COLD SLURRY CONTAINMENT
The present invention provides methods and devices for controlling a cold slurry that is delivered to a target tissue and for limiting heat transferring from surrounding tissue to the target tissue. In particular, a balloon structure is deployed at or near a point of delivery to act as a physical and/or thermal barrier. In some instances, the balloon structure can act as a pressure device obstructing the flow of warm blood into a treatment area, which can melt the cold slurry.
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This application claims the benefit under 35 U.S.C. § 119(e) of U.S. Provisional Application Ser. No. 62/482,008 filed on Apr. 5, 2017 the entire disclosure of which is incorporated herein by reference.
BACKGROUNDCold slurries used in medical applications typically comprise a partially frozen saline solution. Cold slurries are used in surgical applications to induce therapeutic hypothermia and slow organ and tissue metabolic rates thereby protecting a patient's organs during a surgical procedure. Cold slurries can also be injected into a patient for selective or non-selective cryotherapy and/or cryolipolysis.
Approaches to preparing and delivering a cold slurry to fat tissue through a cannula or needle are disclosed in International Application No. PCT/US2015/047292; U.S. Patent Application Publication No. 2013/0190744; and U.S. Provisional Application No. 62/416,484, which are incorporated herein by reference in their entirety. A cold slurry has high fluidity making to possible to inject the cold slurry through a small cannula or needle. Once the cold slurry is delivered, heat transfers from the target tissue to the cold slurry. This lowers the temperature of the target tissue, so that cryolipolysis can occur.
Because the cold slurry is highly fluid, it tends to spread out from where it is delivered to surrounding tissue. A three cubic centimeter volume of cold slurry can cover an area that is about the size of a saucer plate. Heat from the surrounding tissues is also transferred to the cold slurry. Additionally, blood flowing into the treatment area can warm the cold slurry. As more heat is transferred to the cold slurry, the ability for the cold slurry to lower the tissue temperature of the target tissue decreases. Consequently, more cold slurry may be needed for an effective treatment. Another challenge to delivering a cold slurry is protecting tissue surrounding the target tissue from the cooling effects of the cold slurry.
SUMMARYThe present invention provides methods and devices for controlling a cold slurry that is delivered to a target tissue and for limiting heat transferring from surrounding tissue to the target tissue. In particular, a balloon structure is deployed at or near a point of delivery to act as a physical and/or thermal barrier. In some instances, the balloon can act as a pressure device obstructing the flow of blood into a treatment area, which can melt the cold slurry.
A balloon structure for use in the invention can take various forms and shapes, and can have chambers that can be opened or closed to control the shape of the balloon. In some examples, balloons are nested within each other and filled with various fluids or gasses of varying temperatures. For example, in one embodiment, a first inner balloon is filled with a cool mix of water and glycerol, and a second inner balloon, which encloses the first inner balloon, is filled with a coolant gas/fluid (e.g., liquid nitrogen) to freeze or chill the cool mix in the first inner balloon. There can even be a third balloon, which encloses the second inner balloon. The third balloon is filled with a thermal insulator, such as air, to protect surrounding tissue from the cold temperatures of the first and second inner balloons. The multiple balloons can be filled at the same time or at separate times.
A deployment device can be used to deploy the balloon. The device can have one or more working channels to control the function of the balloon or a collection of balloons. For example, the device has an application cannula for deploying multiple balloons one within the other, or one next to each other. In some examples, multiple balloons can be put to use with a set of deployment devices.
One aspect of the invention includes methods of controlling tissue temperature. Preferred methods include delivering a cold slurry to a target tissue located underneath a subject's skin. The target tissue is cooled to a lower tissue temperature as heat is transferred from the target tissue to the cold slurry. Methods further include limiting heat transfer from the surrounding tissue to the target tissue, which in turn slows down rising tissue temperature. Heat transfer can be limited using, for example, a balloon filled with a thermal insulator, such as a fluid, gas or air. The fluid/gas filled balloon acts as a barrier (or block) between the cold slurry and the surrounding tissue. The fluid/gas filled balloon can also act as a pressure device that exerts pressure against the surrounding tissue. The pressure exerted can constrict a blood vessel in the surrounding tissue and limit warm blood from flowing into the treatment area.
