroflowmetry system for use in a seated position according to a particular embodiment of the present invention.

Throughout the figures, the following numbering is adhered to: 100 - pee hat; 1 10 - holder; 1 1 1 - base; 1 12 - side wall; 120 - rim; 121 - flattened portion; 122 - rounded portion; 200 - core unit; 300 - receptacle; 310 - handles; 320 - protrusions; 330 - lateral border; 350 - contact points; 400 - sitting toilet; 410 - toilet seat DETAILED DESCRIPTION

The present invention will be described with respect to particular embodiments but the invention is not limited thereto but only by the claims. Any reference signs in the claims shall not be construed as limiting the scope thereof.

As used herein, the singular forms "a", "an", and "the" include both singular and plural referents unless the context clearly dictates otherwise.

The terms "comprising", "comprises" and "comprised of" as used herein are synonymous with "including", "includes" or "containing", "contains", and are inclusive or open-ended and do not exclude additional, non-recited members, elements or method steps. The terms "comprising", "comprises" and "comprised of" when referring to recited members, elements or method steps also include embodiments which "consist of" said recited members, elements or method steps.

Furthermore, the terms first, second, third and the like in the description and in the claims, are used for distinguishing between similar elements and not necessarily for describing a sequential or chronological order, unless specified. It is to be understood that the terms so used are interchangeable under appropriate circumstances and that the embodiments of the invention described herein are capable of operation in other sequences than described or illustrated herein.

The term "about" as used herein when referring to a measurable value such as a parameter, an amount, a temporal duration, and the like, is meant to encompass variations of +/-10% or less, preferably +/-5% or less, more preferably or less, and still more preferably +/-0.1 % or less of and from the specified value, insofar such variations are appropriate to perform in the disclosed invention. It is to be understood that the value to which the modifier "about" refers is itself also specifically, and preferably, disclosed.

The recitation of numerical ranges by endpoints includes all numbers and fractions subsumed within the respective ranges, as well as the recited endpoints.

All documents cited in the present specification are hereby incorporated by reference in their entirety.

Unless otherwise defined, all terms used in disclosing the invention, including technical and scientific terms, have the meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. By means of further guidance, definitions for the terms used in the description are included to better appreciate the teaching of the present invention. The terms or definitions used herein are provided solely to aid in the understanding of the invention.

Reference throughout this specification to "one embodiment" or "an embodiment" means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, appearances of the phrases "in one embodiment" or "in an embodiment" in various places throughout this specification are not necessarily all referring to the same embodiment, but may. Furthermore, the particular features, structures or characteristics may be combined in any suitable manner, as would be apparent to a person skilled in the art from this disclosure, in one or more embodiments. Furthermore, while some embodiments described herein include some but not other features included in other embodiments, combinations of features of different embodiments are meant to be within the scope of the invention, and form different embodiments, as would be understood by those in the art. For example, in the following claims, any of the claimed embodiments can be used in any combination.

