Abstract:
An apparatus and a method for treatment of benign prostatic hyperplasia are disclosed. The apparatus includes an applicator piece carrying a set of electrodes shaped and positioned to create a substantial electric field in the volume of hyperplasia and a pulse generator adapted for delivery of electrical pulses above the upper electroporation limit for the neoplastic cells. The amplitude, duration and number of the electrical pulses are generally selected to cause necrosis of a significant fraction of the volume of benign prostatic hyperplasia. The apparatus may include a high frequency system for heating the prostatic tissue and a cooling system for cooling the urethra. The combined action of heating and cooling may increase the temperature of the prostate cells to 45 degrees C. to 55 degrees C., while keeping the urinary tract at a temperature 15 degrees C. to 20 degrees C. This temperature distribution can increase the selectivity of the treatment by increasing susceptibility of the neoplastic cells to the electroporation treatment and decreasing it for the normal urethral tissues.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     The present application is a continuation of U.S. patent application Ser. No. 11/347,965, filed Feb. 6, 2006, now U.S. Pat. No. 7,765,010 which is a division of U.S. patent application Ser. No. 10/217,749, filed Aug. 13, 2002 now U.S. Pat. No. 6,994,706, which claims priority to U.S. Provisional Application No. 60/311,792, filed Aug. 13, 2001 and to U.S. Provisional Application No. 60/325,994, filed Oct. 1, 2001, all of which are incorporated herein by reference. 
    
    
     FIELD OF INVENTION 
     The present invention relates generally to the therapeutic treatment of tissues and more particularly, to an apparatus and method for therapeutic treatment of benign prostatic hyperplasia 
     DESCRIPTION OF THE RELATED ART 
     a. Electroporation: 
     Biophysical phenomenon “electroporation” (EP) refers to the use of electric field pulses to induce microscopic aquatic pores—“electropores”—in the lipid cell membranes. Depending on the parameters of the electric pulses, electroporated cell can survive the pulsing or die. The cause of death of an electroporated cell is believed to be a chemical imbalance in the cell, resulted from the fluid communication with the extra cellular environment through the pores. The number and size of electropores depend on both, the amplitude of electric field pulse E and the pulse duration t. Electroporation is observed for pulse durations in the range from tens of microseconds to hundreds of milliseconds. For a given duration of a pulse and below a certain limit of the electric field amplitude, no pores are induced at all. This limit is different for different cells, particularly, for cells of different sizes. The smaller the size of a cell, the higher the electric field required to induce pores and thus the higher the limit is. Above the lower limit the number of pores and their effective diameter increases proportionally with both the amplitude E and duration t. 
     Until the upper limit of electroporation is achieved, the cells survive pulsing and restore their viability thereafter. Above the upper limit, the pore diameters and number become too large for a cell to survive. The irreversibly chemically imbalanced cell cannot repair itself by any spontaneous or biological process and dies. To kill a cell, a potential in the range of 2 to 4 V should be applied along the cell. The cell killing by electroporation is a probabilistic process. Increasing the number of applied pulses leads to increased probability of cell killing, approximately equal to the increase in the total duration of the electric pulse. 
     The survivability of electroporated cells depends significantly on their temperature. At higher temperature cells are more vulnerable, the amplitude and duration of the electric pulses required for cell killing are lower. This experimental fact is explained by two underlying phenomena: at higher temperatures cells are less stable biochemically because of more intense metabolism, and, secondly, at elevated temperatures the strength of lipid membranes decreases, which facilitates creating larger pores or irreversible rupture. At lower temperatures (10 to 20 degrees C.) cells are more resistant to electroporation and can survive two to three times higher voltages than that at the body temperature. 
     b. The Prostate Gland and Benign Prostatic Hyperplasia: 
     The prostate is a walnut-sized gland that forms part of the male reproductive system. The gland consists of several lobes, or regions, enclosed by a dense fibrous capsule. It is located between the bladder and the rectum and wraps around the urethra, the tube that carries urine out from the bladder through the penis. There are generally three glandular zones in a prostate gland: central, peripheral and transitional. The transitional zone is located right behind the place where the seminal vesicles are merging with urethra. This transitional zone tends to be predisposed to benign enlargement. The prostate gland is generally composed of smooth muscles and glandular epithelial tissue. The glandular epithelial tissue produces prostatic fluid. The smooth muscles contract during sexual climax and squeeze the prostatic fluid into the urethra as the sperm passes through the ejaculatory ducts and urethra. Prostatic fluid secreted by the prostate gland provides nutrition for ejaculated spermatozoids increasing their mobility and improves the spermatozoids chances for survival after ejaculation by making the environment in the vaginal canal less acidic. 