Another aspect of the invention is a device for carrying out the above approach. Preferred devices include a first cannula for delivering a cold slurry to a target tissue underneath a patient's skin, thereby cooling the target tissue. The first cannula includes a first open distal end and a first proximal end in fluid communication with a source of cold slurry. Devices further include a second cannula having a second open distal end and a second proximal end in fluid communication with a source of a thermal insulator. Devices further include a balloon disposed around the second open distal end of the second cannula. The balloon is positioned at or near tissue surrounding the target tissue. The balloon has a volume that is filled with the thermal insulator that has been delivered through second cannula. The filled balloon limits heat from transferring from the surrounding tissue to the target tissue.
The balloon can have a first chamber facing the target tissue and a second chamber facing the surrounding tissue. The first chamber is in fluid communication with the first open distal end and is filled with cold slurry delivered through the first cannula. The second chamber is in fluid communication with the second open distal end and is filled with the thermal insulator delivered through the second cannula. This configuration cools the target tissue while projecting the surrounding tissue.
Some devices have two balloons. A first balloon is disposed around the first open distal end of the first cannula and positioned at or near the target tissue. The first balloon has a volume for receiving the cold slurry delivered through the first cannula. A second balloon is disposed around the second open distal end of the second cannula. The second has a volume filled with the thermal insulator. The first balloon contains the cold slurry within its volume while the second balloon, positioned at or near tissue surrounding the target tissue, limits heat from transferring from the surrounding tissue to the target tissue.
Yet another aspect of the invention is a containment device that is applied over a patient's skin to limit/control the spread of cold slurry and/or its cooling effect from outside the patient's body. The containment device has an opening that defines a containment zone within which the cold slurry and/or its cooling effect is confined. The opening is surrounded by a pressure surface for applying pressure around the containment zone. Preferred devices include a pressure surface that is a hollow inside and that can expand when filled with a fluid or gas, such as air. Force is exerted by pumping air/fluid into the pressure surface causing it to expand and press against the patient's skin. The target tissue experiences little or no pressure because of the opening. The surrounding tissue, on the other hand, experiences positive pressure. This positive pressure limits the spread of cold slurry and/or its cooling effect from the target tissue to the surrounding tissue. Additionally, the pressure exerted by the containment device can constrict blood vessels in the surrounding tissue and limit warm blood from flowing into the treatment area.
Some containment devices can have a pressure surface that is divided into segments, for example, concentric rings. The segments can be filled, individually, such that the pressure exerted by each segment is different. For example, a first segment closest to the opening is filled so that the pressure exerted against the patient's skin is greater than the pressure exerted by a second segment. The difference in pressure applied by the containment device can help control the migration of cold slurry. Additional, the different pressures exerted by the containment device segments can facilitate tissue contouring.
Still yet another aspect of the invention is a warm fluid removal device for removing melted cold slurry from the treatment area. Preferred devices have a distal end that is positioned a distance away for the target tissue and within the surrounding tissue. The devices further include a proximal end that is coupled to a vacuum pump that provides the suction to remove the warm fluid from the treatment area. The vacuum pump is operatively coupled to a controller for operating the vacuum pump. The controller can operate the vacuum pump continuously or intermittently. The controller can also monitor the temperature of the target tissue using a temperature probe and operate the warm fluid removal device in response to the rising tissue temperature.
Example warm fluid removal devices can be U-shaped and surround the target tissue when in use. These devices have a plurality of holes defined along their length through which warm fluid is removed from the treatment area. The warm fluid removal devices can also include an open distal end to further enhance removing warm fluid from the treatment area. These devices can further have a non-operating mode and an operating mode. In the non-operating mode, the warm fluid removal device is substantial linear in shape. In the non-operating mode, the warm fluid removal device can be readily inserted through the patient's skin, advanced to the tissue surrounding the target tissue, and removed from the patient when the cold slurry treatment is done. In the operating mode, the warm fluid removal device is U-shaped with the open end facing the target tissue. The warm fluid removal device can be mechanically actuated between the non-operating mode and operating mode with a tension wire, for example. In another example, the warm fluid removal device is made for a shape memory alloy, such as nitinol. The warm fluid removal device can change from the linear shape to the U-shape, and back to the linear shape in response to changes in temperature.