Provided herein are systems, devices and methods in the field of uroflowmetry, more specifically in the field of home or clinical uroflowmetry. In particular, a pee hat is provided. Whereas existing pee hats are devices for collecting urine (in some cases stool as well) in a sitting position, the present pee hat is essentially a holder for a uroflowmeter and a receptacle. Accordingly, a pee hat according to the present disclosure is not, by itself, a device for collection of urine or stool, though evidently it allows collection of urine when used in conjunction with a uroflowmeter. The present pee hats facilitate uroflowmetry measurements in the comfort of a patient's own home since they are compatible with conventional toilets. Furthermore, the pee hat might also be used in a clinical settings, such as on the bedroom toilet of a hospital, or in a (healthcare) professional setting, such as on a public toilet in a physician's private practice. Emulating a natural setting increases the feeling of voiding, which has a beneficial impact on the quality and/or quantity of collected urine. The pee hats have a unisex design; they are suitable for male and female. Accordingly, pee hats according to the present disclosure allow performing many uroflowmetry measurements in an efficient way which in turn allows gathering urological data such as the amount of measurements, the frequency and the maximum flow rate (Qmax) versus voided volume (V.V.) data for all measurements in a single graph, allowing easy analysis of the data. Provided herein is a pee hat for holding a uroflowmeter. The pee hat comprises a rim for positioning the pee hat on a toilet. The rim is suitable for engaging with the bowl of a conventional toilet, regardless of the environment, e.g., home, clinical, etc. Also, the pee hat comprises a holder for holding the uroflowmeter. The holder might be described as a flat-bottomed-bowl-shaped part in the middle of the pee hat. Also, the holder can be said to be disposed to hold a uroflowmeter in a toilet bowl of a sitting toilet. The rim might be described as a flat ledge at least partially surrounding the holder. In other words, the rim can be said to be disposed around at least part of the circumference of the holder. The holder comprises a base and one or more side walls. The side walls may either be continuous, or they may comprise one or more openings. The base comprises a uroflowmeter holding means. The holding means allows for holding of a uroflowmeter to preferably prevent (wobbling) movement of the uroflowmeter that would cause a spilling or splattering of urine, for instance when rinsing. The uroflowmeter holding means may be a uroflowmeter holding member, to provide for said holding. Additionally or alternatively, the uroflowmeter holding means may be a uroflowmeter fixation means; the fixation means allowing the uroflowmeter to attach, latch, lock, link, fix, couple and/or connect to base of the pee hat. The fixation means may be at least one, such as two or three, fixation member(s). For example, it may be (part of) a system that provides for a longitudinal and/or rotational engagement of the uroflowmeter when inserted into the pee hat. Preferably, the borders of the pee hat are rounded, which avoids the presence of sharp edges which may hurt a patient while holding the pee hat.

In some preferred embodiments, the uroflowmeter holding means is a hole and an edge for supporting the uroflowmeter. Preferably, the hole is circular and/or the edge around the hole in the base of the pee hat's holder is ring-shaped. In fact, generally, the hole is circular and the edge is ring-shaped, but other form factors (e.g. geometry, size, shape) may be possible as well. The hole in the base allows use of the pee hat in conjunction with a uroflowmeter which (partially) sinks in the hole, and which is supported by the edge. During seated uroflowmetry measurements, this enhances the volume available in the receptacle of the uroflowmeter for collecting urine. Preferably the receptacle can hold a (urine) volume of up to 2.0 I; preferably up to 1 .8 I; more preferably up to 1 .5 I; most preferably up to 1 .2 I, for example 1 .1 I, for example 1 .0 I. The receptacle can be adjusted to hold higher volumes, although this may require an adjustment to the holder. During standing uroflowmetry measurements, this increases the stability of the pee hat- uroflowmetry assembly. Preferably the receptacle has volume indicators to indicate the volume of collected urine; for example, lines indicating that 0.5 I or 1 .0 I has been collected.

The edge may be seen as a ledge around the hole in the base of the holder of the pee hat. The edge allows supporting a uroflowmeter, preferably a uroflowmeter comprising a core unit and a receptacle, for example a uroflowmeter as described in international patent application no. PCT/EP2016/070180. The edge is particularly suitable for supporting a core unit shaped as a stack of two cylinders with different diameters, as described below. Additionally, the edge may comprise one or more, preferably two, cutouts to allow an easier removal and placement of the uroflowmeter. The edges and/or cut-outs are preferably rounded for improved user friendliness.

In some preferred embodiments, the rim comprises a rounded portion and a flattened portion. On average, the rim is thinner at the flattened portion than at the rounded portion. As a result the flattened portion will be located lower than the rounded portion, creating an incline from the flattened portion towards the rounded portion. The incline lessens or prevents the patient's backside from touching the flattened portion, thus making it more comfortable to sit on and also reduces the chance for a patient to influence the measurement. In some embodiments the flattened portion is located at least 0.5 cm lower than the rounded portion, preferably 1 .0 cm or 1 .5 cm. Accordingly, when the pee hat is put on the bowl of a sitting toilet, an opening remains, thereby allowing for easy disposal of urine. Also, it allows stool to pass during uroflowmetry measurements in a seated position.