     The prostate reaches its normal size and weight (about 20 grams) soon after puberty. The size and weight of the prostate typically remain stable until the individual reaches his mid-forties. At this age, the prostate typically begins to enlarge through a process of excessive cell proliferation, called benign prostatic hyperplasia (BPH). This overgrowth can occur in both smooth muscle and glandular epithelial tissues and has been attributed to a number of different causes, including hormones and growth factors as well as generally to the aging process. 
     Benign prostate hyperplasia can cause distressing urination symptoms. As the disease progresses the dense capsule surrounding the enlarging prostate prevents it from further expansion outward and forces the prostate to press against the urethra, partially obstructing the urine flow. The tension in the smooth muscles of the prostate also increases which causes further compression of the urethra and reduction of the urine flow. Some symptoms of BPH stem from the gradual loss of bladder function leading to an incomplete emptying of the bladder. The symptoms can include straining to urinate, a weak or intermittent stream, an increased frequency of urination, pain during urination, and incontinence—the involuntary loss of urine following an uncontrollable sense of urgency. These symptoms alone can negatively affect the quality of life of effected men. Left untreated, BPH can cause even more severe complications, such as urinary tract infection, acute urinary retention, and uremia. 
     Before age 40, only 10% of men have benign prostatic hyperplasia; but by age 80, about 80% have signs of this condition. Benign prostatic hyperplasia is the most common non-cancerous form of cell growth in men. About 14 million men in US have BPH, and about 375,000 new patients are diagnosed every year. 
     For many years, researchers have tried to find medications to shrink the prostate or at least stop its growth. Between 1992 and 1997, the FDA approved four drugs: finasteride, terazosin, tamsulosin, and doxazosin for treatment of BPH. 
     Finasteride (Proscar) inhibits production of hormone DHT. DHT is one of the hormones that have been found to be involved in prostate enlargement. Treatment with Finasteride has been shown to actually shrink the prostate in some men. 
     Terazosin (Hytrin), doxazosin (Cardura), and tamsulosin belong to the class of drugs known as alpha-blockers. Alpha-blockers act by relaxing the smooth muscle of the prostate and bladder to improve urine flow and reduce bladder outlet obstruction. In men with severe symptoms, though, these medications are not curative. They can delay but not prevent the eventual need for surgery. 
     Regardless of the efficacy of any drug treatment, the long term exposure to xenobiotic compounds may produce additional unwanted side effects that are not realized until years after treatment. Accordingly, a need exists for an apparatus and method for the treatment of BPH that does not require the introduction of xenobiotic compounds. 
     For men with the most severe symptoms, surgery is generally considered to be the best long-term solution. There are several surgical procedures that have been developed for relieving symptoms of BPH. However, all of them are very morbid, require a long hospital stay, generally require the use of general anesthesia, suffer from significant side effects, and have possible complications. 
     In recent years, a number of procedures have been introduced that are less invasive than surgery. One such procedure is the transurethral microwave thermal therapy described in U.S. Pat. No. 5,575,811. In transurethral microwave thermal therapy, a Foley-type catheter containing a microwave antenna is placed within the urethra. The microwave antenna positioned adjacent to the transitional zone of the prostate, where BPH is located, allows selective heating of the prostate. Maintaining the temperature above 45.degree. C. during about one hour session leads to necrosis of the tissues and subsequent reabsorption of necrotic tissue by the body. 
     Another recently developed non-invasive technique is transurethral needle ablation (TUNA). TUNA is described in U.S. Pat. No. 6,241,702. TUNA uses low level radio frequency (RF) energy to heat the prostate. Using TUNA, two separate needles are inserted into prostate through the urethra. Several watts of RF energy is applied to each needle to cause thermal necrosis of the prostate cells around the needles. Application of this treatment to several sites of the prostate typically results in sufficient necrosis to relieve symptoms of the BPH. 
     While generally successful, the microwave and RF therapies are relatively long procedures. Also, because of the poor temperature control of the heated volume, the volume of removed tissue is often not sufficient for the long term relief of the symptoms and/or the healthy tissue of the urethra is damaged. A damaged urethra is capable of restoring itself, but the healing is a long morbid process accompanied by sloughing of the necrotic tissue into urethra and excreting it during urination. 
     Therefore, a need exists for a minimally invasive therapy for treatment of BPH that requires shorter treatment times and is less morbid than existing therapies. 
     SUMMARY OF THE INVENTION 
     The present invention satisfies the above-listed needs and provides additional improvements and advantages that will be recognized by those skilled in the art upon review of the following description and figures. 
     The object of the present invention is to provide a treatment that causes necrosis of BPH in a shorter period of time than that of the existing transurethral thermal therapies. 
