Patent Application
20230255739
This application claims priority to European Patent Application
EP 22 157 224.1 filed Feb. 17, 2022, the entire contents of which are hereby incorporated in full by this reference.
The invention relates to a holding device for simultaneously holding several small animals comprising at least three beds each for a small animal, whereby each bed is attached to an according holder element.
Holding devices for simultaneous holding a multitude of beds with small animals thereon are for example described in U.S. Pat. No. 8,660,633 B2 (Reference [1]) or in Esparza-Cross 2008: “Wireless self-gated multiple-mouse cardiac cine MRI”, Mag. Resonance in Medicine 59, 1203-1206 (2008) (Reference [2]).
In general, the present invention relates to the technical field of laboratory support for conducting scientific investigations on—in most cases living—animals. In particular, the invention contributes as an auxiliary aid for holding small animals, like e.g., mice and rats, during examinations.
U.S. Pat. No. 10,632,271 B1 (Reference [3]) describes a “versatile subject bed” for use with one or more test subjects that is configured to keep the subjects sedated throughout either a surgical procedure or imaging process. This subject bed can include interchangeable manifolds allowing the platform to hold up to four subjects at the same time. The four-subject manifold can include an elevated platform that holds two subject side by side and allows the subjects to be stacked during imaging or other procedures.
In Reference [2] cited above, four mice can be inserted geometrically in parallel into an MRI imaging device. However, these mouse holders are mechanically separated from each other.
Reference [1] also cited above describes a generic holding device for simultaneously holding several small animals. Here, each small animal can be separately fixed to a bed and inserted into a common holder which provides anesthesia ports. The animal beds can all be attached to the holder but must be inserted separately into the holder. The animal beds can be separated from the holder for individually placing the small animals. After mounting, the beds each have a fixed position relative to the holder and to each other. In particular, the device according to Reference [1] does not enable any possibility of moving the beds with respect to each other.
Although there is a wide range of already existing solutions according to prior art devices for holding a multitude of small animals at the same time, no one of them offers the combination of a compact device and an easy animal access when mounted to the holder.
It is an object of the present invention to provide—without much technical effort—a generic and compact holding device for a multitude of small animals facilitating a flexible, easy access to each small animal when attached to the holder, in particular for generating a 3D image of all animals at the same time, e.g., in an MRI, PET, CT scanner or the like. The holding system should be easy to use, in particular for rats or mice, and easily applied in a wide variety of locations through its small and compact construction.
This object is achieved, in accordance with the present invention and in a surprisingly simple and effective way, by modifying a generic device for simultaneously holding several small animals as defined above in the first paragraph in that the holding device is geometrically constructed and mechanically configured such that two holder elements can be moved together with their respective beds above a third holder element without thereby changing the vertical orientation of the beds being attached to the two holder elements.
The holding device according to the invention is adapted for use as a multiple-purpose animal bed to be able to measure/scan multiple small animals in multiple modalities:
It can receive e.g., 4 mice or maybe only 2 mice and a rat or larger mouse.
It can be used in stretched/unfolded mode with e.g., 4 mice near each other, being arranged horizontally or rather in folded mode with e.g., 4 mice arranged in a circle.
In stretched/unfolded mode, the beds are aligned in a common plane and the bottom surfaces as well.
Both modes can be mechanically locked.
While unfolding or folding the bed holder, the orientation of the beds is always in the same vertical direction; therefore, no mouse will accidentally fall off.
The unfolding mechanism provides enough space for anesthesia supply.
Although the holding device according to the present invention is preferably used in devices for preclinical imaging, there are also other possible and useful implementations of the invention in further fields of research.
Preferred embodiments and further developments of the invention:
In straightforward embodiments of the invention, the holding device is geometrically constructed and configured such that the two holder elements can be moved above the third holder element by a translatory movement.
The holding device is designed to be stable due to the translatory adjustability of the holding elements and is a compact arrangement of the animals' beds. Small animals are kept in horizontal position once the beds/holders are arranged for cross-sectional scanning i.e., tomographic modalities. Only that allows for arranging the small animals like that. For surface scanning (optical, thermography) they need to be arranged next to each other.
However, in some other cases of application, there might be some need to avoid translatory movement. For these cases, alternative embodiments of the invention are suitable, where the two holder elements can be moved above the third holder element by a rotating movement.
A rotating movement allows a compact setup of the holding device and reduces the footprint in the unfolded position. This might apply if there is no need to keep the beds attached to the holder horizontal, e.g., when used in a scanner for material samples, e.g., bore cores.
