Patent Abstract:
A device for making an incision in the tympanic membrane, withdrawing fluid from the tympanic cavity and administering a medicament to the space behind the tympanic membrane is provided. The device has a barrel-shaped casing ( 1 ) having a rotatable end turret ( 38 ). A first trigger ( 2 ) allows a shaft ( 18 ) to pierce the tympanic membrane and a tubular vacuum cartridge ( 32 ). The cartridge allows aspiration of fluid. A second trigger ( 4 ) causes medicament ( 34 ) to be released into the space behind the tympanic membrane.

Full Description:
FIELD OF THE INVENTION 
     The invention provides a novel apparatus and method for the treatment of middle ear infections. 
     BACKGROUND OF THE INVENTION 
     Apparatus are known for use in connection with the middle and inner ear where the apparatus is capable of (1) delivering various liquids and solids to the inner ear structures; (2) extracting, withdrawing, or exchanging fluid materials from the inner ear; (3) transferring fluid materials into and out of the inner ear via the round window membrane so that items [1] and [2] can be accomplished; (4) enabling middle and inner ear structures to be electrophysiologically monitored using electrocochleography (“ECoG”) procedures; (5) altering the permeability of the round window membrane in the ear for a variety of therapeutic purposes with drugs, chemical agents, or iontophoresis; and (6) creating a discrete sealed or non-sealed “fluid-receiving zone” within the round window niche so that fluid materials can be transferred into and out of the inner ear via the adjacent round window membrane in a controlled and site-specific manner. 
     In order to treat ear disorders, it has been necessary to deliver therapeutic agents to various ear tissues in a controlled, safe, and efficient manner. For example, a variety of structures have been developed which are capable of delivering/administering therapeutic agents into the external auditory canal of the outer ear. U.S. Pat. No. 4,034,759 to Haerr discloses a hollow, cylindrical tube manufactured of sponge material (e.g. dehydrated cellulose) which is inserted into the external auditory canal of a patient. When liquid medicines are placed in contact with the tube, it correspondingly expands against the walls of the auditory canal. As a result, accidental removal of the tube is prevented. Furthermore, medicine materials absorbed by the tube are maintained in contact with the walls of the external auditory canal for treatment purposes. Other absorbent devices designed for treatment of the external auditory canal and related tissue structures are disclosed in U.S. Pat. No. 3,528,419 to Joechle, U.S. Pat. No. 4,159,719 to Haerr, and U.S. Pat. No. 2,642,065 Negri. The Negri patent specifically describes a medicine delivery device with an internally-mounted, frangible medicine container which, when broken, releases liquid medicines into an absorbent member. 
     However, the delivery of therapeutic agents in a controlled and effective manner is considerably more difficult with respect to tissue structures of the inner ear (e.g. those portions of the ear surrounded by the otic capsule bone and contained within the temporal bone which is the most dense bone tissue in the entire human body). The same situation exists in connection with tissue materials which lead into the inner ear (e.g. the round window membrane). Exemplary inner ear tissue structures of primary importance for treatment purposes include but are not limited to the cochlea, the endolymphatic sac/duct, the vestibular labyrinth, and all of the compartments (and connecting tubes) which include these components. Access to the above-described inner ear tissue regions is typically achieved through a variety of structures, including but not limited to the round window membrane, the oval window/stapes footplate, the annular ligament, the otic capsule/temporal bone, and the endolymphatic sac/endolymphatic duct, all of which shall be considered “middle-inner ear interface tissue structures” as described in greater detail below. In addition, as indicated herein, the middle ear or tympanic cavity shall be defined as the physiological air-containing tissue zone behind the tympanic membrane (e.g. the ear drum) and proximal to the inner ear. 