     Another object of the present invention is to destroy nerves causing tension in the fibro-muscular tissue and thus achieve relaxation of the muscles contracting the urethra. 
     Another object of the present invention is to decrease morbidity of the treatment. 
     Another object of the present invention is to improve control of the volume in the prostate where necrosis occurs, avoid sloughing of the necrotic tissue through the urethra and decrease the damage to the urethra itself. 
     A shorter treatment time is achieved by applying to the tumorous tissue multiple high voltage pulses that cause necrosis of BPH by electroporation. 
     In one aspect, the present invention provides, an apparatus for treatment of benign prostate hyperplasia of a male patient. The apparatus can include an applicator piece adapted for placing a set of conductive electrodes into the urethra in the vicinity of the prostate gland. The electrodes can be shaped and positioned to generate a substantial electric field in the volume of benign hyperplasia. The electric field being directed predominantly in the radial direction to the urethra. The apparatus also includes a high voltage pulse generator. The high voltage pulse generator connected to the electrodes and adapted for delivering high voltage pulses exceeding the upper limit of electroporation for neoplastic cells of the prostate. Thus, the high voltage pulse will cause electroporation necrosis of the benign prostatic hyperplasia. The high voltage generator can also include a means for monitoring the electric current and resistance of the treated tissue before, during and after treatment. The apparatus may also include a urethral catheter with a sealed hollow passage inside. The passage being connected to a cooling system adapted for cooling the urethra to a temperature 10 to 20 degree C. The apparatus can also include a radio frequency generator connected to the electrodes. The radio frequency generator configured to deliver radio frequency power to the prostate to heat the benign prostate hyperplasia tissue to 45-50 degrees C. for a short period of time before application of the electroporation treatment. The apparatus can also include a set of temperature sensors. The temperature sensors may be placed in the vicinity of the conductive electrodes and used to control delivery of coolant to the urethra and radio frequency energy to the prostate for stabilization both the temperature of the urethra and the bulk of the prostate at predetermined levels. 
     In another aspect, the present invention provides another apparatus for treatment of benign prostatic hyperplasia of a male patient. This apparatus includes a urethral catheter carrying conductive electrodes. The urethral catheter includes a proximal end, an elongated member and a distal end. The elongated member being sized so that it can be introduced into the urethra. When introduced into a patient, the proximal end is positioned outside of the patient&#39;s body and the distal end extends through the urethra toward the bladder. The distal end terminates with a balloon which is adapted for expansion in the patient&#39;s bladder. The conductive electrodes are affixed to the elongated member adjacent to the transition zone of the prostate, to the distal balloon in the bladder and on the external surface of the patient&#39;s body. The apparatus also includes a high voltage pulse generator. The high voltage generator is connected to the electrodes and is adapted to deliver high voltage pulses. These high voltage pulses exceed the upper limit of electroporation for neoplastic cells and thus, cause electroporation necrosis of the benign prostatic hyperplasia. The apparatus may include a set of needles carrying conductive electrodes that is introduced into the body of the prostate gland. 
     In yet another aspect, the present invention provides yet another apparatus for treatment of benign prostatic hyperplasia of a male patient. The apparatus includes an applicator having two spatially and electrically separated cylindrical electrodes secured on a flexible needle having a sharp tip. The needle is placed into prostate through a urethral probe. The urethral probe has a proximal end, elongated member and distal end. The proximal end is positioned outside of the patient&#39;s body and is attached to a control handle piece. The control handle piece is used to manipulate angular and longitudinal positions of the probe in the urethra. The elongated member has a passageway extending from the proximal end to the distal end and is adapted to accommodate an endoscope. The elongated member has at least one additional passageway slidably carrying the flexible needle from the proximal end to a side port at the distal end of the probe. The side port is positioned near the transition zone of the prostate. The control handle piece is connected to a finger activated mechanism mounted between the needle and is adapted to advance or retract the needle. The flexible needle is adapted to change direction at the side port and to penetrate the prostate gland at an angle to the urethra close to 90 degrees. The apparatus also includes a high voltage pulse generator connected to the electrodes. The high voltage pulse generator is adapted for delivering high voltage pulses exceeding the upper electroporation limit for the fibro muscular cells of benign prostate hyperplasia and thus, causing electroporation necrosis of the benign prostate hyperplasia. The needle carrying conductive electrodes can have a proximal end, an elongated member and a distal end. The proximal end can terminate with two or more insulated wires connected to at least two cylindrical electrodes that are secured to the elongated member. The electrodes are spatially separated and electrically insulated from each other and from the elongated member. The elongated member has a passage through it carrying the insulated wires. The insulated wires are adapted to connect with the output of the high voltage pulse generator. The distal ends have sharp solid tips. The apparatus can also include a perineal needle template used for placement of conductive needle-type electrodes into the body of the prostate through the perineum under ultrasound guidance. 
