TWI323667B - Implantable and sealable device for unidirectional delivery of therapeutic agents to tissues - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention This invention relates to a device and method for locally delivering a drug; in particular, it relates to an implantable system which, once sealed into a tissue or organ, The drug to be delivered to the target tissue is not exposed to other tissues and fluids in the target tissue, while maintaining a certain amount of drug in the mammalian local tissue or system. Also disclosed are devices and methods for treating diseases. [Prior Art] A number of studies have focused on drug delivery devices that can be implanted into a preselected location in a mammal. To date, many different types of surgically implantable drug delivery devices have been developed, which have been patented and will be described in detail below. A surgically implantable drug delivery device that delivers a low solubility agent to the interior of the body is disclosed in U.S. Patent Nos. The device includes a core containing a drug that is isolated from surrounding tissue via a permeable polymer coating that controls the drug release rate.衮 The edge placement system delivers the drug in multiple directions from the implantation site, so that all the selected locations and the '° are exposed to the drug. In addition, the release of the drug is controlled by a technique that is decomposed by a sputum, a sputum, or a polymer coating that allows the drug to pass through. A surgical implantable drug delivery device for delivering an activity factor to a specific location in a mammal is disclosed in U.S. Patent No. 4,3,78,01, the disclosure of which is incorporated herein by reference. The device comprises a permeable permeable membrane sac that can be implanted into a mammalian body and a fluid impermeable permeable tube, one end of which is connected to one end of the hollow tube Inside the bag, the other end is left to the outside of the animal. The tube can be used as a passage to the membrane bag. After the membrane is implanted into the mammal for a long time, a cell-containing packet (envel〇Pe) can be introduced into the membrane pouch by the tube. After the cell-containing pouch is implanted into the membrane pouch, the cell can produce an active factor' and diffuse through the membrane pocket after the tip to the surrounding tissue or organ of the implanted object. U.S. Patent No. 5, No. 182,111 discloses a surgically implantable drug delivery device for delivering an active agent to a preselected location (e.g., a tissue or organ in a mammal). The device comprises a space formed by a semi-permeable membrane comprising at least one type 1 cell capable of producing a specific activity factor and a second type of cell capable of producing a magnification factor. The amplification factor produced by the type 2 cell can then induce the first type of cell to produce the active factor. U.S. Patent No. 4,479,796 discloses a surgically implantable disperser for delivering a preselected drug directly into the blood. Briefly, the disperser is surgically implanted into alignment with a blood vessel. The disperser contains a replaceable cell tubule 'micro-tissue' which is capable of producing and secreting a drug into the blood that passes through the tubule. U.S. Patent No. 4,309,776 discloses an intravascular drug delivery device 1323667, which has a chamber with implanted cells for surgical implantation into the vessel wall. The device comprises a perforated wall that allows passage of hormones made by the implanted cells and diffuses from the chamber into the blood. A drug delivery device comprising a fillable storage tank connected to a vitreous chamber via a line is disclosed in U.S. Patent Nos. 6,251,090, 5,830,173, 5,725,493 issued to A. This delivery device involves intrusion into the eye frame, thus limiting its application, especially for applications that need to maintain the integrity of the target tissue. U.S. Patent Nos. 6,416,777 and 6,413,540 disclose a device which, once installed under the Tenon's capsule and in contact with the sclera, begins to deliver the drug into the eye. This type of system consists of an outer layer that is not transparent to the intended delivery of the drug, thereby reducing the chance of the drug being washed away by fluid around the eye. The appearance of the device facilitates its implantation into the space below the sclera, while also avoiding the method of implanting and retaining the device in the inferior oblique muscle, preventing the device from slipping to the vicinity from the implantation site. The macula area of the retina. However, these patents do not disclose how to seal the device into the sclera or the ground tissue*4*. Moreover, the design of these devices is not suitable for transmitting more than one type as shown in the dual-chamber storage tank. Medicaments, in addition, do not disclose how to fill the storage tank in order to reposition the position of the liquid medication. The need for a subcutaneous sealed device is derived from the characterization of the agent and tissue. Among the many drug-related factors, including slight differences in effective toxicological concentrations, their inability to deactivate before reaching the target tissue, or a high degree of long-term and stable release curve (in particular for chronic diseases) 5 1323667 And its availability in liquid or gel state. The tissue factor is primarily related to the phenotypic specificity required for the drug, and it is equally important that it is not susceptible to the toxicity of the surrounding tissue. Because the drug may ooze near the device-tissue interface, certain very important drugs (including toxic drugs and other more specific drugs) cannot be used in the drug delivery device • except where it should be exposed The angiogenic peptide must not be exposed to other tissue locations. If the target is to increase blood flow and stimulate microvascular growth, if the angiogenic peptides are exposed to the vascular tissue around the eyes before passing through the adult membrane, in addition to dissipating the effect of generating blood vessels, it will increase. The blood flow and plasma at the implant, and the decomposition and neutralization of the active agents are added. In addition, the biological procedure occurring at that location will change with any release mode of the drug from the delivery device' whether the pharmaceutical system is active or not. The inflammatory response is a basic reaction in the self-healing process of mammals, involving the involvement of a variety of chemical, biological and cytokines, and finally leads to the formation of tissue 4 and the appearance of foreign bodies as an injured organism and Common ruminants after surgical injury, especially when exposed to inert or immunological substances. These reactions are generated by recombining the injured group key + ^ ^ and the team through a series of reactions. Usually, the injured tissue will be strengthened or the foreign object will be isolated. Much of the experience of periocular implants over the past decade has been attributed to circular elements used to treat iris shedding and filtration devices for glaucoma surgery. Because of the above-mentioned objectives, many polymers have been tested, and years of accumulated experience have revealed that implant implants of varying degrees can occur after implantation of the implant