     The inner ear tissues listed above are of minimal size and only readily accessible through microsurgical procedures. In order to treat various diseases and conditions associated with inner ear tissue ˜  the delivery of medicines to such structures is often of primary importance. Representative medicines which are typically used to treat inner ear conditions include but are not limited to urea, mannitol, sorbitol, glycerol, lidocaine, xylocaine, epinephrine, immunoglobulins, sodium chloride, steroids, heparin, hyaluronidase, aminoglycoside antibiotics (streptomycin/gentamycin), antioxidants, neurotrophins, nerve growth factors, various therapeutic peptides, and polysaccharides. Of particular interest in this list are compounds which are used to alter the permeability of the round window membrane within the ear using, for example, hyaluronidase and iontophoretic techniques (defined below). Likewise, treatment of inner ear tissues and/or fluid cavities may involve altering the pressure, volume, electrical activity, and temperature characteristics thereof. Specifically, a precise balance must be maintained with respect to the pressure of various fluids within the inner ear and its associated compartments. Imbalances in the pressure and volume levels of such fluids can cause various problems, including but not limited to conditions known as endolymphatic hypertension, perilymphatic hypertension, perilymphatic fistula, intracochlear fistula, Meniere&#39;s disease, tinnitus, vertigo, hearing loss related to hair cell or ganglion cell damage/malfunction, and ruptures in various membrane structures within the ear. 
     Of further interest regarding the delivery of therapeutic agents to the middle ear, inner ear, and middle-inner ear interface tissue structures are a series of related and co-owned patents, namely, U.S. Pat. Nos. 5,421,818; 5,474,529, and 5,476,446 all to Arenberg. Each of these patents discloses a medical treatment apparatus designed to deliver fluid materials to internal ear structures. U.S. Pat. No. 5,421,818 describes a treatment system which includes a tubular stem attached to a reservoir portion with an internal cavity designed to retain a supply of therapeutic fluid compositions therein. The side wall of the reservoir portion further comprises fluid transfer means (e.g. pores or a semi-permeable membrane). Contact between the fluid transfer means and the round window membrane in a patient allows fluid materials to be delivered on-demand to the round window membrane, followed by diffusion of the fluid materials through the membrane into the inner ear. U.S. Pat. No. 5,474,529 involves a therapeutic treatment apparatus with a plurality of reservoir portions (e.g. a first and a second reservoir portion in a preferred embodiment) which are connected to multiple tubular stems that are designed for implantation into the endolymphatic sac and duct using standard microsurgical techniques. Finally, U.S. Pat. No. 5,476,446 discloses a therapeutic treatment apparatus which includes a reservoir portion for retaining liquid medicine materials therein, a first tubular stem on one side of the reservoir portion, and a second tubular stem on the opposite side of the reservoir portion. The second stem is designed to reside within the external auditory canal of a patient lateral to the ear drum, while the first stem is sired for placement within an opening formed in the stapes footplate/annular ligament so that medicine materials in fluid form can be delivered into the inner ear from the reservoir portion (which resides in the middle ear cavity medial to the ear drum). 
     A different approach for transferring materials into and out of the inner ear via the round window membrane/round window niche is disclosed in U.S. patent application Ser. No. 08/874,208 filed on Jun. 13, 1997. This application describes a system in which one or more fluid transfer conduits are provided which are operatively connected to a “cover member” that is designed for placement on top of the niche (e.g. at its point of entry) or within the niche. The cover member is used to create a “fluid-receiving zone” (or “inner ear fluid transfer space”) which is partially or entirely sealed in order to facilitate fluid transfer into and out of the inner ear. In one embodiment, the cover member consists of a thin, solid, plate-like structure that is secured in position on top of the niche at its point of entry as previously noted. Alternatively, the cover member may comprise a portion of flexible and compressible material which, during placement within the round window niche, is compressed and thereafter allowed to expand once the portion of compressible material is positioned within the niche. As a result, the cover member can engage the internal side wall of the round window niche, thereby creating the fluid-receiving zone (“inner ear fluid transfer space”) between the compressible cover member and the round window niche. Representative materials used to construct the portion of compressible material associated with the cover member in this particular embodiment optimally involve foam-type products including but not limited to polyethylene foam, polyether foam, polyester foam, polyvinyl chloride foam, polyurethane foam, and sponge rubber (e.g. synthetic or natural), all of which are of the closed cell variety, with such materials being non-fluid-absorbent in accordance with the substantial lack of open cells therein. Specifically, the non-fluid-absorbent character of these materials results from the closed cell structure thereof which prevents fluid materials from being absorbed compared with open cell (absorbent) foam products. 