     In another aspect, the present invention provides a method for treatment of benign prostatic hyperplasia of a male patient. The method includes placing a set of conductive electrodes in the body of the patient in the vicinity of the prostate. The electrodes being shaped and positioned to create a substantial radial to the urethra electric field in the region of benign prostatic hyperplasia. The method further includes delivering high voltage pulses with amplitude and duration exceeding the upper electroporation limit for the neoplastic cells and thus, causing electroporation necrosis of the benign prostatic hyperplasia. The method may include a step of cooling the urethra to a temperature of 10 to 20 degree C. The method may also include a step of delivering radio frequency power to the electrodes to heat the benign prostate hyperplasia tissue to 45 to 50 degrees C. for a short period of time before application of the electroporation treatment. The method may also include a step of providing a set of temperature sensors placed in the vicinity of the conductive electrodes and used for control of delivery of coolant to the urethra and radio frequency energy to the prostate for stabilization of the temperature of the urethra and the prostate at predetermined levels. The method may also include monitoring of the electric current and resistance of the treated tissue during and after treatment. The monitoring used to determine an end-point for the treatment. The method may include the high voltage pulse generator generating pulses that are rectangular, exponential, single or alternating polarity. The method may utilize a set of conductive needle-type electrodes placed into the body of the prostate by using a perineal needle template under ultrasound guidance. 
     In another aspect, the present invention provides another apparatus for treatment of benign prostatic hyperplasia of a male patient. The apparatus includes a urethral probe carrying a conductive electrode. The urethral probe has a proximal end, elongated member and a distal end. The proximal end is positioned outside of the patient&#39;s body and is attached to a control handle piece. The elongated member is made of a rigid metal and sized so that it can be introduced into the urethra. The distal end terminates with a balloon adapted for expansion in the patient&#39;s bladder. The conductive electrode is electrically insulated from the elongated member and is secured on the surface of the elongate member adjacent to the transition zone of the prostate. The control handle piece includes a rail. A plurality of needle electrodes are mounted in a rigid cartridge that is slidably movable along the rail. The movable cartridge being able to travel along the rail between at least two positions. In a first position, the needles are hidden behind a protective cap for safety. In a second position, the needles are advanced forward through bores and introduced into the body of the prostate. The needle electrodes are adapted to be placed in the transition zone. The urethral probe and rail are shaped and spatially positioned relatively to each other so that the needles move parallel to the distal part of the urethra at predetermined distances and positions from each other and from the urethra electrode. The apparatus also includes a high voltage pulse generator. The high voltage pulse generator is connected to the urethral electrode and the needle electrodes to deliver high voltage pulses. The high voltage pulses have an amplitude and duration that exceeds the upper limit of electroporation for neoplastic cells and thus, causes electroporation necrosis of the benign prostatic hyperplasia. The needle electrodes in the needle cartridge of the applicator can be arranged in two or three rows circumferentially to the urethra with electrodes parallel to each other and to the urethra and each needle in a row positioned an equal distance from the urethra. The needle electrodes in each row can be connected to each other and kept at the same potential during high voltage pulsing to generate an electric field with a predominantly radial direction. 
     In yet another aspect, the present invention includes an applicator for placement of electrodes into prostate of a male patient to deliver a variety of forms of electrical energy for treatment of the prostate. The applicator includes a urethral probe carrying a conductive electrode and having a proximal end, elongated member and a distal end. The proximal end is positioned outside of the patient&#39;s body and is attached to a control handle piece. The elongated member being made of a rigid material and sized so that it can be introduced into the urethra. The distal end terminates with a balloon adapted for expansion in the patient&#39;s bladder. The conductive electrode is secured on the surface of the elongated member to be positioned adjacent to the prostate. A rail is secured to the control handle piece. A plurality of needle electrodes are mounted in a rigid cartridge that is slidably movable along the rail. The movable cartridge is able to travel between at least two positions. In the first position, the needles are hidden behind a protective cap for safety. In the second position, the needles are advanced forward through holes in the protective cap and are introduced into the body of the prostate. The needle electrodes are adapted to be placed in a zone of the prostate to be treated. The urethral probe and rail are shaped and spatially positioned relatively to each other such that the needles move parallel to the distal part of the urethra at predetermined distances and positions from each other and from the urethra electrode. 