around the eye. Even for medical products that have been widely used (such as hair spray), the coating phenomenon can be observed on the third day of implantation. However, the &' body does not cause much damage to the fibrotic response of prosthetic or structural implants. Conversely, it can even provide the desired mechanical stability of the implant to enhance its structural function. The lack of a means of reaching and sealing the drug delivery device to the subcutaneous tissue not only affects how the drug is carried and its interaction with the surrounding tissue, but also affects the surrounding tissue's response to the drug and the delivery system. The coating phenomenon of such systems and the scar tissue formed on the drug storage tank and organ surface will significantly change the mode of drug release and change the main determinant of its diffusion surface (the surface is mainly composed of membranes with known characteristics). The composition, and the diffusion coefficient of certain factors. In ophthalmology, many studies have been conducted to study the characteristics of the sclera (the outermost layer of the eyeball). Many studies have used the method of injection around the eyes (periocuUr;) to deliver drugs. Edelhauser et al. have conducted many studies on the function of the sclera as a permeable membrane. The results of its in vitro tests have been further confirmed by in vivo tests, showing that periocular injections deliver the drug to the internal tissues of the eye. The results show that molecules up to 7 〇 Kda can diffuse through the sclera and reach the intraocular space, even if there is a pressure gradient. Although the true mechanism of such properties is not well understood (especially the mechanism by which these macromolecules can reach the intravitreal space with highly selective barrier structures such as blood-retinal barriers), 7 丄β Sex can be explained by the porous nature of scleral collagen. Indeed, the rule of the ruler, the path that can pass through the sclera has been used for many years, and it has been proven that *^^ has some medicine to administer certain drugs. Anti-inflammatory steroid drugs are injected through the conjunctiva to the space below the orbital membrane and in direct contact with the sclera, which allows the drug to diffuse into the intraocular space for the purpose of providing therapeutic agents to various layers of the eye. A sterol formulation with a safety and equivalence or super effective achievable system that does not have side effects has been provided. However, because these injections do not protect the tissues surrounding the eye from exposure to the injectables, most of the injected drugs are systematically absorbed into the surrounding tissue and taken away from the injection site. Therefore, such an injection is a short-acting drug. Some other drugs that are used because of the high concentration of the eye layer that is required to pass through the eye may cause severe allergies or toxicity to surrounding tissues, and therefore cannot be administered by such a peripheral injection route. Due to the injection route around this eye, the agent dissipates quite quickly (this is mainly caused by the cleaning mechanism of the soft tissue of the eye, or by the composition of the inflammatory cells, immunoglobulins and plasma to allow the agents to reach their target tissues. It has been inactivated before, so it is necessary to use a high concentration of the drug 6 In some cases, such as endophitis, the intraocular concentration used can provide a high amount of antibiotics to the eye in a short period of time. . However, for patients with chronic conditions, repeated intraocular injections are likely to cause complications (possibly due to injection procedures or immediate high-concentration agents provided by direct injection). In addition, intraocular injection 323667 can not always be used, such as inflammatory conditions such as uveitis, especially serious abnormalities such as Behcet's syndrome', even the least invasive intraocular injection can cause serious and Long-term low-tension (ie, low osmotic pressure) conditions. Since cancer cells may detach from the original position and disperse throughout the eyeball, the cancer is also required for non-invasive treatment. The most common intraocular tumor in children, retinoblastoma, is an eye disease that is suitable for the delivery of local chemotherapeutic agents. Its clinical feature is that the cancer cell line is planted on the vitreous gelatinous substance, which is currently treated with systemic chemotherapy. Systemic treatment often results in failure of treatment due to the inability to achieve a therapeutic concentration at the site of treatment, and ultimately the eyeball must be removed. It is almost impossible to apply the agent directly to the vitreous, because it is very likely to cause the cancer cells to disengage from the original and spread, which directly leads to the death of the patient. Local treatment is another option and is currently in clinical trials. There have been some encouraging results, but some toxic side effects have also been reported. In certain situations, high concentrations of cytotoxic agents in the eye, such as the hardened surface, may cause an unexpected episode in the patient's limited life. In particular, retinoblastoma is more susceptible to cytogenesis due to genetic mutations. A similar agent treatment effect can also be obtained if the agent injected around the eye is isolated from the extraocular & green tissue, as it provides 4S 1 release and causes lower side effects on the eye tissue and optical nerves. Since the interface area in contact with the agent, which is the primary factor determining the rate of diffusion of the agent through the film, is clearly defined, controlled release of the agent such as 1323667 can also be achieved. The location of the drug in contact with a particular area of the sclera also prevents exposure of more sensitive tissue (e.g., optical nerves) to such high concentrations of toxic agents. Regional treatment has been studied in detail and has proven to be very effective in many situations. Although drug delivery systems based on polymer technology have improved the bioavailability and pharmacokinetic properties of therapeutic agents in the tissue, the lack of local specificity is still a major limitation of the technology in clinical applications. New types of therapeutic agents offer little hope, but the inability to deliver such agents to the tissue in a rapid, efficient and specific manner also limits their success in in vitro testing. Many of these agents do not produce the same experimental results as in vitro tests when tested in the sputum. In addition, once a natural component such as an organ is broken by surgery, the cancer cells and infectious agents can be dispersed to other organs or even the entire system. The above system can provide therapeutic effects by releasing the agent to the chamber or surrounding tissue space and fluid without directly delivering the agent to the target interstitial tissue. This ultimately can result in the organ absorbing the agent from any surrounding structure. However, such systems lack specificity and are not suitable for clinical use when the surrounding tissue is toxic. This problem becomes more serious when the agent may initiate a pathological response. This problem is more common in the case of viral gene