The rim is generally shaped to match the contours of a toilet seat. Accordingly, in some embodiments, the rim has a central diameter between at least 20 and at most 60 cm, more preferably between 20 and 40 cm; most preferably 25 and 35 cm, for example 30 cm. This allows effective positioning of the pee hat on a conventional toilet bowl.

Alternatively, a rim comprising a rounded portion and a flattened portion may be described as a U-shaped rim. The U-shape of the rim allows positioning the rim on a toilet bowl, and clamping the rim between toilet bowl and toilet seat. Because a toilet bowl generally has an oval shape, a pee hat with a U-shaped rim does not cover the entire toilet bowl, and accordingly, an opening remains for easy disposal of urine and/or for stool to pass.

In some preferred embodiments, the one or more side walls have a length between at least 5.0 cm and at most 15.0 cm, for example 6.0 cm, for example 14.0 cm; preferably between 7.0 cm and 13.0 cm, for example 8.0 cm, for example 12.0 cm; most preferably between 9.0 cm and 1 1 .0 cm, for example 9.5 cm, for example 10.0 cm, for example 10.5 cm. This allows a sidewall to reach maximal depth while still fitting in a conventional toilet bowl. Accordingly, a uroflowmeter comprising a receptacle can be positioned in the pee hat's holder, thus allowing uroflowmetry measurements in a seated position.

In some preferred embodiments, the rim is bent in an axial direction, i.e. from the centre of the pee hat to its perimeter. In some embodiments, the bend covers an arc between 0.5° and 10.0°, for example 0.6°, for example 9.0°; preferably between 0.7° and 5.0°, for example 4.5°, for example 4.0°, for example 3.5°, for example 0.9°; more preferably between 1 .0° and 3.0°, for example 2.5°; most preferably between 1 .0° and 2.0°, for example 1 .1 °, for example 1 .2°, for example 1 .3°, for example 1 .4°, for example 1 .5°, for example 1.6°, for example 1.7°, for example 1.8°, for example 1 .9°. The bend allows a fixing or clamping of the pee hat in an approximately horizontal or level position when a toilet seat is closed or a patient sits on it. Additionally, selecting an optimal angle decreases the amount of vibrations during voiding in a standing position. Though the rim may be bent in an axial direction, the rim preferably comprises a planar line which lies in a plane within a margin of 5°, more preferably 2°, even more preferably 1 °; most preferably approximately 0°. The planar line is preferably parallel to the base within a margin of 5.0°, more preferably 2°, even more preferably 1 °; most preferably approximately 0°. The planar line is an effective way of ensuring that the base is in an approximately horizontal or level position which allows for more accurate installation of a uroflowmeter in the holder, for instance when the pee hat is placed upside down for the standing position.

In some preferred embodiments, the one or more side walls are perpendicular to the base within a margin of 1 .0x10 1 °; preferably 5.0°; more preferably 2.5° ; most preferably 1 .0°.

Further provided is a uroflowmetry system comprising a uroflowmeter and a pee hat as described above. The pee hat comprises a holder which supports the uroflowmeter. This allows for efficient, robust, and ergonomical uroflowmetry measurements in the comfort of a patient's own home, or in a clinical setting.

The uroflowmetry systems provided herein facilitate uroflowmetry measurements. In particular, the uroflowmetry devices provided herein may facilitate multiple uroflowmetry measurements for the same patient. This is especially useful for constructing Q max versus V.V. graphs, wherein Q max is the maximum urine flow rate during urination, and V.V. is the voided volume. In some preferred embodiments, the uroflowmeter comprises a core unit and a receptacle (300). This may enhance the effectivity of uroflowmetry systems.

Preferably, the core unit has a waterproof housing. This enhances the reliability of the uroflowmetry system in view of accidental liquid spills during uroflowmetry measurements.