In particularly preferred variants of these embodiments of the invention, the two holder elements which can be moved above the third holder element are pivotably linked to the third holder element each with at least two holder arms.
By using two holder arms, the mechanical stability during rotation and in the static case is improved.
In another class of advantageous embodiments of the present invention, the holding device has a locking mechanism which is geometrically constructed and mechanically configured such that two of the holder elements can be locked in their movement and fixed in a folded position with at least one of the first two holder elements being placed above the third holder element and in an unfolded position with at least one of the first two holder elements being placed horizontally beside the third holder element.
This mechanism makes the holder mechanically stable in both, the open and closed state, and a small animal can be easily removed without removing a bed from the holder. It prevents the assembly of moving unintendedly during a cross-sectional scanning—maybe induced by an animal moving. Further, this makes sure that for animal preparation—in unfolded position—the assembly does not fold and can be put on a flat surface without toppling over.
In a preferred further development of this embodiment, the holder arms of the two holder elements have deepenings and the third holder element has spring loaded balls which can engage in the deepenings so that the two holder elements can be fixed with respect to the third holder element in the folded position or in the unfolded position.
As a result, the fixation of the two retaining elements in the unfolded and folded positions can be achieved without much force and with a smooth transition. It is the least space consuming way of providing a locking mechanism. Only a single spring-loaded ball is needed to lock a holder element into folded and unfolded position.
A preferred variant of this further development is characterized in that the deepenings have a slot-like structure.
This allows for relaxed requirements on manufacturing tolerances of the holding device, as the deepenings of the holder arms do not need to be aligned exactly with the spring-loaded balls when being fixed in the folded or unfolded position. Compared to a circular deepening a slot-like deepening allows more freedom of the ball of the spring-loaded ball to snap into. In that sense, it allows to compensate for manufacturing tolerances.
Alternatively or conjointly, in a further advantageous variant, the third holder element comprises two spring loaded balls, which engage in the deepening of the upper holder arms and the lower holder arms in the unfolded and in the folded position, respectively.
This reduces material usage as only two spring loaded balls are required for the device to lock into folded and unfolded position, which means less material costs and less mechanical complexity.
A further embodiment of the invention is characterized in that the first and second holder element each have a flat surface at their bottom such that the first and second holder element can stand stable on a flat working surface, in particular on a desk, in an unfolded position with at least one of the first and second holder element being placed horizontally beside the third holder element.
Due to this measure, the device is stable when open and small animals can be removed or inserted freehand. As explained above, this arrangement will make sure that for animal preparation—in unfolded position—the assembly does not fold and can be put on a flat surface without toppling over.
Also favorable are embodiments of the invention, which are characterized in that in a completely folded position, with the first and the second holder element being both placed above the third holder element, the holding device forms a cylindrical shape with circular circumference.
Due to the circular cylinder shape, the device is designed to be particularly compact. A cylindrical shape is especially helpful for cross-sectional imaging.
Preferred is a further development of these embodiments, in which the holder device is constructed in such a way that its cylindrical circumference in the completely folded state fits into an entry opening of an imaging instrument with circular inner diameter.
This would be e.g., a diameter of around 80 mm for an in-vivo micro-CT device or 85-200 mm for a magnetic resonance imaging instrument. It is an important requirement that the device needs to fit into the bore for imaging.
In some embodiments, the third holder element comprises two beds for small animals, in particular mice.
This allows to maximize the number of animals to be arranged occupying the least amount of space. It is required for an application which demands a total of 4 beds to be arranged for simultaneous scanning.
In alternative embodiments, the third holder element comprises one bed for a small animal, in particular a rat.
This makes the holding device more flexible to accommodate one smaller and one larger animal and is required to provide enough space even for a larger animal.
In another class of comparatively compact and simple embodiments of the invention, each of the animal beds have a semicircular cross section.
That feature provides a stable holding of each small animal. Further, a semicircular cross section provides enough space for the small animal. In principle, other cross-sections are also possible, but a semicircular cross section is easy to handle and clean since there are no corners compared to rectangular cross sections. In addition, a semicircular cross-section will provide enough space to put a warming pad below the small animal.
Further beneficial embodiments of the invention are characterized in that the beds at their free ends adjacent to their respective holder elements have a holding bar or stopper element preventing the small animal from slipping out of its bed.
The small animals are thereby kept in position even if the holding device is tilted when transferring it, e.g., to an imaging instrument. Further, this prevents fluids (e.g., mouse urine) from dropping out of the bed and polluting the imaging system.
Preferred is a further development of these embodiments, in which the holding bars or stopper elements have a notch for holding a tail of the small animal while lying in the bed.