vectors, bioactive factor inhibitors, and non-specific sensitizers. The patch delivery system is developed to deliver or release the drug through the skin or mucous membrane. "These systems are designed to have an interface with the skin or mucosal epidermis, and the 10/agent is released through this interface. The other interface is usually the outside of the target body tissue, that is, the scorpion! In the case of the skin delivery system, it refers to the external environment; for the transmucosal transmission, the hand is especially 丄 ' w, then the intestine cavity or the mouth. The main consideration when designing a far-end device is that the release of the drug is not broken by the secretions of the gastrointestinal, oral and nasal passages, and m is said to allow more agents to reach the circulatory system afterwards instead of directly Act on the target tissue or organ. For the transmucosal delivery device, any neutralizing enzymes, flora or physical inactivation mechanisms from the outer surface are neutralized or transferred to the circulation after being absorbed by the distal end. It is also the ultimate goal of most drug delivery systems. This type of transdermal 哎... 贴 mucous membrane delivery system has never been developed in the direction of surgical implant systems; Α has never been exposed to fluids in the body (ie, blood, connective tissue test /-£ _ JL - the wind biocompatibility after any cell reaction) was studied. Its possible applications are exposed to body fluids and are therefore not subject to severe inflammatory J5 u underreaction and do not require very high biocompatibility. Polymer barriers such as polymer barriers for release of medicaments and ophthalmic polymer systems have some of the same characteristics as transdermal or mucosal delivery systems. The purpose is not to deliver the agent directly to the cornea or conjunctiva or to any specific eye structure, and ifij疋 releases the agent in multiple directions into the body's secretions, such as the tear layer. The agent begins to diffuse through the surface of the eye from the tear layer and then reaches the tear discharge system and the nasopharyngeal mucosa, again exposing other tissues to possible toxic side effects. Such systems provide long-acting release, but are non-specific long-acting release' effects that dissipate toward all surrounding tissues (ie, conjunctiva, LID skin 1323667 skin, cornea, lacrimal gland system). Like systems, such systems are designed for products that are not surgically implanted. As a patch delivered through the skin or mucous membrane to provide non-invasive long-acting release, and is only attached to the body or mucosal surface and experimental and clinical evidence that the surface of the saddle is not exposed to high doses, It may cause the internal shovel to reach the dose of & dose, even higher than the systemic application can achieve the itch? The potential spread of the && organization and organization will be discussed below, as well as the advantages of the decision, Α, as a treatment path, etc., as discussed below. Bioactive skin is the essential substance naturally present in biological procedures' but in the state of disease (eg, cancer, choroidal neovascular membrane), there may or may not be present (eg, ischemic myocardial site) "Reducing this type of disease to or from T will improve the disease state' and when it is used as an effective therapeutic agent, it will need to be able to deliver it to the target tissue in a long-term and continuous manner. The same protective regulatory delivery is also found in the delivery of gene vectors, antisense agents, antibiotics, cytotoxic agents, alizarin, certain hormones, and the like. Other known sensitizers also require a specific effect. In addition, the agent that is resorbed for the target tissue will then be used to define the utility of a particular treatment (ie, chemotherapy, laser, radiation, or heat treatment), such as limiting or enhancing its effectiveness. And side effects on the treatment location. The effect of topical drug delivery for the treatment of intracranial cancer is currently in clinical trials. Certain nerve-derived tumors, such as collagenblastoma, are currently receiving considerable attention. These tumors were treated with standard surgical resection plus external 12 1323667 radiation therapy. Since this type of tumor invades Zhouyuan brain tissue, it often recurs at the edge of the resection site ^ ^ _ γ. Based on these characteristics and the tumors that have not responded to systemic chemotherapy, it began to consider local delivery of agents, sensitizers and peptides, and studied their effects on the quality of life of patients as a treatment option. possibility.

Brem et al. reported that controlled release of a polymer containing 3 (:\1; prolongs the lifespan of patients with recurrent collagen blastoma. This type of polymer releases 50% of the drug in the first 24 hours, and to 丨2 hours of release of 95% of the drug is prepared. Another report indicates that there is a high probability of complications surrounding the surgery, such as wound infections and strokes, and is no more effective than traditional therapies. Exposure of tissues to high concentrations Therapeutic agents will improve the efficacy without systemic side effects, but at the same time increase the risk of local side effects, usually referring to dose-related side effects. The prior art did not find a selective and protective local delivery system can be substantial To improve the therapeutic effect, as well as to make the potentially toxic agents of the surrounding tissue that have never been acceptable for use become available agents, and the pro-system is designed to deliver the agent to the implantation site without The nearby normal tissue provides any protection. For example, there are many studies dedicated to the development of delivery of bioactive agents to the myocardium or myocardial surface. Inter-local therapy. Currently, pericardial effusion syndrom and metastatic tumors respond best to 13 1323667, which delivers local chemotherapeutic agents (transporting 5-fluorouracil and cisplatin to the inner periphery of the myocardium). Effectively provide high dose of drugs on the surface of the myocardium, but if chronic chronic use, there may be a risk of secondary infection.

An exquisite experiment by Darsino et al. showed that the pharmacokinetic study of digoxin and lidocaine in various heart tissues (including valves) showed that after injection of these compounds around the heart, Irregular distribution pattern in cardiac tissue. For patients with arrhythmia and dysfunction of the heart, it is preferable that a system can be specific to a predetermined position of the same organ. Compared with other heart tissues, the absorption of digoxigenin and the absorption of digoxigenin and lidocaine in the aorta around the heart is the highest in 20 to 60 minutes. Lidocaine is evenly distributed on the LV wall within 30 to 60 minutes, and 50 micrograms of digitalis are mainly concentrated under the surface of the heart. This pattern of distribution limits the administration of these agents in a manner that is within the surface of the heart, as higher amounts of the agent will be required in these areas. In the other experiment, the same author also pointed out that the concentration of amiodarone (AMI0DAR0NE) injected into the heart circumference is higher under the surface of the heart than in the