As mentioned earlier, the base of the pee hat's holder comprises a hole. This hole is particularly advantageous in conjunction with a core unit which is shaped as a stack of two cylinders, a lower and a higher cylinder. The lower cylinder has a diameter which is smaller than the diameter of the hole in the pee hat's holder. In some embodiments, the lower cylinder has a diameter which is between 0.50 and 2.0 mm smaller, preferably 1 .0 mm smaller than the diameter of the hole in the pee hat's holder. The higher cylinder has a diameter which is larger than the diameter of the hole in the pee hat's holder, preferably between 5.0 and 15.0 mm, preferably 10.0 mm larger than the diameter of the hole in the pee hat's holder. Accordingly, the core unit partly fits through the hole in the pee hat's holder which ensures a reversible though stable connection during uroflowmetry measurements. Also, this lowers the centre of gravity of the uroflowmetry set-up, which further enhances its stability, especially during uroflowmetry measurements in a standing position.

The receptacle may comprise a plurality of protrusions, for example half dome protrusions. This may eliminate or limit the risk of splashes.

In some embodiments the receptacle comprises a spout to allow easy pouring; the receptacle may further comprise two or more spouts, preferably spread out or on opposite sides of the receptacle, to allow pouring from multiple sides. In some embodiments, the receptacle comprises handles. These handles allow for easy handling of the receptacle. Additionally or alternatively, they may function as an overflow spout, allowing an overflow of urine to pour out during a void. In some embodiments, the receptacle comprises handles and the pee hat comprises corresponding holes. Thus, the handles and corresponding holes may function as an overflow. Also, the handles may be provided with an overflow channel for effectively directing excess urine through the holes in the pee hat.

The receptacle is configured for operationally coupling with a core unit. In some embodiments, the receptacle comprises urine analysis sensors for chemically analysing urine. The sensors may include a pH sensor, a specific gravity sensor, a urine detector, a glucose detector, a ketone detector, a blood detector, a leukocyte esterase detector, a nitrite/nitrate detector, a bilirubin detector, a urobilinogen detector, and/or an ion sensor (e.g. a CI " sensor).

In particular embodiments, the receptacle and/or the holder comprise an identification tag. The identification tag may be, for example, an NFC tag or an RFID tag. The identification tag may comprise an identification code of the receptacle and/or the patient who uses the receptacle. Additionally, there may be a recess for placing or inserting the identification tag. The identification tag may instead also provide a means to write or register a patient's name. Commonly, a receptacle is used by a single patient, such that an identification tag generally identifies a single receptacle and a single patient. Preferably, the identification tag is located on the bottom of the receptacle.

In particular embodiments, the receptacle comprises a base and one or more walls. The base comprises a lower face for resting on a core unit, and an upper face facing urine during a uroflowmetry measurement. In particular embodiments, the upper face of the receptacle's base is provided with protrusions, preferably rounded protrusions. Additionally or alternatively the protrusions may be hemispherical, hemi ellipsoidal, or of any other suitable shape. The protrusions minimize the risk of splashing during urination. In some embodiments, the pee hat's holder and the receptacle have a cylindrical shape, though other shapes are possible as well. The diameter of the receptacle is preferably between 4.0 and 6.0 mm, for example 5.0 mm smaller than the diameter of the holder. This ensures that the weight of the receptacle rests on the core unit during uroflowmetry measurements in a seated position, and that the uroflowmetry measurements can occur without artefacts related to friction between the receptacle and the walls of the holder. It will be understood that the term "cylindrical" as used herein may refer to objects which are not perfect cylinders in the mathematical sense. For example, the receptacle and the holder may show slight diameter variations along their central axes, for example variations in diameter of 4 to 6 mm.

In a particular embodiment the receptacle rests on the holder on at least two contact points, preferably four contact points; for example, the contact points may be the edges of the uroflowmeter that contact the pee hat, or the edges of the receptacle that contact the holder.

