BALLOON ASSEMBLY FOR USE IN A HEMOSTASIS BAND

A balloon assembly (200) that can be attached to a band assembly (300) to form a hemostasis band (100) used to perform hemostasis on a puncture site (89) of a human being (90). The balloon assembly (200) can include a balloon (210) that provides for being inflated to apply pressure to the puncture site (89), one or more openings (220) that provides for the insertion of the band assembly (300), and an inlet (230) for inflating the balloon (210).

BACKGROUND OF THE INVENTION

The invention relates generally to hemostasis. More specifically, the invention is a balloon assembly that can be combined with a band assembly to form a hemostasis band that is used to apply pressure on a puncture site to facilitate hemostasis of the puncture site.

Hemostasis means the “stoppage of bleeding or hemorrhage”. Human beings and other animals require the flow of blood to sustain life. Blood loss can be fatal to a patient, but steps taken to stem the loss of blood in a patient can also negatively impact the flow of blood in the patient. The amount of pressure on the puncture site required to perform hemostasis can vary based on the location of the puncture site and the cause of the bleeding.

II. Different Causes of Bleeding

There are many contexts in the providing of healthcare to patients when it is necessary to address bleeding or hemorrhage of a patient. Regardless of the cause of the bleeding, information about the flow of blood through and around the puncture site can be highly useful to providers in the treatment of patients undergoing hemostasis.

A. Bleeding that Results from a Patient Condition

In many instances, bleeding is the result of a medical condition of the patient. Examples of bleeding caused by the medical condition of a patient can include diseases, disorders, injuries, allergies, and other conditions that providers seek to address (collectively “conditions”).

B. Bleeding that Results from Medical Treatment

Bleeding can also result from the providing of medical treatment and/or the subjecting of the patient to certain types of diagnostic tests. Whether the healthcare activity is undertaken for the purposes of diagnosis (such as a blood test) or treatment (such as the injection of medicine into the patient), activities performed by health care providers (collectively “treatment”) can result in bleeding that must be addressed.

Intravascular catheterization includes the catheterization of either the arterial or venous systems for diagnosis or treatment of diseases for all systems and organs of the body, such as cardiovascular, neural (brain), pulmonary (lungs), renal (kidneys) and peripheries. Cardiac catheterization is a subset of intravascular catheterization used to diagnose and treat heart conditions. According the Centers for Disease Control and Prevention, heart disease is the leading cause of death in the United States. Cardiac catheterization involves inserting small tubes (“catheters”) into the circulatory system of the patient. Using X-ray guidance and other sensors, information about blood flow and blood pressure is obtained. Dyes can be injected into the circulatory system for the purpose of identifying the existence of obstructions such as atherosclerotic plaque within blood vessels. On the basis of the location and number of obstructions, a treatment plan for the patient is devised. Such a treatment plan can utilize different devices, such as the placement of a stent to maintain vessel patency, specialized medications, and/or surgery.

At the beginning of the catheterization procedure a doctor will puncture the vessel to gain access. After gaining access, the necessary catheters are inserted through the “access site” or “puncture site”. At the end of the catheterization procedure and after all the catheters are removed, the puncture site must be properly closed. A conventional bandage is insufficient because an artery will bleed out through the bandage because it cannot apply sufficient pressure. The proper amount of pressure, or force, needs to be applied at the puncture site to stop bleeding. The pressure can be applied manually by a health care professional holding pressure with their hand, or a medical device or apparatus can be used to apply pressure.

Cardiac catheterization and other types of intravascular catheterization are commonly performed through either a puncture site the femoral artery in the groin (“femoral catheterization”) or the radial artery in the wrist (“radial catheterization”).

Femoral catheterization has traditionally been the more common catheterization because the femoral artery is large and the femoral artery provides a direct route to the heart. However, femoral catheterization can require the patient to lie flat without bending their leg for up to 8 hours during recovery. In some cases, there are bleeding complications with femoral catheterization even when the patient fully complies with the immobility restrictions.