deep left atrium. As for the blood, it is measured. Less than these drugs. Preferably, the preferred distribution of these agents is such that certain areas have a higher absorption of the agent. The injection will expose the entire surface of the myocardium to the agent, while the rate of resorption of the different regions will be different. This results in an uncontrolled surface transport pattern. The utility of a bioactive agent as a therapeutic agent depends on its delivery route. For some biologically active purines, 'the natural form makes it more susceptible to inactivation or is saturated with many naturally occurring factors before reaching the target tissue. β 14 1423667 Some growth factors and other compounds increase myocardial infarction areas. Newborn blood vessels. Uchida et al. showed in a model of myocardial infarction in dogs that the injection of basal fibroblast growth factor (bFGF) and heparin sulfate in the pericardium can effectively promote vascular proliferation and can be rescued compared to the infarcted area of the myocardium. More areas of myocardial surface infarction. Further experiments on the pig's chronic heart infarction model system have again confirmed that injection of basic fibroblast growth factor (bFGF) and heparin sulfate around the heart is effective in promoting vascular proliferation. Although the results of animal testing are encouraging, the ability to administer medications to human patients with the aforementioned devices, including cardiac catheterization, remains a major concern. ° Use of this type of application is worsened and the blood of the eyes is suppressed, so 'if the blood vessels grow will be different. In order to make the area of the sound, the pathological area is locally, continuously, and achieves the above purpose, which may potentially make the injection more advantageous, and some people have considered the intravascular route of administration, and the comparison. However, the results are not better than the placebo group. A major concern is the potential risk of retinal vascular disease. Angiogenic factors tend to bind to their receptors. They are saturated before reaching the deep tissue. The result is that the distribution of factors in the tissue layer is not uniform, and the effect of flb reaching the deep layer of the myocardium must be such that it does not and does not affect And its effect is limited to a specific pathological area, so that the specific object can make the drug reach the deep tissue after prolonged action. _ Protected and selectively delivered drugs will be more effective and have fewer side effects; more patients benefit from minimally invasive implantation procedures. This strategy provides the effect of intracardiac injection on the effect of intracardiac injection. 15 1323667 There have been many studies dedicated to the topical use of bioactive agents. Angiogenesis inhibitors are potentially useful tools for the treatment of ocular vascular proliferative disorders (eg, premature retinopathy and age-related degenerative macula, & both diseases are the leading causes of blindness in premature newborns or blindness in the elderly) . [Contents] According to an embodiment of the present invention, there is provided an implantable, sealed drug delivery system that provides a local performance release therapeutic agent for direct and selective release into a mammalian internal organ, tissue or system . A preferred embodiment includes an isolated drug storage reservoir for selectively exposing the drug to the target tissue structure via the interface. The interface control of the device is achieved by the sealing mechanism provided by the sealing method described herein. Disclosed is a simple, novel method of providing a topical or systemic therapeutic agent that delivers the agent, tissue or system directly, unidirectionally, and in a protective manner to a mammal. The device of the present invention can deliver the therapeutic agent to a specific tissue surrounded by the body fluid in a preferred manner, and expose only the target tissue to a high dose of the therapeutic agent for a long period of time, and avoid the formation of the surrounding tissue structure. Any undesired side effects. In one embodiment, the drug reservoir is isolated from surrounding structures and liquids by a layer of polymer that is not permeable to the therapeutic agent being carried. A transfer port or interface window is provided on the seat of the device to provide a surrounding controllable interface or interface window for the release of the contained agent 16^23667 to the target group. In contact with the slow release of the tissue. Connect the unit to a series of structural group seals. The present invention is capable of implanting a therapeutic drug platform and a transplanter for mammalian performance in a collapsible transport or weaving system. The present invention is an allergic agent, magnetic or diagnostic. A channel that can be woven. The interface window is sealed to the tissue surface by a sealing structure to ensure a sufficient degree of subcutaneous sealing for the expansion mechanism. The transmission can be covered by a structural layer that is not transparent to the therapeutic agent, or covered by a structural layer. In some cases, when the therapeutic agent is implanted, the transfer port or interface window does not need to be formulated for any substance, so that the pill in the storage tank can be directly labeled with the embodiment, and the device holder includes a connection. The mechanism is provided by the subject organization. This is provided by a series of structures that enable the system and the target tissue to provide a therapeutic or prophylactic therapeutic or physiological agent between the system and the target tissue. In the system. The present invention can provide a carrier or a physiological sword to an artificial organ, cell structure or tissue or tissue. The present invention can be used to selectively or protectively release a medicament by a minimally invasive procedure, a flexible or extensible drug delivery device for selecting a therapeutic or physiological agent to a mammalian organ or group. In a manner that scatters through the target interface 'and avoids dissipating the agent to the surrounding node and also provides a selective delivery or radiation agent to the mammalian organ or tissue, which provides a treatment for these structures. Know the invention. 