     The present invention, as well as its various features and advantages, will become evident to those skilled in the art when the following description of the invention is read in conjunction with the accompanying drawings as briefly described below and the appended claims. Throughout the drawings, like numerals refer to similar or identical parts. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a schematic illustration of an embodiment of an apparatus for treatment of BPH in accordance with the present invention; 
         FIG. 2  illustrates a cross-section of the prostate with the urethral catheter in place; 
         FIG. 3  illustrates a longitudinal section of the urethral catheter; 
         FIG. 4  is an enlarged view of a cross-section of the urethral catheter; 
         FIG. 5  illustrates an embodiment of an apparatus for treatment of BPH with a perineal needle template; 
         FIG. 6  illustrates an embodiment of an apparatus for treatment of BPH with a urethral probe having a two-electrode needle; 
         FIG. 7  illustrates a version of the apparatus in accordance with the present invention for treatment of BPH with a urethra-perineal applicator; 
         FIG. 8  illustrates a cross-section of the prostate with electrodes of the urethra-perineal applicator in place; and. 
         FIG. 9  illustrates a schematic drawing of needles used in different versions of the apparatus for treatment of BPH in accordance with the present invention. 
     
    
    
     All figures are drawn for ease of explanation of the basic teachings of the present invention only; the extensions of the figures with respect to number, position, relationship and dimensions of the parts to form the preferred embodiment will be explained or will be evident to those skilled in the art after the following description has been read and understood. Further, the exact dimensions and dimensional proportions to conform to specific force, weight, strength, and similar requirements will likewise be evident to those skilled in the art after the following description has been read and understood. 
     Where used in various figures or on multiple occasions within the same figures, the same numerals generally designate the same or similar parts or features. Furthermore, when the terms “vertical,” “horizontal,” “top,” “bottom,” “right,” “left,” “forward,” “rear,” “first,” “second,” “inside,” “outside,” and similar terms are used, the terms should be understood to reference only the structure shown in the drawings as it would generally appear to a person viewing the drawings and utilized only to facilitate describing the illustrated embodiment. 
     DETAILED DESCRIPTION OF THE INVENTION 
     In one aspect, the current invention in part stems from recognition of the fact that the effect of electroporation on tissue can be modulated by selecting a specific direction relatively to a cell for application of a pulsed electric field. For elongated cells similar to muscle fibers the length-to-width ratio can be as high as 20 to 30. For the nerve cells this ratio can be even higher. The vulnerability of cells to electroporation is different for different directions of the applied field. It depends on the size of a cell in the direction of the applied field. In other words, elongated cells can be killed with significantly lower electric field if the field is applied along the cells. If the field is applied across the cell, the cell is capable of surviving much higher amplitudes of the electric field. 
     In the current invention relief of symptoms is achieved by electroporation treatment, which is used to create a necrotic zone in the BPH tissue around the urethra. Necessary control of the volume of the necrotic area, its shape and location relatively to the healthy tissues of the prostate and urethra can be provided by a system of electrodes generating electric field in the area of the benign enlargement of the prostate. Application of multiple electrical pulses with appropriate voltage and duration leads to necrosis of prostatic tissues around the urethra. 
     Anatomically, predominant direction of fibers in the fibro-muscular glandular tissue of BPH is radial to the urethra. In the present invention the preferred direction of applied electric field is also radial to the urethra, coinciding with the direction of fibers. Application of the electroporating pulses along the muscular fibers and nerves that anatomically follow them selectively kills both types of fibers. Thus two intermediate goals of the present therapy become achieved: first, a significant volume of necrotic BPH tissue around the urethra is created; second, the nerves causing elevation in tension of the muscle fibers are destroyed. Removal of the necrotic tissue by macrophages decreases the total volume of BPH and reduces pressure on the urethra. Destruction of the nerves results in relaxation of the prostate. Subsequently, both effects contribute to the improvement of the urethra and bladder functions after treatment. 
     To apply a pulsed electric field to the BPH region in the transition zone of the prostate, a set of electrodes is placed into the urethra (and the bladder) on the urethral catheter. In other embodiments of the invention, external electrodes are utilized or needle-type electrodes may be introduced into the volume of BPH tissue. The electrodes are electrically connected to a generator producing high voltage pulses, the amplitude and duration of which are selected to provide electric field in the prostatic tissue exceeding the upper electroporation limit for the fibro-muscular cells. Duration of pulses may be selected from the range of 10 microseconds to 500 milliseconds. The amplitude and number of pulses are preselected to cause necrosis of the BPH cells, mainly muscle cells and nerves. 
     Sphincters, located on the urethra anterior and posterior to the prostate gland, consist of smooth muscle cells wrapped circumferentially around the urethra. They control shutting down the flow of urine from the bladder and should be preserved during the treatment. Radial electric field applied to the prostate is transversal to the sphincter muscle fibers to which they are relatively resistant. However, to ensure that electroporation injury to the sphincters is avoided, the electrode in the urethra between the sphincters should not be positioned too close to them. For the same reason the amplitude of the electric field during treatment should be selected not to exceed the upper electroporation limit of the sphincter muscles in the transversal direction. 