In a particular embodiment the sidewalls of the pee hat that engage with the uroflowmeter, for instance through the aforementioned contact points, may be configured with a draft angle (measured perpendicular to the cylindrical parting line) between at least 0.1 ° to at most 1 .0°; for example 0.5°. The presence of a (low) draft angle allows for the uroflowmeter to gradually sink into the pee hat as the weight of the uroflowmeter increase, for instance during rinsing. Preferably, the draft angle is kept as low as possible to prevent resistance to sinking. The uroflowmeter may thus be more easily placed into the pee hat at a higher position through a slidable engagement. Preferably a draft angle is also present on the sidewalls of the uroflowmeter that engage with the pee hat, for instance with the edges of the hole in the pee hat.

Preferably, the edges of the receptacle and/or the holder are rounded. This avoids the presence of sharp edges which may hurt a patient when they hold the receptacle and also lowers the amount of friction if the receptacle contacts the holder with a sliding motion, for instance during insertion or extraction. A rounding is preferably also present where the uroflowmeter contacts the pee hat, for similar reasons.

In some preferred embodiments, the core unit rests on the base. Also, the receptacle rests on the core unit. This allows for effective uroflowmetry measurements.

In some preferred embodiments, the core unit and the receptacle comprise a flat surface having a lateral border. The lateral border allows easily centering the receptacle on top of the core unit. Accordingly, the core unit and the receptacle can be easily stacked. In addition, and especially for uroflowmetry measurements in a standing position, the risk of the receptacle sliding off the core unit in the course of the measurement is reduced. Further provided is a uroflowmetry assembly. The uroflowmetry assembly comprises a sitting toilet, and a uroflowmetry system as described previously. The sitting toilet comprising a toilet bowl comprising an toilet bowl edge. The rim of the pee hat rests on the toilet bowl edge. This allows effective uroflowmetry measurements in the comfort of a patient's own home.

In some preferred embodiments, the holder is positioned in the toilet bowl. This allows for uroflowmetry measurements in a seated position.

In some preferred embodiments, the holder is positioned above the toilet bowl. This allows for uroflowmetry measurements in a standing position. Further provided is a method for performing a uroflowmetry measurement. The method comprises the following steps: First, a pee hat as previously disclosed is provided. Then, the pee hat is positioned on a toilet. The toilet comprises a toilet bowl and a toilet seat. The pee hat may be positioned with its holder in the toilet bowl for uroflowmetry measurements in a sitting position. Alternatively, the pee hat may be positioned with its holder above the toilet bowl for uroflowmetry measurements in a standing position. Preferably, the pee hat's rim is clamped between the toilet bowl and the toilet seat. This enhances the stability of the pee hat during uroflowmetry measurements. Next, a uroflowmeter is positioned on the holder. The uroflowmeter comprises a receptacle. The uroflowmetry set-up is now ready for use, and during a uroflowmetry measurement, a patient urinates in the receptacle.

One of the advantages of the present pee hat comes to fruition in the instant method: one and the same uroflowmetry system (pee hat & uroflowmeter) can be used for both standing and seated uroflowmetry measurements. The primary difference between a set up for standing uroflowmetry measurements and a set up for seated uroflowmetry measurements is the orientation of the pee hat.

Further provided is the use of a pee hat according as described herein for holding a uroflowmeter. Preferably, the uroflowmeter comprises a core unit and a receptacle, preferably as described in international patent application no. PCT/EP2016/070180.

EXAMPLES

To better illustrate the properties, advantages and features of the present invention some preferred embodiments are disclosed as examples with reference to the enclosed figures. Accordingly, the present invention discloses many embodiments and adjustments as appreciated by those skilled in the art and the scope of the present invention is by no means limited to one of the illustrative examples presented below.

Example 1

In a first example, reference is made to Figs 1 and 2. Figs 1 and 2 show exemplary modes of using a pee hat (100) as provided herein in the context of uroflowmetry measurements. The pee hat (100) supports a uroflowmeter comprising a core unit (200) and a receptacle (300).