17 1323667 The present invention relates to a topical drug delivery device. The system of the present invention is useful in the treatment of diseases or in the treatment of conditions requiring local delivery of a therapeutic agent to a mammalian organ. The system of the present invention is designed to be applied to a tissue or device e surface and to perform the function of releasing the tincture on the surface of the tissue or organ. The present invention includes a device that provides controlled release of a therapeutic agent for passage through and distribution to an organ or tissue layer. A method of achieving the objects of the present invention involves designing a structure that allows the drug reservoir to be subcutaneously sealed to a target tissue surface and maintains its seal with the skin to maintain the diffusion drug pattern for a prolonged period of time. Embodiments of the invention also include structures that allow for backfilling of the medicament to the reservoir or for refilling more than one therapeutic agent for a useful period of time. The system of the invention is also designed to be applied to the surface of any organ or tissue. The figures show their application to the eye, but the same method can be applied to other organs and tissues. Figure 1 is a schematic cross-sectional view of a human eye; to understand the system of the present invention, it is necessary to first understand the relationship of the various structures shown. The linear structure of the eye includes the anterior cornea (9) and the posterior sclera (1). The cornea (9) is covered with a layer of tears that can be exposed to the environment. The sclera (1) is surrounded by tissue around the eye (6). These tissues include the Ten〇n's capsule and the extraocular muscles. The sclera is related to the structure of the posterior segment of the eye, and the cornea is related to the structure of the anterior segment of the eye. The crystal is separated from each other by the lens, mainly the gavity. The front end of the cavity is filled with the body fluid solution (8), and the rear end is filled with the vitreous gel 18 1323667 (4)»In some cases, the vitreous gel system can be replaced by a body fluid solution or a synthetic substance. For example, oyster sauce or gas ceremony. The body fluid solution is made of the ciliary body (7). When excessive, it causes an increase in intraocular pressure and finally causes an eye of the sound. One of the ways to reduce IOP is to interfere with the manufacturing process of the solution. As for the glassy gel, it is a residual embryonic structure that occupies most of the post-clear structure volume, which is composed of water and a collagen-proteoglycan network and will not be replaced for life. The sclera is associated with the internal choroid (2), which consists of the retinal vascular network Bruch's membrane, the retinal pigment epidermal (RPE) basement, and RPE. These structures play a very important role in the visual process dominated by photoreceptors on the innermost layer of the retina (3). The choroid extends forward in the retina serrated edge to become a flat portion (10). The choroid, flat, side wall, and iris are all composed of uveal tissue, which is also the site of inflammation and infection in the eye. The sclera is located behind a corneal ganglion cell and is called a porous structure called a tear screen. The corneal axons extend to form an optical nerve, which is responsible for transmitting visual signals to the visual cortex of the brain. Figure 2 is a schematic cross-sectional view of the tissue of the eye showing the relationship between the sclera (15), the choroid (14), the RPE complex (13), the retina (12), and the vitreous gel (u). Figure 3 is a top view of the apparatus of the present invention. The system of the present invention comprises a storage tank type body constructed of a polymer structure, preferably (but not limited to) injection molding, compression molding, transfer and extrusion molding, depending on the polymer used, Copolymer 'or matrix'. The choice of polymer depends on the type of tissue or organ to be implanted. Preferably, but not limited to, polyacetamidine, anthrone, water 19 1323667 gelatin, poly-o-esters, polyoxalic acid, polylactic acid, polycaprolactone, polyethylhydrin or any derivative thereof . The structure 16 is designed to stabilize the crease lines. The seal 18 will maximize the sealing effect between the gas-tight seal and the target tissue surface. Fig. 4 is a schematic cross-sectional view of the embodiment, which comprises a reservoir 20 containing a medicament. The outer surface I9 continues as the sealing seat 2, and a gas-tight seal with the target tissue surface 24 can be provided by the use of an adhesive layer 22. Figure 5 is a cross-sectional view of the apparatus of the present invention having two biocompatible storage tanks. The storage tank is separated by an inner wall 28 that extends beyond the surface of the target tissue as shown by arc 29 to provide The hermetic sealing effect with the tissue 'and avoids the action of the agent on the tissue before reaching the surface 30. The suture ballast 26 is also disclosed. The sixth side shows a bottom side view of the two biocompatible storage tanks 32, the partitioned inner wall 31, and the sealing base 34 having the adhesive layer 33 thereon. Section 7 is a bottom side view of Example 35 of a single storage tank and its relationship to the sealing base 36' adhesive layer 37, outer surface 39 and suture ballast. Preferably, the outer curve of the sealing base 36 conforms to the target tissue curve. Section 8 is an embodiment in which the device of the present invention is applied to the eye. In this embodiment, the intraocular system has an intraocular tumor called "retinoblastoma", which is an intraocular tumor mainly occurring in childhood. The sclera adjacent tissue is incised by a peritomy to expose the scleral surface 41. The extraocular muscles are separated by a standard technique to provide a more comprehensive control of the exposed (four) scleral area. Once the tissue around the eye on the surface of the scleral region 20 1323667 is removed, the implant 42 (in this case, the cytotoxic agent is carried) is placed at a fixed point with an applicator or hand. The suture 4 5 passes from one side of the implant to the other, passing it through and securing the ballast 44 to allow the sealing base 42 to produce a moderate tighting effect and maximize sealing. The suture needs to pass through the entire scleral thickness. After implantation, the muscles are released and the conjunctiva can return to its original position covering the surface of the eye and sewed close to the cornea. Figure 9 is a top view of the implant 49 when it is sewn to the tissue 46. The suture stabilizer 47 allows the suture to secure the implant at a fixed point, but primarily creates a gas-tight effect between the implant device and the target surface. Figure 10 is a bottom plan view of the inner surface of the device of the present invention in contact with the surface of the sclera. The interface window 55 is surrounded by a sealed base 54. The outermost edge of the sealing base 54 is coated with an adhesive layer 53. Figure 11 is a cross-sectional view of the device of the present invention applied to the surface of the tissue. The device shown is the interface between the reservoir and the tissue. It also reveals the relationship between the sealing base 58 and the target tissue. In this case, the air-closing effect is achieved by covering the base 58 with an adhesive layer 59. The 12th circle is a cross-sectional view between the device of the present invention and the target tissue 65. The illustration shows the interface between the sealing base 63 and the sclera 65, and the subcutaneous sealing effect provided by an adhesive layer 64. Figure 13 is a cross-sectional illustration of a single lumen 67 device adjacent to the sclera 71. Also disclosed is a method of filling the reservoir. The outer surface 66 of the device includes a filling bowl 68, preferably made of self-sealing rubber. The drug, volume 21 1323667 is easy or suspension is injected through a cannula or needle device 69. A flushing device can also be used to extract any residual solution and backfill the reservoir with a new solution or agent. . The filling cassette 68 is constructed to have an angle that is suitable for its position to be inserted into the needle 