     The present invention represents an advance in the art of middle ear or tympanic cavity treatment, diagnosis, and medicine delivery as described in detail below. In part, the prior art treatment of acute middle ear infections has been based on tympanocentisis or insertion of tubes into the tympanum or tapping the ear with a conventional syringe or a aspirator. Aspirators are known which are adapted to apply suction using a vacuum which is based on an externally provided vacuum source or a vacuum that is generated by the withdrawal of a piston in the aspirator device. Generally, the use of surgical intervention has been accompanied with the evacuation of fluid in conjunction with the systemic administration of antimicrobial medicaments to treat the localized infection in the ear. 
     The present invention is concerned with providing a novel apparatus and method of treating middle ear infections that is capable of rapidly (a) making a surgical incision in the tympanum; (b) aspirating fluid from the behind the tympanum and (c) administering a dose of an antimicrobial compound using a compact handheld apparatus. 
     SUMMARY OF THE INVENTION 
     The apparatus of the invention comprises a device having a barrel shaped casing having rotatable ends adapted to engage tubular elements:
     (a) a first actuating trigger which activates a first tubular element comprising a spring-loaded, hollow piercing shaft having a first end which is adapted to penetrate a tympanic membrane when it is extended from said barrel shaped casing by the action of said spring and a second internal end which is adapted to engage an end of a tubular vacuum container having a frangible seal;   (b) said tubular vacuum container having a frangible seal, being positioned in said barrel shaped casing and being spring loaded for axial rotation in said barrel with a first axial spring, when said hollow piercing shaft is extended from said barrel casing, said tubular vacuum container having a frangible seal, being adapted to axially move into register with said second internal end of said piercing shaft, said piercing shaft being adapted to break said frangible seal as said tubular vacuum container moves into register with said second end of said hollow piercing shaft to expose said hollow piercing element to the effect of vacuum in said tubular vacuum container in order to aspirate fluid from said tympanic cavity or middle ear;   (c) a second trigger actuating axial spring loaded pressurized tubular medicament chamber, which is positioned in said barrel casing and is adapted to rotate under the action of said second trigger and engage the second internal end of said piercing element and release medicament into the space behind the tympanic membrane.   

     Accordingly, it is a primary object of the invention to provide an apparatus which is capable of rapidly (a) making an incision in the tympanic membrane; (b) evacuating the fluid contents; and (c) administering a medicament to treat any pathology behind the tympanic membrane. 
     These and other objects will become apparent from a review of the Detailed Description of the Invention. 
    
    
     
       BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS 
         FIG. 1  is a cutaway view of the apparatus of the invention which shows one side of the cover removed. 
         FIG. 2  is a partially exploded view of the apparatus of the invention which shows the cover sections and the operating components. 
         FIG. 3  is a rear perspective view of some of the operating parts that fit within the internal portion of the barrel shown in  FIG. 2 . 
         FIG. 4  is a front perspective view of some of the operating parts that fit within the internal portion of the barrel shown in  FIG. 2 . 
         FIG. 5  is a partially exploded view of the end of the barrel assembly of the device of the invention. 
         FIG. 6  is an exploded perspective view of the barrel and turret assembly which shows a sealed antibiotic chamber and a device for opening said antibiotic chamber. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     As best seen in  FIG. 1 , the apparatus of the invention comprises an external cover  1  having two halves held together by rivets placed in rivet holes  1 B. A first actuating trigger  2  and a second actuating trigger  4  are mounted on the cover. The cover  1  is provided with a plurality of indentations  6 ,  8  and  10  that serve as ergonomically shaped finger gripping surfaces. At the forward end  12  of the apparatus, a viewing opening  14  is provided that is adapted to engage a standard otoscope  12  (in  FIG. 2 ). At the tip  14  of the viewing cannula  16 , the needle  18  is shown in a partially extended position as if it was being extended for the purpose of piercing the tympanic membrane. 