Radial catheterization involves a puncture site located on the radial artery. Radial catheterization has many advantages over femoral catheterization, including less bleeding complications, improved outcomes and reduced costs. Unlike with femoral catheterization, radial catheterization does not require the patient to be immobile. Moreover, patients find radial catheterization to be the more comfortable option because they are free to sit up, walk around, and even eat.

III. Prior Art Weaknesses

Hemostasis can literally be a matter of life and death. Yet, the prior art does not provide doctors and other health care providers with the most convenient and effective tools for applying hemostasis to a puncture site.

SUMMARY OF THE INVENTION

The invention relates generally to hemostasis. More specifically, the invention is a balloon assembly that can be combined with a band assembly to form a hemostasis band that is used to apply pressure on a puncture site and assist in achieving hemostasis.

The band assembly can be connected to the balloon assembly by inserting the band assembly into one or more openings in the balloon assembly. The balloon assembly can be positioned appropriately with respect to the band assembly, forming a hemostasis band that can provide pressure on a puncture site. One or more balloons on the balloon assembly can be inflated to apply pressure on the puncture site after the balloon and hemostasis band are properly positioned.

The band assembly and balloon assembly can be implemented in a wide variety of different embodiments that are highly modular and configurable.

DETAILED DESCRIPTION

The invention relates generally to hemostasis. More specifically, the invention is a balloon assembly that can be combined with a band assembly to form a hemostasis band that is used to apply pressure on a puncture site.

FIG. 1a is a block diagram illustrating an example of interaction between a patient 90 and healthcare provider 92 using a hemostasis band 100 that is comprised of a balloon assembly 200 and a band assembly 300. FIG. 1b is an environmental diagram illustrating an example of a puncture site 89 involving the radial artery 91 during a radial catheterization procedure. The hemostasis process involves placing the hemostasis band 100 on the puncture site 89 so that pressure can be placed on the puncture site 89 to stop bleeding at the puncture site 89.

The hemostasis band 100 is an apparatus that can be secured to the body of the patient 90 while the hemostasis band 100 is used to apply pressure to achieve hemostasis, a process by which the bleeding of the patient 90 is stopped. While the hemostasis band 100 stops bleeding, the body of the patient 90 will naturally close the puncture site 89 incision into the radial artery 91. This “closing” of the puncture site 89 usually takes 1-4 hours depending on patient conditions and medications administered during the catheterization procedure. After the puncture site 89 has closed, the hemostasis band 100 can be removed from the patient 90 and there will be no bleeding.

The balloon assembly 200 provides for the functionality of pressurizing the hemostasis band 100 by inflating the balloon assembly 200. The position of the balloon assembly 200 can be moved/adjusted with respect to the band assembly 300. In some embodiments of the balloon assembly 200, it is manufactured separately from the band assembly 300 and the hemostasis band 100 is assembled together by the provider 90 or someone else at the location of the patient 90. In other embodiments, the balloon assembly 200 and band assembly 300 are manufactured, sold, transported, and used as a unit.

In many embodiments of the balloon assembly 200, it is the balloon assembly 200 that is in direct contact with the puncture site 89 during the hemostasis process. In other embodiments, a surface or component in the band assembly 300 can be in direct contact with the puncture site 89 of the patient 90.

2. Band Assembly

The band assembly 300 provides for all functions of the hemostasis band 100 that are unrelated to the inflation/deflation of the balloon assembly 200. Among other functions, the band assembly 300 provides the “band” structure of the hemostasis band 100. The band assembly 300 secures the position of the hemostasis band 100 to the patient 90 even if it is the balloon assembly 200 that is in direct contact with the puncture site 89 of the patient 90.

The hemostasis band 100 can be implemented with a variety of useful features and attributes.

The hemostasis band 100 can be comprised of two highly or even fully modular assemblies, the balloon assembly 200 and the band assembly 300. The balloon assembly 200 and the band assembly 300 can be manufactured separately and combined as needed by providers 92. The hemostasis band 100 can be configured to allow a balloon assembly 200 to be used with multiple band assemblies 300, and vice versa.