69. The fourth view is the bottom view of the inner surface of the device, showing the seal base 75, the adhesive layer 76, the outer surface 73, the suture ballast 72, and a filling port 74 that can contact the external environment and the internal storage tank 77. Relationship. Preferably, the filling crucible is produced in a molding process for molding the outer surface 72, and is later completed by a second process in which a rubber having a self-sealing effect is incorporated into the cavity or cavity of the crucible. The rubber with a self-sealing effect is preferably, but not limited to, a ketone. Preferably, the position of the iliac 74 and its access to the reservoir are such that it can be inserted into a filling needle device or cannula. Figure 15 is a top view of the device showing the relationship between the filling dam 78 and the outer surface 79. To improve the self-sealing effect, depending on the thickness of the outer surface 79, it can be constructed to increase the length of the tunnel and maximize the gas-tight sealing effect of the crucible 78. Figure 16 shows the relationship between the device 84 of the present invention and a tissue surface 82. It is to be understood that the sealing base 85 is made porous by the plurality of holes 83 to allow a suture having a sealing effect to be applied to the base 85. Another variation is to create a narrower channel around the surface of the sealing base to accommodate continuous or continuous stitching of the suture to the base during the implantation procedure. The seventh step is the application of the device 87 to the surface of a human eye sclera, which is achieved by suture 88 to seal the base to the target tissue. Figure 18 shows a passage 94 built into the outer surface 95 of the device. An example of a passage through the device to provide a sealing effect between the base and the target tissue. The passage 94 is provided for conforming to a ring member, preferably by, but not limited to, anthrone. to make. Figure 19 is a view of the device of the present invention applied to the eye and located in contact with the sclera 89 and below the annular member 93. The annular element 93 is placed by a technique associated with the retinal membrane separation process but not the retinal separation procedure. Once the ring member is secured, the base functions as a hermetic seal. Figure 20 shows the application of device 98, which in this example is a dual chamber device under a ring member 97. By this method, the device resting on the sclera can achieve a subcutaneous sealing effect by a gas-tight sealing position 99. In addition, other devices can be placed anywhere under the ring member 97, depending on the dosage and number of therapeutic agents that must be delivered. Another 21st aspect of the invention discloses another variation of the inner surface in which a biodegradable polymer 100 is coated on the inner surface of a reservoir containing the medicament. This plating is preferably applied between the pedestal and the adhesive layer 1 〇 1 . This is accomplished by providing a series of window-shaped apertures along the outermost portion of the biodegradable polymer 100. There are many variations to this embodiment, which are readily apparent to those skilled in the art and will be discussed below. Figure 22 is a bottom view of the device of the present invention showing the main body 丨〇3, the suture ballast 102, The relationship between the biodegradable layer ι〇6 and the adhesive layer ι〇4 in the sealed base 105' is 23 1323667. Figure 23 is a cross-sectional view of the relationship between the device and the eye of the present invention. The device comprises a single chamber 108' having a drug solution therein and held by a biodegradable layer 111 to prevent the secret: 尧 cage: ** 々 琢, valley liquid leakage or before subcutaneous gas sealing Being exposed to the tissue. The coating layer lu has a structural function, and after dissolution, the agent or drug is exposed to the sclera and penetrates the layers of the eye. The invention is described in detail. In one embodiment, the invention relates to a selective delivery treatment to a mammalian organ, A new method of tissue or system by implanting a device system that forms a seal with the skin, the device system providing a long-lasting, protective release of a therapeutic agent to ensure diffusion of the therapeutic agent through the target group Weaving the interface and avoiding the dissipating of the agent to adjacent structures. The present invention has been developed based on some unexpected findings, including the discovery that the drug system can be safely and predictably delivered to a particular tissue with a therapeutic anti-therapeutic amount. Even if it is a local tissue, it is achieved by controlling the amount of the drug exposed on the surface of the organ, and by controlling the drug to the internal tissues and fluids of the body. This maintenance of the organ surface by osmotic, physical, scientific or biological treatment allows the agent to be isolated or confined to a particular zone by a sealing mechanism. The drug-related polymer and osmotic agent can be used to control the drug exposed on the surface of the organ. It is best to use a drug that cannot be separated here. These or pre-extrusion agents are used to coat the drug storage tank against the polymer of 24 1323667, wherein the drug that cannot pass the polymer is the active agent, and the agent is prevented from dissipating to the adjacent structure. Or the fluid is toxic or makes the utilization of the tissue higher than the standard. This can be achieved by a series of structures that maintain the subcutaneous sealing relationship between the device and the target tissue. The inventors have discovered that the system of the present invention provides a means of delivering drugs to tissues or organs. More advantages, and allowing agents that were previously considered to be ineffective for clinical treatment due to insufficient specificity, can be used again in the treatment of diseases, so the novel drug delivery method of the present invention can help develop new drugs or find out conventional knowledge. An alternative to drugs and used to treat diseases. The invention also allows for the development of new treatment modalities such as the development of organ transplants, tissue regeneration techniques, artificial organs or tissue transplants. This will provide any therapeutic or physiological support required to rely on new techniques for incorporating or maintaining an implant in vivo. The drug in the reservoir can be associated with or mixed with other agents, polymers or osmotic agents. A multi-layered medicament can be provided which can then deliver a second layer of medicament after delivery of the first layer of medicament. It is also possible to use a multi-chamber storage tank which also has an inner wall which separates the cavity by $. The main Zhao Wei includes walls that can distinguish the cavity. Preferably, the dividing wall may extend slightly beyond its relative height to the arc or surface of the sclera to separate the %~ ▲ Yang Zhao Temple structure at the interface. This allows the different agents to be minimized in their ability to merge or act from % before reaching their target surface.