In Fig. 1 , a set-up is shown for use by a sitting patient. In particular, panel A shows how a uroflowmeter is placed in a pee hat (100) with the body of the pee hat (i.e. the holder (1 10)) hanging inside the toilet bowl. A close-up of the pee hat (100) is shown in panel D. The pee hat comprises a rim (120) for positioning the pee hat on a toilet, and the pee hat comprises a holder (1 10) for holding a uroflowmeter comprising a core unit (200) and a receptacle (300). For a uroflowmetry measurement, the core unit (200) is placed inside the pee hat (100) (see panel E), and the receptacle (300) in turn is placed on top of the core unit (see panel F). During a uroflowmetry measurement, the rim (120) is clamped between the toilet bowl and the toilet seat (410) and a patient can sit down on the toilet seat (410) as they would normally do (panel B). After the uroflowmetry measurement, urine can be emptied into the toilet (400) without removing the pee hat (100) or the core unit (200) (panel C): the shape and dimensions of the pee hat (100) allow uroflowmetry measurements while a patient is seated on a regular toilet, while also leaving some space in the back for stool to pass and to empty the receptacle (300) in the toilet (400). In other words, and also referring to Figs 3 and 4, the pee hat (100) comprises a rim (120) comprising a rounded portion (122) and a flattened portion (121 ). During uroflowmetry measurements, the rounded portion follows the contours of the edge of the toilet bowl of the toilet (400), whereas the flattened portion is suspended over the toilet bowl.

In Fig. 2, the same pee hat (100), core unit (200), and receptacle (300) are used in a different configuration, namely in a set up for use by a standing patient. In this configuration, the pee hat (100) is turned upside down compared to the configuration for use by sitting patients. In particular, panel A shows the pee hat (100), core unit (200), and receptacle (300) on top of a toilet (400). The pee hat is placed with its body (holder 1 10) rising above the toilet bowl while the rim (120) rests on the toilet bowl. As shown in panel A, a toilet seat (410) can be used to clamp the rim between toilet bowl and toilet seat (410).

A close-up of the pee hat (100) in a position for use in this configuration is shown in panel D. For a uroflowmetry test (panel B), the core unit (200) is placed on top of the pee hat (see panel E), and the receptacle (300) is placed on top of the core unit (200) (see panel F). The pee hat (100) leaves some space near the back of the toilet bowl, thereby allowing easy emptying of the holder in the toilet (panel C). The height increase in this set up compared to the sitting set up (cfr. Fig. 1 ) makes it easier for a standing person to aim during uroflowmetry measurements.

Example 2.

In a further example, reference is made to Figs. 3 and 4. Figs. 3 and 4 show cross sectional views of a pee hat (100) as envisioned herein. The particular shape of the pee hat (100) allows uroflowmetry measurements while standing or while sitting down. In particular, Fig. 3 shows cross sections of uroflowmetry set-ups comprising a pee hat (100), a core unit (200), and a receptacle (300). In particular, the uroflowmetry setup of Fig. 3, panel A, is arranged for use in a seated position, and the uroflowmetry setup of Fig. 3, panel B, is arranged for use in a standing position.

Fig. 4 shows a different cross section of the uroflowmetry set-up for use in a seated position, highlighting its T-shaped contour when viewed along the cross section shown in Fig. 4. The pee hat (100) has a hole in the base of its holder in which the core unit (200) rests. The particular shape of the uroflowmetry set up and the hole in the base of the pee hat's holder make it possible to use the uroflowmetry set up in both a standing and a seated position. Changing from one configuration to the other is as simple as turning the pee hat (100) upside down and rearranging the core unit (200) and the receptacle (300). The T-shaped cross sectional contour of the uroflowmetry set-up is largely determined by the shape of the pee hat (100) which comprises a holder and a rim. This T-shape has several specific benefits: in the set-up for seated uroflowmetry measurements, the receptacle (300) is provided with ample space in the pee hat (100) such that it can capture a greater volume during a single uroflowmetry measurement. In the set-up for standing uroflowmetry measurements, the particular shape of the various components makes the set-up more stable. The base of the pee hat's (100) holder comprises a hole. The core unit is shaped as a stack of two cylinders, a lower and a higher cylinder. The lower cylinder has a diameter which is smaller than the diameter of the hole in the pee hat's (100) holder. The higher cylinder has a diameter which is larger than the diameter of the hole in the pee hat's (100) holder. Accordingly, the core unit (200) partly fits through the hole in the pee hat's (100) holder which ensures a reversible though stable connection during uroflowmetry measurements. Also, this lowers the centre of gravity of the uroflowmetry set-up, which further enhances its stability.