The balloon assembly 200 can be moved to a variety of different positions on the band assembly 300. This flexibility can be utilized before the hemostasis band 100 is secured on the puncture site 89, during the hemostasis process while the band 100 is on the patient 90, after the hemostasis process is complete while the band 100 is on the patient 90, or even after the band 100 has been removed from the patient 90.

The hemostasis band 100, and its various assemblies and components, can be implemented with a wide variety of different materials. Some embodiments of the band 100 can utilize transparent or at least substantially transparent materials. This can allow providers 92 to see the puncture site 89 even while the hemostasis band 100 is performing hemostasis on the puncture site 89. This visibility can help the provider 92 to avoid the undesirable extremes of too little pressure being applied to the puncture site 89 or too much pressure being applied to the puncture site 89.

C. Process Flow

FIG. 1c is a flow chart diagram illustrating an example of a process 500 for utilizing a hemostasis band 100 with a balloon assembly 200 that can be positioned with respect to a band assembly 300.

At 520, the balloon assembly 200 is positioned relative to the band assembly 300.

At 540, the band assembly 300 is secured to the body of the patient 90.

At 550, the balloon assembly 200 is inflated. This increases the pressure on the puncture site 89, which results in the process of hemostasis being achieved on the puncture site 89.

FIG. 2a is a block diagram illustrating an example of different components that can be included as part of a balloon assembly 200. All of the elements identified below are also discussed in greater detail in the index/glossary of element numbers provided as Table 1 below.

In the aggregate, the function of the balloon assembly 200 is to allow a provider 90 to apply pressure to the puncture site 89. This can be done by inflating the balloon assembly 200. The balloon assembly 200 will also have the function to adjust the applied pressure as necessary. During the hemostasis process, the pressure in the balloon assembly 200 can be increased or decreased as needed.

The balloon assembly 200 can include a varying number of balloons 210. In many embodiments, the balloon assembly 200 will include only one balloon 210, but in alternative embodiments, other configurations can be used. The balloon 210 will often be the component of the band 100 that is in direct contact with the puncture site 89, applying pressure over the incision. The pressure stops bleeding while the body naturally closes the incision in the skin and artery

The balloons 210 incorporated into the balloon assembly 200 can be comprised in a variety of shapes, sizes, and dimensions. A wide range of materials and manufacturing processes can be used to create the balloons 210 used by the assembly 200.

A balloon 210 can be made by RF (radio frequency) welding two layers of polymer film together. The RF welding creates the seal around the perimeter of the balloon. RF technology can be used on materials that have the correct form of dipolar molecules. The radio frequency excites the molecules imparting energy which causes the material to go from a solid to liquid state. After the RF input is stopped, the material cools back to a solid state creating a weld between the two layers of polymer.

The balloon 210 could be manufactured using a blow molding method. Blow molding is valuable for apparatuses that have a cavity or hollow area. Common examples are bottles, containers or larger polymer structures that are hollow. Some children toys are made using blow molding. Medical devices can also be made using blow molding, such as medical bottles, or containers for blood or bodily fluids. It is envisioned that the balloon 210 component for the band can be made using a blow molding manufacturing method.

The balloon 210 could be manufactured using a dip molding method. A dipping mandrel in the shape of the balloon 210 can be made. The mandrel would be dipped into a vat containing liquid polymer. Some of the polymer would adhere to the mandrel. Repetitive dipping adds layers of polymer. When the desired thickness of balloon has been achieved, it can be removed from the mandrel, thus creating the balloon 210.

Examples of balloons can be seen in FIGS. 2a-2g. If a balloon 210 is neither transparent nor at least semi-transparent, the balloon 210 can include a substantially transparent window 212 (see FIG. 2f) that allows for a provider 90 to see the puncture site 89 under the band 100 while hemostasis is being performed.

Returning to FIG. 2a, the balloon assembly 200 will include an opening 220 through which the band assembly 300 can be positioned. Many embodiments of the balloon assembly 200 will include two or even more openings 220. Openings 220 facilitate the ability of the balloon assembly 200 and the band assembly 300 to be combined into a single hemostasis band 100. Many openings 220 can be characterized as being either slits 222 or slots 224. Examples of openings 220 are illustrated in FIGS. 2a-2f.