The approach provides several benefits. By acting as a temperature barrier, the balloon 130 can slow down the melting process, thereby prolonging the usefulness of the cold slurry 110. The balloon 130 can further help keep the target tissue 105 cold and thus, increase the effectiveness of the cold slurry treatment. By acting as a temperature barrier, the balloon 130 also protects the adjacent tissue 135 from being adversely affected or damaged by the cold. For example,
The fluid delivery cannula 225 is open at its distal end defining a fluid outlet 230. The controlling end 215 further includes an inner balloon 235 disposed around the fluid outlet 230. The fluid delivery cannula 225 is in fluid communication with an interior volume of the inner balloon 235, which is labeled 240 in the figure. The inner balloon 235 is located inside the outer balloon 220. As shown, the inner balloon 235 occupies a portion of the interior volume of the outer balloon 220 leaving a space or gap 245 between an outer wall of the inner balloon 235 (which is labeled 250 in the figure) and an inner wall of the outer balloon 220 (which is labeled 255 in the figure).
To use the cold slurry delivery device 200, the application cannula 205 is inserted through the patient's skin and the controlling end 215 is advanced to a location at or near a target tissue in much the same manner as described above with reference to
Examples of the balloon can have any shape in addition to the linear and spherical examples described above with reference to
Other examples of the balloon can have a number of chambers that can be opened or closed to control the shape of the balloon. For example,
In the example shown, the cold slurry temperature monitor 500 includes at a temperature sensor 510 at its distal tip. Without limiting the principles of the invention, the temperature sensor 510 can be a forward infrared (FIR) sensor. As shown, the cold slurry temperature monitor 500 can be moved to intermediate positions between the retracted and extended positions. These intermediate positions together with the extended position correspond to different locations within the cold slurry, which are labelled in figure “A” through “E”. By moving the cold slurry temperature monitor 500 to the intermediate positions and the extended position, a temperature gradient (or “temperature thru depth”) of the cold slurry can be determined. The temperature gradient, in turn can, can be used to assess, for example, the capacity (capability) for the cold slurry to cool the target tissue.
In a convenient example of the containment device 600, the pressure surface 615 is a hollow inside and can expand when filled a fluid or gas, such as air. Force is exerted by pumping air/fluid into the pressure surface 615 causing it to expand and press against the patient's skin. The target tissue 105 experiences little or no pressure because of the opening 605. The surrounding tissue 135, on the other hand, experiences positive pressure. This positive pressure limits the spread of cold slurry and/or its cooling effect from the target tissue 105 to the surrounding tissue 135. Additionally, the pressure exerted can constrict blood vessels in the surrounding tissue 135 and limit warm blood from flowing into the treatment area.
The exerted pressure can be reduced or removed by pumping air/fluid out of the pressure surface 615 causing it to deflate. In a convenient example, the pumping of air/fluid into and out of the pressure surface 615 is done automatically. For example, air/fluid is pumped into the pressure surface 615, such that the containment device 600 applies pressure at or near the start of a cold slurry treatment. After a pre-determined amount of time, the air/fluid is pumped out of the pressure surface 615 relieving pressure from the containment device 600 at or near the end of the cold slurry treatment.
Shown in
In another example of the containment device, the pressure surface is solid. When a force is exerted against the containment device, the target tissue experiences little or no pressure because of the opening. The surrounding tissue, on the other hand, experiences positive pressure. This positive pressure limits the spread of cold slurry and/or its cooling effect from the target tissue to the surrounding tissue. Additionally, the pressure exerted can constrict blood vessels in the surrounding tissue and limit warm blood from flowing into the treatment area.
The solid pressure surface can be divided into segments, for example, concentric rings. The segments can be added or removed to make the size of the opening and, in turn, the containment zone bigger or smaller. The segments can also be added or removed to make the size of the pressure surface bigger or smaller and thus change the area over which pressure is applied.
In the examples shown, the containment device 600 has a circular shape with the opening 605 centrally located and the pressure surface 615 concentric with the opening 605. Further, the pressure surface 615 is a substantially planer surface, as shown. The containment device 600 can be of any shape suitable for applying pressure to a part of the patient's body. For example, the containment device 600 can be rectangular, triangular or other regular shape. The containment device 600 can also have an irregular shape that is adapted to conform to a part of the patient's body being treated. For the example, the containment device 600 can be concaved to saddle, for example, the patient's stomach. The concavity of the containment device 600 is defined in the context of the device in use.
As shown, the opening 605 and pressure surface 615 are axially aligned, i.e., sharing a common axis. In other examples, the axis of the opening 605 and axis of the pressure surface 615 are offset a distance. This non-axial example of the containment device 600 can be useful in applications where it is desirable to bias the containment of cold slurry more or less to one side of the target tissue 105.