     In another aspect, the present invention provides an apparatus and method for treatment of the prostate. The invention is generally described in the context of an apparatus and method for the treatment of BPH as a specific example for illustrative purposes only. Upon review of the following description and figures, those skilled in the art will understand that an apparatus in accordance with the present invention may be used for a wide variety of indications. 
     An apparatus for treatment of the prostate in accordance with the present invention is shown in  FIG. 1 . A Foley type urethral catheter  101  includes balloon  102  at its distal end. Urethral catheter  101  is introduced into the urethra  111  ( 411  in  FIG. 4 ) and balloon  102  positioned within the bladder  115 . As illustrated, transition zone  120  of the prostate is being treated for BPH. Anatomically, central zone  121 , peripheral zone  125  seminal vesicle  123 , and ejaculatory duct  122 , are illustrated. Ejaculatory duct  122  delivers the sperm into the prostatic urethra during sexual climax. The catheter can include an electrode  103  adjacent to the prostate in the transition zone  120 , and an electrode  104 , placed into the bladder distally to the urethra or outside of the urethra on the skin (not shown) of the patient. 
     An implementation of the present invention having three electrodes is shown in  FIG. 1 : electrode  104  is in the bladder, electrode  103  is adjacent to the transition zone, electrode  105  can be placed proximally to the electrode  103  in the urethra. Placing more than two electrodes allows achieving better concentration of electric field on affected region of the prostate in the transition zone. A port  106  may be provided in the proximal end of the urethral catheter serving as an inlet for the coolant intended to cool the urethra as the prostate is heated. In one aspect, the prostate may be heated using RF. Therefore, an radio frequency (RF) generator  110  is illustrated for exemplary purposes. In this embodiment, a port  107  can also be provided to serve as an outlet for the coolant carrying the heat from the electrodes  103  and  105  via a flexible tube  117  to the coolant system  118 . Wires  108  ( 408  in  FIG. 4 ) can be provided to connect electrodes  103 ,  104 ,  105  with a generator  109 , sending electroporation pulses to BPH. For purposes of electroporation, generator  109  is typically configured to provide high voltage. During treatment, the urethra may be cooled by a cooling system  118 . Outlet  130  is a channel, fluidly connected to the balloon  102  and serving for its inflation in the bladder  115 . 
     In  FIG. 2  a cross-section of an embodiment of the urethral catheter  101  inserted through a prostate is illustrated. Number  100  corresponds to the transition zone of the prostate  120  effected by BPH. Electrode  103  is positioned in the prostatic urethra  111 . 
       FIG. 3  and  FIG. 4  show a longitudinal-section and a cross-section of an embodiment of the urethral catheter  101 . Number  103  corresponds to the urethral electrode,  406  is the channel in the catheter, fluidly connected to the inlet  106  at the proximal end of the catheter and accepting the coolant liquid from the pump, not shown in the figure. Number  407  is designated for two channels in the catheter in which the coolant moves back to the proximal end, where through the outlet  107  it is returned to the cooling system. 
     Another apparatus for implementing the method in accordance with the present invention employing a perineal needle template for placement of electrodes into BPH is depicted in the  FIG. 5 . Here  520  is a needle perineal template with holes  521  for directing needles having proximal end  522 , distal ends  523  and elongated part  525 . The proximal ends are electrically connected to multi electrode connector  526 , leading to a switch board circuit  527 , which, in turn, is connected to the output of the high voltage pulse generator  109 . 
     An apparatus for treatment of BPH by electroporation employing a urethral probe—an applicator for placement of electrodes into the prostate via urethra, is shown in  FIG. 6 . The apparatus comprises a urethral probe  600  having a proximal end  601 , elongated member  603  and a distal end  602 . The elongated member  603  has a passageway  606  extending from the proximal end of the probe  601  to its distal end  602  and ending at a side port  604  of the probe  601 . In the passageway at the proximal end of the probe, an endoscope  611  is introduced. The endoscope has a wide-angle view and allows one to visualize the urethra at the distal end of the probe and thus provides visual control during manipulation of the probe. The endoscope has a fiber optic port  630  secured to a cable  640  connected to a light source  650 . The light source  650  provides necessary illumination of the urethra beyond the distal end of the probe. Probe  600  is attached to a control handle piece  612 . A flexible needle  605  inside passageway  606  extends throughout its length from the proximal end where it is engaged with a finger  607  via a mechanism adapted for advancement or retraction of the needle along the probe. Being advanced forward, the needle  605  bends at the distal end  602  of the probe  601  and comes out from the side port  604  under an angle close to 90 degrees to the urethra. Control handle piece  612  is used for manipulation of angular and longitudinal positions of the probe in the urethra and placement of the distal end  602  of the probe  601  into several locations along the transition zone of the prostate. The needle has a sharp tip  608  which easily penetrates through the urethra wall  619 . Electrodes  610  on the distal part  609  of the needle thus placed into the volume of the BPH. The electrodes are spatially and electrically separated and, being pulsed by a high voltage, are capable of creating a substantial radial electric field along the muscle fibers of the BPH. Two wires leading from the electrodes  610  are extended through the needle  605  to its proximal end and further inside the handle  612  to the connector  613 , where they are connected to the cable  614 . The cable  614  is connected to the generator  109 . 