A slit 222 is a narrow cut-like opening in the balloon assembly 200. Analogous to a button hole, such an opening 220 often requires manual prodding to create sufficient open space for the band assembly 300 to be positioned into the opening 220. Examples of slits 222 are illustrated in FIGS. 2a, 2d, and 2e.

A slot 224 is a more substantial opening 224 than a slit 222. A slot 224 does not require manual prodding to create space. Examples of slots 224 are illustrated in FIGS. 2b, 2c, and 2f.

The space of an opening 220 is often shaped by a member 226 that is exterior to the opening 220. Such members 226 can be configured in a wide variety of different shapes, sizes, types of materials, etc. Examples of members 226 are illustrated in FIGS. 2a-2d, and 2f.

Returning to FIG. 2a, the balloon assembly 200 can include a sheath 250 that is used to house the balloon 210, openings 220, and potentially other parts of the balloon assembly 200. The sheath 250 can be comprised of virtually any material used to make the balloon 210 or the members 226. Examples of sheaths 250 are illustrated in FIGS. 2a, 2b, 2d, and 2e.

Returning to FIG. 2a, the balloon assembly 200 can include an inlet 230 that provides for the inflation and deflation of the balloon 210. Examples of inlets 230 are illustrated and expressly identified in FIGS. 2a-2d.

A tube 232 can make it easier and more convenient to inflate and/or deflate the balloon 210. The tube 232 allows inflation and deflation to take place further away from the body of the patient 90. An example of a tube 232 is illustrated in FIGS. 2a-2b.

A valve 234 can make it easier for the balloon 210 to stay inflated as well as to be deflated. The valve 234 can possess a variety of operating modes such as fully open, fully closed, and a variety of operating states in between.

E. Drawings of Balloon Assembly

FIG. 2b is a diagram illustrating an example of a top view of a balloon assembly 200 that includes a sheath 250, a tube 232, and a valve 234.

FIG. 2c is a diagram illustrating an example of a top view of a balloon assembly 200 that includes a slot 224 as an opening 220 but does not include a sheath 250.

FIG. 2d is a diagram illustrating an example of atop view of a balloon assembly 200 that includes a slit 222 as an opening 220 and a sheath 250 that encloses a balloon 210.

FIG. 2e is a diagram illustrating an example of top view of a balloon assembly 200 that includes a slit 222 as an opening 220 and a sheath 250 that encloses a balloon 210.

FIG. 2f is a diagram illustrating an example of a top view of a balloon assembly 200 that includes a slot 224 as an opening 220 but does not include a sheath 250.

FIG. 2g is a diagram illustrating an example of a side view of a balloon 210 that is inflated over a puncture site 89.

III. Band Assembly

The band assembly 300 is the portion of the hemostasis band 100 that comprises the band itself (comprised of one more segments 330), as well as providing the structures for securing the hemostasis band 100 onto the patient 90. The band assembly 300 can be implemented in a wide variety of different structures, from a simple elastic band that holds the balloon assembly 200 in place to a complex assembly that includes sensors, electronic communications, computer processors, and other components that may be useful to the hemostasis process, whether directly or indirectly.

FIG. 3a is a block diagram illustrating an example of different components that can be included as part of the band assembly 300. As illustrated in FIG. 3a, the band assembly 300 can include a fastener component 310, including but not limited to a hook and loop fastener 312 commonly referred to as VELCRO®, a hinge 320 that connects segments 330 of the band 100 together, and padding components 340 such as a foam pad 342 or a balloon pad 344.

The components of the band assembly 300 can be manufactured using injection molding methods or die cut from stock material.