     The viewing opening  14  is preferably arranged so that it allows the physician to view the tympanic membrane as the needle  18  pierces the tympanic membrane. As shown in  FIG. 1 , the partially extended needle  18  follows the path shown by dotted line  22  as it is extended by the spring  23  which is controlled by latch  24  that pivots at mounting pivot  28  when first actuating trigger  2  is depressed. Spring band  19  provides a resistance that holds trigger  2  in the open position. Needle  18  is preferably made of a resilient material such as a polyimide that is flexible enough to bend as it is passed through an internal channel shown by dotted line  22  in viewing cannula  16 . The needle cartridge assembly  30 , vacuum cartridge  32  and medicament chamber  34  are shown within barrel  36  which is shown within cover  1  by dotted lines. Barrel  36  is a cylindrical structure provided with a space  36 B that receives the needle cartridge assembly  30  and separate chambers for the vacuum cartridge  32  and the medicament chamber  34 . 
     The barrel  36  comprises a cylindrical structure which is divided into a hollow first chamber  36 B and an offset core of solid material that has two separate chambers. The first chamber acts as a mounting means for vacuum cartridge  32  and the second chamber is medicament chamber  34 . 
     Dotted lines  34 C on barrel  36  show the position of medicament chamber  34  that houses the medicament and its associated delivery elements which comprise a spring, a plunger element and a seal which engages end  58  of needle retainer element  44 A when barrel  36  is rotated into position for ejecting medicament. Dotted lines  32 C show the position in barrel  36  where vacuum cartridge  32  is placed. End cap  60 , which allows access to the inside of the cover  1  is mounted at the end of cover  1  opposite the end on which tip  14  is mounted, on a movable axle  62  and is held in a closed position with locking tab  64 . 
     As best seen in  FIG. 2 , a partially exploded view of the otic aspirator/dispenser of  FIG. 1  is disclosed which has a view of otoscope  12 A which may be placed in opening  14  of cannula  16 . At the forward end  31  of the barrel  36  is a turret  38  which has an axially located opening  40  and remains fixed while the barrel  36  is rotated from a first position where the needle assembly is in register with an off center hole  42  in turret  38  that allows the needle to be extended from the barrel by the action of spring  23 . The barrel  36  is mounted within cover  1  on complimentary molded half circle shaped supports  46  which are on the inside of both cover halves but are only shown on one side of cover  1  in  FIG. 2 . 
     The forward end  31  of the barrel  36  has an opening into space  36 B and is also provided with an axle  40 A which is fitted into hole  40  in turret  38 . Opening  30 B is provided to allow the shaft  58 A below needle retainer element  44 A to move out of the barrel  36  when trigger  2  is activated. Opening  32 D is provided to allow vacuum cartridge  32  to communicate with the end  58  of needle cartridge assembly  30  when barrel  36  is rotated by spring  46 A. O-ring  32 E is placed in recess  32 F to provide a seal between opening  32 D and hole  42 . Opening  34 D is provided to allow medicament chamber  34 B to communicate with the end of needle cartridge assembly  58  when barrel  36  is rotated by spring  46 A when trigger  4  is activated. O-ring  34 E is held in recess  34 F to seal the medicament chamber and the end  58  of needle assembly  30  when the barrel  36  rotates to allow opening  34 D to communicate with the end  58  of needle assembly  30 . 
     Spring  23  is released by the action of lever  24  which is controlled by trigger  2 . As the needle cartridge is extended by the action of spring  23 , the end  58  of needle retainer element  44  is extended past the end of barrel  36  which allows barrel  36  to be axially rotated by the action of an axial spring  46 A to cause vacuum cartridge  32  to move into register with off center hole  42  which is in communication with needle  18 . As the vacuum cartridge tube  32  rotates into register with off center hole  42 , a detent  35 A in groove  34 A stops rotary movement of the barrel  36 . The vacuum cartridge  32  is opened to place a vacuum on needle  18  by opening end cap  60  and digitally depressing plunger element  47  against the force exerted by spring  45  to cause needle  45 A to break the seal  32 A on the vacuum in vacuum cartridge  32 . The effect of the vacuum on the end of needle  18  is to aspirate any fluid in the tympanic cavity or middle ear. 