The interface window can be plated and or contain -A promoters that help the drug spread to the tissue, such as enzymes. Collagenase, & 4, adenine analogues, matrix gold 25 1323667 Protease, hydratase are enzymes that improve the diffusion properties of the sclera or tissue surface. The replating procedure is preferably accomplished when the solid drug is compressed or during the preparation of the drug and mixed with its polymer or carrier. If a stable, long-lasting release is desired, the coating can be evenly dispersed throughout the reservoir' or the coating can be applied to the interior surface that will contact the sclera. Depending on the reaction and stability between the accelerator and the active therapeutic agent, a layer of accelerator may be incorporated into the interior surface of the reservoir. It is preferably prepared using a biodegradable material such as collagen, gelatin, oxalic acid, cellulose, and lactic acid. Alternatively, any material that does not directly interfere with the release of the agent from the reservoir and that does not interfere with exposure of the agent to the target tissue process can be made. In other words, it is not expected that the substance carrying the promoter will play any important role in the rate of drug release, but rather the role of the promoter itself on the surface of the target tissue. This layer is referred to as a functional layer containing a drug or accelerator which will affect the rate of diffusion and the pharmacokinetic properties of the given agent in the future. An inner layer composed of a rapidly biodegradable polymer, which is constructed of gelatin, hydrated acid, methyl cellulose, polyoxalic acid, or polylactic acid to allow liquid, powder, and viscous substances to be retained. In the storage tank, it can also remain stable on the surface of the tissue. This process is preferably accomplished by placing the layer between the sealing base and the bonding layer, while also allowing for a strong bond between the bonding and the sealing base. An accompanying channel around the interface window also allows the layer to be embossed or any material like a seal seat or device that constructs a circle of material that conforms to and fits within the tunnel so that the layer is mechanically placed or adhered The interface is trapped in the tunnel. 26 1323667 Interface window, that is, where the storage tank is exposed to the target tissue, surrounded by a sealed base formed by the extension of the polymer wall, or the base can be composed of a variety of different polymers. It is formed by a bonding mechanism or by sticking it together with an adhesive. The outer surface of the sealing base may be composed of different components that have been mechanically incorporated into the body assembly. The core device is limited to a layer of polymer that can hold a liquid or mucus in the storage tank. To avoid premature exposure of the agent or to avoid leakage, or to stabilize the aforementioned accelerator carrier layer. This method is much like a method of handling sandwiches, and later the interface window area will be the main factor in determining the interference. Thereafter, the piece will have the aforementioned features to allow for a subcutaneous seal state. The materials used to construct the device of the present invention between the drug storage tank and the target surface as a sealed base and the exposed target tissue include, but are not limited to, polyethylene, fluorenone, hydration glue, poly - adjacent Xue, polyoxalic acid, polylactic acid, poly-caprolactone, polyvinyl alcohol, polyethyl ketone, and any derivatives thereof; and such as sugar acid, fibrin, methyl cellulose, collagen Biocompatible polymers such as protein gelatin and any derivatives thereof can be used to construct other parts of the device of the present invention. It is preferred to utilize a designed surface to permit and protect the treatment by using a drug that is impervious to flow. As for the nature of the exogenous agent and the carrier polymer, the structure allows the device to be subcutaneously sealed to the surface of the target interface. The outer surface 'can be achieved whether the agent can only pass the external body fluid on one side, then 'and whether it needs to use a solution of 27 1323 667 to regulate the release of the drug from the site 丄 ^ _ feeding tank 〃 The release mechanism of this type of agent may be simply to dissolve the drug/polymer by the fluid entering the drug storage tank, or to use an osmotic agent to regulate the amount of water flowing in and the dissolution rate of the agent before passing through the surface of the target. The embodiment as described herein is achieved by incorporating a series of structures to achieve a subcutaneous, sealed surface of the device. The first structure is the sealing base which is mainly composed of a sealable way. The surface extending beyond the interface window is required to achieve the sealing contact area, whether or not the contact surface has been coated with a layer of adhesive. Whether or not. At the same time, the sealing base preferably conforms to the curve of the target surface itself, although it is generally designed to achieve greater sealing by achieving greater sealing, especially if the material used is an elastomer. Combine the use of one or more or more of the other features to achieve maximum sealing. These auxiliary structures also help to achieve the controlled release of the drug. The first auxiliary structure is a buckle stitch stabilizer or a stitch stabilizer. This is a projection, channel or channel disposed and constructed along the outer surface to prevent the suture from slipping out of the implant when the device is secured to the tissue with the suture. One or more such suture ballast structures may be provided depending on the size of the device and the location of the tissue to be implanted. Preferably, such suture ballasts are molded from the same material used to make the outer surface. Alternatively, it can also be made of different materials and incorporated into the device during a later molding process. The second auxiliary device is a buckling belt or a house such as a part of the department, the system 28 1323667 is pressed into the outer surface by a diameter that can pass through the entire outer surface to allow a surrounding component to be placed and provided The sealed state of the device and the standard. Preferably, it is attached to the outer surface during the molding process. A third type of auxiliary device is a plurality of holes disposed along the base that pass through the base of the fixture. Preferably, the holes are provided in the periphery of the base or in the periphery of the base to serve as a sealed base, while a liner is used to surround the thinner edges to apply the suture using an automated device. The above-described use of the drug delivery device to be subcutaneously sealed is primarily intended to reduce the interference of the peripheral liquid in the diffusion mechanism between the drug-tissue interface. In addition, it plays a very important role in avoiding the toxicity of the drug in which the tissue is violent. The fluid transport before the dissolution of the agent is mainly through two kinds of non-production. The first is the diffusion of the permeate or pressure across the surface of the organ. The second is that the outer wall of the polymer is driven primarily by the osmotic pressure gradient and polymer properties with the external tissue. The concentration of the agent on the surface of the drug provider side and the molecular