A fastener component 310 is a portion of the band assembly 300 that is used to secure the band assembly 300 on the patient 90. A mechanism or component of the band assembly 300 by which the band assembly 300 and the hemostasis band 100 as a whole, can be secured to the patient 90. Many embodiments of the band assembly 300 will require some type of fastener component 310. In some embodiments of the band assembly 300, the segment 330 of the assembly 300 is an elastic band that serves at its own fastener to the patient 90. In other embodiments, the band assembly 300 will use a snap, button, zipper, adhesive surface, hook and loop fastener 312, or other similar technology to secure two ends of the band assembly 300 together while the balloon assembly 200 is secured to the band assembly 300. Examples of fastener components 310 are illustrated in FIGS. 3a, 3g, and 3h,

If a band assembly 300 includes two or more segments 330, one or more hinges 320 can be used to link those segments together. The functionality of the hinge 320 allows one segment 330 to move with respect to another. That movement and positioning can provide for a band 100 being opened and closed. Thus, the hinge 320 can be an important aid in securing the position of the band 100 on the patient 90. Examples of hinges 320 are illustrated in FIGS. 3a, 3d, 3g, and 3h.

In many embodiments of the hinge 320, the hinge 320 will be an actual hinge that includes a hinge pin. In other embodiments, the hinge 320 can implement a “living hinge” concept where the function is equivalent to a hinge without having the express structural components of a hinge.

The band assembly 300 can be comprised of one, two, or even more segments 330 which can also be referred to as “band segments” or “band surfaces”. Some embodiments of a band 100 can involve a single segment 330 that could be fashioned with a fastener component 310 on each end (see FIG. 3b) or even a single segment 330 that is an elastic loop (see FIG. 3c). Other embodiments of the band assembly 300 will often involve two or more segments 330 and one or more hinges 320.

Many embodiments of rigid or at least partially rigid segments 330 will involve curved segments 330. Examples of segments 330 can include a flexible elastic band, a strip, a loop, a semi-flexible/semi-rigid band, and a fully rigid band. Segments 330 can serve as the relevant surface of the band assembly 300 that various components are attached to (virtually all of the components of the band assembly 300) as well as the relevant portion of the band assembly 300 that moves within the openings 220 and with respect to the balloon assembly 200. A segment 330 that is curved can be referred to as a curved segment 332.

Segments 330 can be implemented in wide variety of different shapes, sizes, materials, transparency levels, etc.

Returning to FIG. 3a, the band assembly 300 can also include as few as zero padding components up to as many padding components 340 that can fit on the various segments 330 of the band 100. Padding components 340 exist for the purpose of the comfort of the patient 90. Examples of padding components 340 can include a foam pad 342 or a balloon pad 344 (i.e. an additional balloon). The pad component and closure mechanism can be manufactured with more than one method. Either could be molded, die cut, rotary die cut or water jet cut. The components would have the same feature regardless of manufacturing method.

E. Band Assembly Drawings

FIG. 3b is a diagram illustrating an example of a top view of a band assembly 300 in the form of a single rectangular strip as the sole segment 330.

FIG. 3c is a diagram illustrating an example of a side view of a band assembly 300 with a single segment 330 in the form of a continuous elastic loop.

FIG. 3d is a diagram illustrating an example of a side view of a band assembly 300 that includes two segments 330 connected by a hinge 320.

FIG. 3e is a diagram illustrating an example of a perspective view of a foam pad 342.

FIG. 3f is a diagram illustrating an example of a perspective view of a balloon pad 344.

FIG. 3g is a diagram illustrating an example of a side view of a band assembly 300 in an open position.

FIG. 3h is a diagram illustrating an example of a top view of a band assembly 300 in an open position.

IV. Hemostasis Band as a Mechanism for Hemostasis

The hemostasis band 100 can be implemented in a wide variety of different embodiments with utilizing different components, component configurations, materials, geometries, and other attributes. For some embodiments of the band 100, components can be manufactured using injection molding methods or die cut from stock material.

FIG. 4a is a diagram illustrating an example of a side view of a hemostasis band 100 in an open state that is comprised of a balloon assembly 200 and a band assembly 300. In terms of the balloon assembly 200, there is a balloon 210 illustrated with a valve 234. The positions of two slots 224 are also illustrated. The entire balloon assembly 200 is positioned on one segment 330 between the hinge 320 and the fastening component 312 of the band assembly 300. The band assembly 300 includes a hinge 320 connecting two segments 330, a fastening component 312 comprised of two straps of VELCRO® material fixed to those two segments 330. A foam pad 342 is fixed to one of the segments 330.