     The vacuum cartridge  32  and the medicament chamber  34  are within barrel  36 . The vacuum cartridge is preferably provided with a vacuum which may be approximately P&lt;5×10 −3  Pa. 
     As best seen in  FIG. 5 , turret  38  is provided with axial hole  40  and off center hole  42 . The barrel  36  rotates due to the action of axial spring  46 A to bring the vacuum cartridge  32  into register with off center hole  42 . The vacuum cartridge  32  is provided with a constricted end portion  48 . This constricted end portion  48  engages off center hole  42  when the vacuum cartridge contacts the off center hole  42 A. A small needle  45 A in constricted end portion  48  which is mounted at the end of vacuum tube  32  breaks the vacuum seal  32 C as plunger element  47  is manually depressed. O-ring  46 B is mounted inside of barrel  36  to seal the end of vacuum cartridge  32  against the inside of opening  32 D. Spring  45  is held in recess  54  as shown in  FIG. 3  on the inner side of offset hole  42  so that it does not move out of alignment with offset hole  42 . The end  58  of needle retainer element  44  is adapted to rotate so that it is centered on O-ring  32 E in back of spring retainer  32 A. Needle  18  is attached to the end of needle retainer element  44 A which forms a conduit from the tip of needle  18  to end  58 . Expanded mid-section of needle retainer element  44  cooperates with retainer stop  46 C to prevent end of needle retainer element  58  from being extended beyond the end of turret  38  by the action of spring  23 . Thus, in operation, as needle cartridge assembly  30  is extended from barrel  36  by the action of spring  23 , the action of the axial spring  46 A on barrel  36  causes the barrel  36  to rotate until it reaches a detent  35 A set in groove  34 A where trigger  4  extension  4 A causes the rotary movement of the barrel to stop and which causes the vacuum tube  32  to be held in register with offset hole  42 . As described above, digital pressure is used to break the vacuum seal with needle  45 A to cause the seal on said vacuum cartridge  32  to open and expose the tympanic cavity or middle ear to the vacuum in the vacuum cartridge which is sufficient to extract any fluid from behind the tympanic membrane through needle  18  without damaging any of the inner ear tissues. 
     As best seen in  FIG. 3 , medicament chamber  34  is shown by dotted lines within barrel  36 . The medicament chamber  34  is provided with a constricted end portion which acts as seal  47 B. 
     As best seen in  FIG. 4 , spring retainer element  56  is positioned against spring  28 A which contacts connector element  47 A which contacts seal  47 B in medicament chamber  34  in barrel  36 . The medicament is stored in medicament chamber  34  between seal  47 B and turret  38 . When trigger  4  is activated, detent  35 A is bypassed and barrel  36  rotates to allow medicament to be ejected, through needle  18  by the action of spring  28 A on connector  47 A and seal  47 B, into the space behind the tympanic membrane. 
     As best shown in  FIG. 6 , the end of seal  47 B in medicament chamber  34  may be ruptured by cutting element  47 F on turret  36  as the barrel  38  rotates and passes over the end of the medicament chamber  34  under the action of a spring which is released by the trigger. Recessed channel  42 F is provided in barrel  36  to allow cutting element  47 F to move across the vacuum chamber and over the medicament chamber where it breaks seal  47 B. 
     After medicament is injected into the middle ear and the device is removed from the patient&#39;s ear, vacuum cartridge  32  can be removed from barrel  36  for testing of effluent aspirated from the tympanic cavity or middle ear. 
     The apparatus of the invention including the needle cartridge, vacuum cartridge and medicament chamber are all manufactured so that they are sterile when delivered to the physician. Various procedures are well known for the preparation of pre-filled sterile applicators and for packaging these devices in suitable containers to maintain sterility. 
     The particular medicaments that may be provided in the medicament cartridge include antibiotics, anesthetics etc. which are disclosed above.

Technology Classification (CPC): 0