     Under endoscopic guidance the probe is introduced by a physician into the patient&#39;s urethra with the distal end of the probe positioned inside the prostate. The needle of the probe is advanced into the BPH tissue surrounding the urethra and multiple HV pulses are applied. The end point of the electroporation therapy is a significant and stable drop in the electrical resistance of the treated volume. The resistance drop indicates profound electroporation damage to the fibro muscular cells, which later on leads to their necrosis. Overall treatment of one site takes about 10 pulses and several seconds to several tens of seconds in time depending on the repetition rate of the pulse generator. 
     Another implementation of the current invention is shown in the  FIG. 7 . In this version of the apparatus, the needle electrodes are delivered to the prostate by a urethra-perineal apparatus. This apparatus is a combination of a urethral probe carrying a central electrode in the prostatic segment of the urethra and a cartridge of needle electrodes placed into the body of the prostate via a perineal approach. The urethral probe  701  is made of a rigid material, preferably metal, and has a proximal end  702 , a distal end  703  and an elongated member  704 . The distal end of the probe  703  is terminated with a balloon  705  adapted for inflation in the patient bladder  115 . During treatment, the probe is introduced into urethra  706  of penis  707  and balloon  705  is inflated. Inflated balloon  705  anchors the probe longitudinally relatively to the bladder and prostate. The length of the urethral electrode and the distance between the electrode and the balloon are selected in such a way that the electrode is placed precisely adjacent to the BPH in the transition zone of the prostate  709 . Balloon  705  via a channel inside the probe  701  fluidly communicates with inflation port  710  connected to a syringe  711  actually inflating the balloon. The urethral electrode  708  electrically connected to a wire  712  coming out of the distal end of the probe  702  to switching board circuit  713  whose function is the distribution of the high voltage pulses received from the generator  109  between electrodes placed into prostate during electroporation treatment. The urethral probe  701  is attached to a handle piece  714  used for longitudinal and angular manipulation of the probe. A cartridge  720  used for placement of needle electrodes into prostate via perineal approach is secured at the opposite side of the handle piece  714 . The cartridge  720  has a proximal cap  721 , a distal cap  722  and a cylinder  723  between them. A piston  724  secured at the end of a plunger  725  slides inside the cylinder  723  between two extreme positions, a proximal and a distal one. In the proximal position the needles are hidden in the cylinder. Being pushed by a knob  730  the piston  724  moves the needles forward through holes  731  in the distal cap  722  forcing the needles to prick perineum  700  situated between scrotum  715  and anus  716  and penetrate prostate  709 . An exemplary needle  727  (for simplicity only two needles are shown) has proximal end  726 , distal end  728  and electrode  729 . The proximal ends of all needles are mounted on the distal surface of the piston  724 , electrically insulated from the needles. Through holes on the proximal surface of the piston the needles are electrically connected to wires  731 , leading to switchboard circuit  713 , used for commutating the high voltage pulsed between separate electrodes or groups of electrodes. The switchboard circuit  713  is coupled to a high voltage pulse generator  109 . The needles may be mounted on the piston  724  in two or three rows along concentric circumferences. The electrodes  729 , preferentially electrically insulated from the needles, are connected to wires  731 , leading to the switchboard circuit  713 , with insulated wires disposed inside the hollow needles. The needles in each row may be electrically connected to each other and kept at the same potential during high voltage pulsing. These connections decrease the number of wires that should be placed between the needles and the switchboard circuit  713  and generate electric field in predominantly radial direction, the direction that is especially efficient in killing fibro muscular cells positioned radially. The shape of urethral probe  701 , its spatial position relatively to the needle cartridge  720  and spacing between the needles are selected to insure that the needles move parallel to the distal part of the urethra and can be placed in the urethra at predetermined radial and longitudinal positions from each other and from the urethra electrode  708 . Stated otherwise, the probe member  704  may be configured to include a substantially linear distal end segment that serves to straighten the prostatic urethra when the probe is placed in an operative position in the urethra as shown in the Figure. This distal end segment carries the balloon  705  and the urethral electrode  708 . The distal end segment and the needle electrodes  727  each define linear axes that are substantially parallel to each other. With this configuration, then, the needle electrodes  727  may be advanced such that they move substantially parallel to the distal end segment and thus the distal or prostatic urethra. With this configuration of rigid probe, handle, and needle cartridge, the electrodes  729  may be precisely positioned relative to the urethral electrode  708  for application of the electroporation therapy, as will be explained in greater detail with respect to  FIG. 8 , below. 