FIG. 4b is a diagram illustrating an example of a perspective view of a hemostasis band 100 in an open state that is comprised of a balloon assembly 200 and a band assembly 300. The band 100 of FIG. 4b is essentially identical to FIG. 4a, except that the illustrations are taken from different points of view.

FIG. 4c is a diagram illustrating an example of a perspective view of a hemostasis band 100 in an open state that is comprised of a balloon assembly 200 and a band assembly 300. The band 100 of FIG. 4c is substantially identical to the band 100 of FIGS. 4a and 4b, differing primarily in point of view. FIG. 4c illustrates the spatial relationship between the balloon 210, the two openings 220 of the balloon assembly 200, and the segment 330 positioned between the two openings 220.

FIG. 4d is a diagram illustrating an example of a top view of a hemostasis band 100 in an open state that is comprised of a balloon assembly 200 and a band assembly 300. The band 100 of FIG. 4d is substantially identical to the band 100 of FIGS. 4a-4c, differing primarily in point of view.

FIG. 4e is a diagram illustrating an example of a side view of a hemostasis band 100 in a closed state that is comprised of a balloon assembly 200 and a band assembly 300. FIG. 4e illustrates a closed band 100 where FIG. 4a illustrates an open band 100 from the same orientation.

FIG. 4f is a diagram illustrating an example of a perspective view of a hemostasis band 100 in a closed state that is comprised of a balloon assembly 200 and a band assembly 300. FIG. 4f corresponds close to FIG. 4b, with the primary difference being in the operating state of the band 100.

V. Process Flow View

FIG. 5 is a flow chart diagram illustrating an example for using a hemostasis band 100 that is comprised of a balloon assembly 200 and a band assembly 300.

At 510, the band assembly 300 can be inserted into one or more openings 220 in the balloon assembly 200, securing in a non-permanent way, the combination forming the hemostasis band 100.

At 520, the balloon assembly 200 is positioned with respect to the band assembly 300. This is typically done by sliding the one or more openings 220 along one or more segments 330.

At 530, the band assembly 300 is secured on the patient 90, a process by which the band 100 is also secured on the patient 90. This process can include positioning the band 100 on the patient 90 and securing that position by closing the fastener components 310. In many instances of many embodiments, the balloon 210 will be positioned over the puncture site 89.

At 540, the balloon assembly 200 can be repositioned with respect to the band assembly 300 for the purposes of properly configuring and positioning the band 100 for providing hemostasis at the puncture site 89.

At 550, the one or more balloons 210 of the balloon assembly 200 are inflated. With embodiments involving a balloon pad 344, the balloon pad 344 can also be inflated at this time, or at a time prior to the inflating of the pressurizing balloon 210.

At 560, hemostasis is performed by the band 100, which can be adjusted as desired in terms of magnitude of pressure or the position of the balloon 210 or other component with direct contact to the puncture site 89.

At 570, the balloon 210 can be deflated. This can either be purposeful and active, or the end result of the balloons 210 inherent structure to slow leak air over a period of time.

At 580, the band can be removed from the patient 90. This is done by unfastening the fastener component 310 and removing the band 100 from the patient.

At 590, the balloon assembly 200 and the band assembly 300 can be separated from each other and disposed of, cleaned, etc. as appropriate.

The process is then complete.

Table 1 below provides a chart of element numbers, element names, and element descriptions.

Element

Number
Name
Description

89
Puncture Site
A location on the patient 90 for which hemostasis is

performed to prevent blood loss. In the context of

catheterizations, the term “arteriotomy” is synonymous with

the term “puncture site”.

90
Patient
A living organism, typically a human being, subject to a

91
Radial Artery
A blood vessel on a human patient 90 used to perform

radial catheterization. The puncture site 89 for a radial

catheterization procedure is a location on the Radial Artery

technician, physician assistant, paramedic, or other person

involved in performing hemostasis on a patient 90.