The containment device 600 can be made out plastic, polymer, rubber or other material suitable for applying pressure to a part of the patient's body. The containment device can be used manually, for example, a clinician presses (e.g., by way of a handle on the containment device) the device 600 against the patient's skin. Use of the containment device 600 can also be facilitated with straps or clamps for wrapping the containment device 600 around a part of the patient's body.
A warm fluid removal device 700 removes the resulting warm fluid from the treatment area. The warm fluid removal device 700 has a distal end 705 that is positioned a distance away for the target tissue 105 and within the surrounding tissue 135. The warm fluid removal device 700 further includes a proximal end 710 that is coupled to a vacuum pump 715. The vacuum pump 715 provides the suction to remove the warm fluid from the treatment area.
The vacuum pump 715 is operatively coupled to a controller 720 for operating the vacuum pump 715. The controller 720 can operate the vacuum pump 715 continuously such that warm fluid is constantly removed. The controller 720 can operate the vacuum pump 715 intermittently such that warm fluid is drawn off at pre-determined intervals. In a convenient example, the controller 720 monitors the temperature of the target tissue 105 using a temperature probe (e.g., one similar to the cold slurry temperature monitor 500 described above with reference to
In a convenient example, the warm fluid removal device 750 has a non-operating mode and an operating mode. In the non-operating mode, the warm fluid removal device 750 is substantial linear in shape. In the non-operating mode, the warm fluid removal device 750 can be readily inserted through the patient's skin, advanced to the tissue surrounding the target tissue, and removed from the patient.
In the operating mode, the warm fluid removal device 750 is U-shaped with the open end 755 facing the target tissue 105 as shown in
The warm fluid removal device 750 further includes a proximal end 770 that is coupled to a vacuum pump 775. The vacuum pump 775 provides the suction to remove the warm fluid of the treatment area. The controller 781 can operate the vacuum pump 775 continuously such that warm fluid is constantly removed. The controller 720 can operate the vacuum pump 775 intermittently such that warm fluid is drawn off at pre-determined intervals. In a convenient example, the controller 780 monitors the temperature of the target tissue 105 using a temperature probe (e.g., one similar to the cold slurry temperature monitor 500 described above with reference to
The warm fluid removal device 700 of
In a convenient example, the controller 720 monitors the temperature of the target tissue 105 using a temperature probe (e.g., one similar to the cold slurry temperature monitor 500 described above with reference to
In a convenient example, any one of the devices described above can be deployed using a guide.
In various embodiments, fenestrated needles or cannulas are provided with one or more mini or micro balloons that, when filled with a therapeutic cold fluid or slurry, drastically increase surface area through which the cannula can transfer heat from surrounding tissue. The balloons may be modeled after intestinal villi for example and may be deployed from a single needle or cannula as shown in
An exemplary fenestrated needle or cannula is shown in
The micro or mini balloons of fenestrated cannulas may be a variety of different shapes as shown in
Claims
1-20. (canceled)
21. A device for controlling tissue temperature, the device comprising:
- a fenestrated cannula for delivering a cold slurry directly to a target tissue underneath a patient's skin, thereby directly contacting and cooling the target tissue, the cannula comprising a plurality of openings at a distal end and a proximal end in fluid communication with a source of cold slurry; and
- a plurality of balloons, each disposed in one of the plurality of openings and configured to expand when exposed to cold slurry from the source of cold slurry and thereby provide an increase in surface area for thermal transfer from the target tissue to the cold slurry at the distal end of the cannula.
22. The device of claim 21, wherein one or more of the plurality of openings is configured to impart a shape the plurality of balloons disposed therein when expanded.
23. The device of claim 22, wherein the shape comprises a plurality of expanded members.
24. The device of claim 22, wherein the shape comprises an ovoid.
25. The device of claim 22, wherein the shape comprises a sphere.
26. The device of claim 22, wherein one or more of the plurality of balloons comprise two or more areas of differing elasticity.
27. The device of claim 21, comprising an array of fenestrated cannulas.
Type: Application
Filed: Sep 8, 2022
Publication Date: Jan 5, 2023
Applicant: MIRAKI INNOVATION THINK TANK LLC (Cambridge, MA)
Inventor: Christopher VELIS (Cambridge, MA)
Application Number: 17/940,681