The receptacle comprises handles (310) which allow easy handling. Also, in the set-up for seated uroflowmetry measurements, the handles function as an overflow in combination with corresponding holes in the pee hat. Furthermore, the handles may function as a pouring spout. Additionally, Fig. 5 shows an illustration of a holder (1 10) from a top and bottom view. Fig 6 shows an illustration of a receptacle (300) from a top and bottom view. The receptacle of Fig 6 is suitable for placement inside or on top of the holder of Fig. 5 depending on the arrangement. Moreover, the bottom of the receptacle in Fig 6 is provided with a rectangular recess for placement of an identification tag, or alternatively a means to write a patient's name. Example 3.

In a further example, reference is made to Figs. 7 and 8. Figs. 7 and 8 illustrate a pee hat (100), and the panels in particular show a zoomed-in view of a contact point (350) as envisioned herein.

In Fig. 7 the holder (1 10) is shown to contact the receptacle (330) on four contact points, as indicated by the circles. By limiting the amount of contact points the potential friction between the holder (1 10) and the receptacle (330) is kept to a minimum. Moreover as shown in greater detail on the zoomed-in panels, in this particular embodiment the sidewalls are configured with a draft angle of about 0.5° (as measured from the perpendicular to the wall). When the holder (1 10) is inserted into the pee hat, (100) this allows a slidable engagement of the contact points of the holder(1 10), in this embodiment the edges, with the inner sidewall of the pee hat (100). During initial placement the holder with thus be in a 'high' position; however, when the weight of the holder increases, for instance during rinsing, the holder may gradually sink into the pee hat to reach a 'lower' position.

In Fig. 8 the uroflowmeter is shown to contact the pee hat; the contact are may be limited to specific points, for example four or eight points, or it may run across the circumference of the uroflowmeter. A greater contact area typically increases the stability, but may be more difficult to remove or place the uroflowmeter inside the pee hat. The zoomed-in panels further illustrate that the sidewalls of the urflowmeter are configured with a draft angle with a draft angle of about 0.5°; this allows a gradual sinking of the uroflowmeter into the hole of the pee hat, for instance during rinsing.

Example 4.

In example 3, reference is made to Fig. 9 which shows a detailed view of a pee hat (100) arranged for use in a seated position. The pee hat's (100) holder hangs down, and in it are placed a core unit (200) and a receptacle (300). Both the holder and the receptacle (300) are cylindrical. It will be understood that the term "cylindrical" as used herein may refer to objects which are not perfect cylinders in the mathematical sense. For example, the receptacle (300) and the holder in Fig. 4 show slight diameter variations along their central axes. In particular, the distance (a) between the receptacle (300) and the walls of the holder varies from top (top of page) to base (bottom of page) between 6 mm and 4 mm.

Fig. 10 illustrates a cross-sectional view of a particular embodiment of the present invention arranged for use in a seated position. The total vertical height of the pee hat is 1 10,19 mm. As outlined above for example 1 , the pee hat has a flattened and a rounded portion; the depth difference between the flattened and the rounded portion is 10,13 mm. The width as measured running through the central point is 247,26 mm; however, the widest width measured as the line connecting the two furthest removed points along the outside rim is 357,65 mm. The receptacle of the pee hat in this embodiment is adapted to hold a (urine) volume of 1 ,2 I.