100
Hemostasis
An apparatus formed when the band assembly 300 is

Band
inserted into one or more openings 220 in the balloon

assembly 200. The hemostasis band 100 can be

implemented using a variety of different materials including

hemostasis band 100 can also be referred to simply as the

band 100. Some embodiments of the band 100 can be

implemented such that the band is transparent or at least

substantially transparent. This can aid providers 92 in

preparing as well as monitoring the hemostasis process.

In some embodiments of the band 100, the surfaces of the

hemostasis band 100 that come into contact with the skin

of a patient 90 can be coated with anti-adhesive coatings

to prevent the band 100 from sticking to the skin of the

200
Balloon
An assembly 200 that provides for combining with a band

Assembly
assembly 300 to form a hemostasis band 100. The

balloon assembly 200 includes one or more openings 220

into which the band assembly 300 can be inserted into or

connected through. The balloon assembly 200 can include

at least one balloon 210, at least one opening 220 for the

band assembly 300, and at least one inlet 230 for the

inflation of the balloon 210. The balloon assembly 200

serves to pressurize the hemostasis band 100 after the

band 100 is properly positioned on the patient 90.

210
Balloon
The balloon 210 can be the mechanism within the

hemostasis band 100 by which pressure is placed on the

puncture site 89. Balloons 210 are typically configured to

be inflated with gasses such as air or liquids such as

water, however balloons 210 can also be inflated with solid

fluids such as gelatinous or substantially gelatinous

materials. Balloons 210 can be comprised of a wide

variety of materials, including but not limited to plastic,

rubber, or latex. In many embodiments, it is the surface of

the balloon 210 that comes into direct physical contact with

the puncture site 89 of the patient 90. In many

embodiments, the balloon 210 will be transparent or at

least substantially transparent to permit the puncture site

89 to be seen by the provider 92 when (1) positioning the

band 100 over the puncture site 89; (2) inflating the balloon

21O; and (3) monitoring the hemostasis process after the

balloon is inflated.

212
Window
Embodiments of balloon assembly 200 with an opaque

balloon 210 may include a transparent or at least

substantially transparent window 212 to permit the provider

to see the puncture site 89 of the patient 90.

220
Opening
A space within the balloon assembly 200 that allows for

the insertion of the band assembly 300 into the balloon

assembly 200 and for the sliding of the balloon assembly

200 along the band assembly 300. Many embodiments of

the balloon assembly 200 will include two openings 220,

but the balloon assembly 200 can have as few as one

opening 220 or as many as three or more openings 220.

222
Slits
A thin opening 220 with the thickness of a cut. Analogous

to a button hole, a human being will often need to manually

pry open a slit 222 before the band assembly 300 can be

224
Slots
An opening 220 that is wider than a slit 222. A slot 224 is

a permanent opening that unlike a slit 222, is sustained

without being manually pried open.

226
Members
A surface area or structure adjacent to a slot 224 that

shapes the slot 224. Members 226 of all different shapes

and sizes can be used to create an opening 220 of the

desired shape and size.

230
Inlet
A pathway into the balloon 210 that allows for the inflation

and deflation of the balloon 210. The inlet 230 of the

balloon 210 may in some embodiments be filled with a

232
Tube
A passageway to the inlet 230. Use of the tube 232 can

permit the inflation and deflation of the balloon 210 to

occur at a greater distance from the surface of the balloon

210. The tube 232 can also make it easier for a valve 234

to be used as part of the balloon assembly 200. In some

embodiments, the tube 232 is a separate and distinct

component of the balloon assembly 200. In other

embodiments, the tube 232 can simply be the neck of the

balloon 210. The structure and functionality of the tube

232 can be achieved using a balloon 210 with a similarly

234
Valve
A device that can be included in the balloon assembly 200

that can control the flow into and out of the balloon 210. A

typical valve will have at least two operating states, an

operating state of being closed/sealed and an operating

state of being open/unsealed. Some embodiments of the

valve 234 may operate in a linear fashion between the two

extreme states of totally closed/totally sealed and totally

open/totally unsealed. Valves 234 can be made up of a

wide variety of different materials, including but not limited

can include a pressure sensor.