     The relative positioning of the urethral electrode and the needle electrodes in the prostate during treatment is illustrated by  FIG. 8 .  FIG. 8  shows a cross-section of the prostate with all electrodes in place. Numbers  813  and  815  stand for peripheral and central zones of the prostate respectively. Number  812  corresponds to anterior fibro muscular area and  814 —for ejaculatory ducts. As can be seen from the  FIG. 8 , the urethral electrode  808  is placed in the center of the prostate with the needle electrodes  829  positioned around it. A channel  809  connects the distal balloon of the urethral probe and the inflating port located at the proximal end of the probe. Two circumferential rows of needle electrodes are placed concentrically around the urethra. High voltage pulsing applied to the central electrode and any of the rows of electrodes creates a predominantly radially directed electric field. Also, the radial electric field can be created by pulsing the rows of the needle electrodes only, without applying voltage to the central urethral electrode, or it can be created by consecutive pulsing pairs of electrodes positioned at different distances from the urethra along the same radius. 
     The treatment procedure with a urethra—perineal applicator starts by placing the probe  701  into the urethra  706 . Balloon  705  at the distal end of the probe  703  is inflated. Inflated balloon  705  anchors the probe relatively to the urethra and the bladder. Due to selection of the location of electrode  708  on the probe  701 , it can be positioned in the urethra at the exact location of the transition zone in the middle of the BPH overgrowth. As the probe  701  is being placed in the urethra, the needles  727  in cartridge  720  stay inactive, hidden in the back position. After the probe  701  is placed and anchored, the scrotum  715  is pulled aside and gently secured at a side and up position to avoid injury by the needles  727  to be advanced. Then the needles  727  are advanced into the forward position. They pierce the perineum  700  and the prostate  729  and deliver the needle electrodes  729  into the treatment positions around the central urethral electrode  708 . After placement of all electrodes, the electroporation treatment is performed. Multiple high voltage pulses are delivered to the electrodes to create a radial to the urethra electric field to cause cell death and necrosis of a significant volume of neoplastic tissue, resulting in a relief of BPH symptoms. As the HV pulses are delivered the electrical resistance of the tissue is monitored. The end of the therapy is marked by a significant and stable drop in the resistance of the treated volume of tissue. 
     Placement of electrodes in the vicinity of prostate using a urethra-perineal applicator does not require ultrasound or other imaging guidance. Precise placement of the needles is provided by high mechanical tolerances of the applicator and high rigidity of the urethral probe. Using the urethra-perineal applicator allows for a short treatment time because it provides treatment in only one position of the electrodes, and does not require repositioning electrodes and multiple manipulation of the applicator. 
     The urethra-perineal applicator can be used for delivery of electrical energy to the prostate not only in the form of high voltage pulses causing electroporation necrosis, but also in the form of RF energy causing thermal necrosis of BPH. 
     Different needle electrodes used in the electroporation treatment are shown in  FIGS. 9   a, b, c .  FIG. 9   a  shows a one electrode needle adapted for creating electric field normal to the axis of the needle. The needle has a proximal end  901 , distal end  902  and a metal hollow body  906 . At the distal end  902  the needle is terminated by a sharp metal tip  910  ( 911 ), brazed into the hollow body of the needle. A cylindrical electrode  903  is secured on an insulator layer  905  deposited on the needle surface. The electrode  903  ( 904 ) is electrically connected to high voltage generator via a wire  907  ( 908 ). A version of a similar needle with two electrodes adapted for creating electric field directed along the axis of the needle is shown in the  FIG. 9   b.    
     In versions  9   a  and  9   b  the sharp tips are electrically separated from the HV electrodes. In version  9   c  the tip is made of an insulating material, like glass, dielectric crystal or ceramics. This feature of the design prevents electric breakdowns and sparking from the tip through the tissue during HV pulsing. 
     Although preferred embodiments of the invention have been described in some detail, it is understood that obvious variations can be made without departing from the spirit and the scope of the invention as defined by the appended claims.