In this way, the small animals are at least partially fixed in an upward or downward position. In addition, this might act as a defined outlet for fluids.
Still other advantageous embodiments of the holding device according to the present invention are characterized in that each of the holder elements have a slot or slit for receiving and holding inlet tubes for leading anesthetization gas to a gas mask for the respective small animal.
This arrangement allows for a compact design of the entire assembly, since no inlet tubes need to be routed outside the perimeter of the holding device. It can be combined with an afore mentioned anesthesia mask.
Further advantages can be extracted from the description and the enclosed drawings. The features mentioned above and below can be used in accordance with the invention either individually or collectively in any combination. The embodiments mentioned are not to be understood as exhaustive enumeration but rather have exemplary character for the description of the invention.
The invention is shown in the drawings and is explained in more detail based on illustrative embodiments.
In the drawings:
The present invention is principally concerned with providing tools for performing scientific investigations on small animals, in particular with the development of an improved holding device for a multitude of small animals like mice and rats.
According to the invention, this holding device 10 is geometrically constructed and mechanically configured such that two of the holder elements 12a, 12b can be moved together with their respective beds 11a, 11b above a third holder element 12c without thereby changing the vertical orientation of the beds 11a, 11b being attached to the two holder elements 12a, 12b.
The holding device 10 of
The beds 11a, 11b, 11c, 11d in this embodiment each have a semicircular cross section. In a completely folded position with the first and the second holder element 12a, 12b being both placed above the third holder element 12c the holding device 10 forms a cylindrical shape with circular circumference. This provides the biggest amount of animals in a circle and in this way one can easily use circular scan methods like CT, PET etc.
The third holder element 12c in this embodiment comprises two beds 11c, 11d for small animals A, in particular mice. In other embodiments of the invention (as shown in
Further, holding bars or stopper elements 17a, 17b, 17c, 17d are provided, each having a notch 18a, 18b, 18c, 18d for holding a tail T of the small animal A while lying on its bed 11a, 11b, 11c, 11d. The holder elements 12a, 12b, 12c each have a slot or slit 19a, 19b, 19c, 19d for receiving and holding inlet tubes for leading anesthetization gas to a gas mask for the respective small animal A.
The first and second holder element 12a, 12b each have a flat surface 16a, 16b at their bottom such that the first and second holder element 12a, 12b can stand stable on a flat working surface, in particular on a desk, in an unfolded position with at least one of the first and second holder element 12a, 12b being placed horizontally beside the third holder element 12c.
The holding device 10 has a locking mechanism which is geometrically constructed and mechanically configured such that two of the holder elements 12a, 12b in their movement can be locked and fixed in a folded position with at least one of the first and second holder element 12a, 12b being placed above the third holder element 12c and in an unfolded position with at least one of the first and second holder element 12a, 12b being placed horizontally beside the third holder element 12c.
The holder arms 13a, 13a′; 13b, 13b′ of the two holder elements 12a, 12b have deepenings 14a, 14a′; 14b, 14b′ with a slot-like structure.
A schematic stereoscopic view of an embodiment of the holding device according to the invention having four beds and being in a partially folded position with one of the beds in the lifted position and the other three beds in the lower horizontal arrangement is depicted in
The third holder element 12c carrying two beds 11c, 11d comprises screws with spring loaded balls 15a, 15b which can engage in the deepenings 14a, 14b′ of the holder arms 13a, 13b′ so that the first two holder elements 12a, 12b can be fixed with respect to the third holder element 12c in the folded position or in the unfolded (stretched) position. In
More precisely,
The third (bottom) holder element 12c contains two ball screws, which are inserted from the backside. Once the holder arm 13b′ moves over the spring-loaded ball screw, the ball snaps into the grove 14b′ and will lock the movement of the arm 13b′. That means, the spring-loaded ball screws 15a, 15b are not part of the holder arms, but part of and rigidly connected to the third (bottom) holder element 12c. In fact, there is a little hole in the third (bottom) holder element 12c on the front (bed) side that allows to adjust the fit of the ball screw and thus of the load onto the holder arm. In the figure, the third (bottom) holder element is hidden and reveals the inserted ball screws and it looks like they are connected to the arms—which they are not in fact. But the figures nicely illustrate that the ball snaps into the grove of the top holder arm in case the assembly is open and into to bottom holder arms once it is closed.
The stereoscopic view of
Finally,
Publications considered for assessing patentability of the present invention:
| Number | Date | Country | Kind |
|---|---|---|---|
| 22 157 224.1 | Feb 2022 | EP | regional |