250
Sheath
A cover for some or all of the balloon assembly 200. For

example, the balloon 210, openings 220, and inlet 230 can

each be integrated into a single sheath 250 that prevents

the individual removal of any of the integrated

300
Band Assembly
An assembly 300 that provides for combining with a

balloon assembly 200 to form a hemostasis band 100. In

many embodiments, the band assembly 300 is removable

from the balloon assembly 200 and it is the band assembly

300 which serves to secure the hemostasis band 100 on

the puncture site 89 of the patient 90. In some

embodiments, some portion of the band assembly 300

comes into direct contact with the puncture site 89,

although it many embodiments it is the balloon 210 of the

balloon assembly 200 that is intended to come into direct

contact with the puncture site 89 on the patient 90.

310
Fastener
A mechanism or component of the band assembly 300 by

Component
which the band assembly 300 and the hemostasis band

100 as a whole, can be secured to the patient 90. Many

embodiments of the band assembly 300 will require some

type of fastener component 310. In some embodiments of

the band assembly 300, the segment 330 of the assembly

300 is an elastic band that serves at its own fastener to the

patient 90. In other embodiments, the band assembly 300

will use a snap, button, zipper, adhesive surface, hook and

loop fastener 312, or other similar technology to secure

two ends of the band assembly 300 together while the

balloon assembly 200 is secured to the band assembly

312
Hook and Loop
A type of fastener made out of two strips of VELCO ®

320
Hinge
A joint that links one segment 330 of the band assembly to

another segment 330. The hinge 320 permits relative

movement between the two or more seqments 330.

330
Segment
A surface on the band assembly 300 that can also be

referred to as the “band” of the band assembly 300. Many

embodiments of the band assembly 300 will include two

segments 330 joined by a hinge 320, although some

alternative embodiments can include as few as one

segment 330 (an elastic loop for example) or more than

two segments 330. Segments 330 can be flexible, rigid, or

partially rigid/partially flexible. Many embodiments of rigid

or at least partially rigid segments 330 will involve curved

segments 330. Examples of segments 330 can include a

flexible elastic band, a strip, a loop, a semi-flexible/semi-

rigid band, and a fully rigid band. Segments 330 can also

be referred to as “body components” 330 as segments

serve as the relevant surface of the band assembly 300

that various components are attached to (virtually all of the

components of the band assembly 300) as well as the

relevant portion of the band assembly 300 that moves

within the openings 220 and with respect to the balloon

332
Curved
A segment 330 that is at least semi-rigid such that it can

Seqment
maintain an at least somewhat curved shape.

340
Padding
A mechanism to enhance the comfort of the patient 90 with

Component
respect to the apparatus 100 and the band assembly 300.

Examples of padding components include a foam pad 342,

a second balloon, and other types of active or passive

342
Foam Pad
An example of a padding component 340

344
Balloon Pad
An example of a padding component 340.

No patent application can disclose all of the potential embodiments of an invention. In accordance with the provisions of the patent statutes, the principles and modes of operation of the balloon assembly 200, the band assembly 300, the aggregate hemostasis band 100, and the method 500 of use thereof are explained and illustrated in certain preferred embodiments. However, it must be understood that the hemostasis band 100, balloon assembly 200, band assembly 300, and method 500 of their use may be practiced otherwise than is specifically explained and illustrated without departing from its spirit or scope. Each of the various elements described in the index above can be implemented in a variety of different ways while still being consistent with the spirit and scope of the invention. For example, a hemostasis band 100 comprised of the balloon assembly 200 and the band assembly 300 can be implemented in far more different ways using far more different components in far more different configurations than what is illustrated in the accompanying figures.

The description of the apparatus provided above should be understood to include all novel and non-obvious combination of elements described therein, and claims may be presented in this or a later application to any novel non-obvious combination of these elements. Moreover, the foregoing embodiments are illustrative, and no single feature or element is essential to all possible combinations that may be claimed in this or a later application.