weight of the drug in the factors related to the passage of the drug through the biofilm provide the desired amount at the specific site of the tissue. Others need to consider the properties of the membrane and the pharmacokinetic properties of the drug in the tissue. Although it is a biological factor, it can be constructed between the surfaces of the mechanism exposed to the device and the drug. The device allows the suture to be molded into the sealing bottom elastic material to make the target method from the tissue and the dew. In the unnecessarily the same mechanism, the production gradient is driven by the diffusion of the storage tank as the contact area, balanced with each other, and the amount of the factor is preliminarily covered by these factors, by 29 1323667 by physical, chemical or biological methods. In other words, the bioavailability and pharmacokinetic properties of the permeable drug will vary with the path it may traverse, and will therefore help to understand which combination of compounds is appropriate. The system of the present invention can also have many different variations and presentations. For example, the device of the present invention can carry an enhancer, preferably, but not limited to, an enzyme and a protein such as albumin. The outer surface may be composed of a polymer which is impermeable to the carrier, preferably, but not limited to, anthrone, polyoxalate, polylactic acid, derivatives, polyethylenol, acrylate, and propionate. , cellulose, collagen, metal, derivatives of any of the above polymers or related substances, or any other material having properties that do not allow the passage of the carrier. The outer surface of the device may comprise a filling crucible, preferably, but not limited to, made of a self-sealing material, such as an anthrone rubber. The current design uses as many as the device' while also creating multiple filling ports in the device. These structures are built on the outer surface to contact the outside environment and the interior of the storage tank. In order for the tendon to be readily recognized after implantation, the fistula is labeled with a biocompatible, radiosensitive marker or dye. Alternatively, the crucible is designed to extend beyond the outer surface of the device and position it on a relatively accessible portion of the device body. The device of the present invention is foldable or resilient so as to be implantable into the body from a small surgical incision, and Can be close to the surface of irregular organs. The invention includes a method of selectively administering a desired dose to a mammalian organ, tissue or system by controlling the passage of the drug through a standard device interface. It is better, but not limited to, by gelatin, internal tooth, glycocalyx, cellulose, poly. The compounds and or compositions of oxalic acid, polylactic acid, and the like may be pressure sensitive, ', heat sensitive, photosensitive, or chemically sensitive compounds and or compositions. The active agent can be provided in the form of a capsule such as a fat microparticle or a microsphere. Included in the surgical implantation of the device of the present invention to the mammal. Therefore, after the invention is also in the body, the drug is directly transmitted through the target tissue interface in a one-step 'protective and durable manner', and the agent is prevented from dissipating into the surrounding tissue and fluid. Methods. The method of the present invention involves the step of contacting the device interface window loaded with the agent with the target tissue. The method of the present invention also includes the step of subcutaneously sealing the device to the target tissue in the form of an adhesive, a fixation or a suture or a combination thereof. In order to construct a viscous layer, it is preferred, but not limited to, to use hydrated gum, uronic acid, and fibrin glue. It is incorporated in a sealed base with a film or a thin layer containing adhesive on both sides or incorporated in advance by applying an adhesive on the inside of the sealed base. In order to secure the adhesive, it is preferred to provide a plurality of chambers, a separate chamber or a channel system along the inner surface of the sealing base. Preferably, these sealing structures are fabricated simultaneously during the molding of the device. After the adhesive is in contact with the base, another thin layer can be placed on the adhesive layer. Preferably, the layer does not react with the adhesive and can be torn off prior to implantation. The exposed sealing base is used in the above structure to hold the adhesive there, and also allows the adhesive to be used before the implantation, especially when the desired 31 1323667 adhesive is such as fibrin. A biological adhesive such as a beta device and an artificial organ, a synthetic or biological platform for use in a cell or biological agent, a platform for tissue or cell regeneration, and/or a transplanted tissue or device Form an interface. A method of the present invention can be performed by surgically implanting a unidirectional delivery of a drug through an interface window to make the other surface unable to pass the device through the device to the target tissue or organ 'in the mammalian organ 局部 local or secret, Physiological or pharmacological effects. One such agent may be a prophylactic therapeutic agent. With an osmotic pressure agent. ... or the device can be used after the surgical implantation - the second agent (whether it is chemical, physical or biological) to initiate the effect or spread of the gas-enhancing agent. The disease which can be treated by the present invention Examples include (not limited to) myocardial hypoxic diseases, liver cancer, diffuse hepatitis caused by rectal cancer, bladder cancer, adrenal cancer, neuroblastic cancer, kidney cancer, and pancreatic cancer. The device of the present invention can be loaded with the desired active agent (i.e., drug and/or precursor or precursor) and can be implanted and attached to the surface of the original or tissue. For example, the device can be adhered to the surface of the pericardium to deliver the medicament to the pericardial space, and the drug in the reservoir is diffused throughout the heart muscle. The device can also be directly adhered to the myocardium through a small hole in the pericardium (required that the pericardium is a capsular bag, and Rong Xiping is not a cell, but is derived from the surface of other tissues; but the myocardium is mostly like & w J into the stem cells, derived from the heart that eventually becomes muscle cells and has a clearly distinguishable surface. Preferably, the present invention is not implanted in the myocardium to deliver the drug to deep muscles or specific cell populations, preferably such invasive techniques are employed as much as possible. Thus, when it is necessary to implant, the device of the present invention preferably does not destroy the structure of the tissue to be treated. In the embodiment, the present invention discloses many applications on the eye, since the eye provides a number of mountable inventions. The location of the device. In ophthalmology, the device is preferably located in a position in contact with the sclera or in a colloidal space between the outermost layer of the eye and the vitreous (which can be reached by sclerectomy), or Even in the space under the retina. For the space under the opticureum, a sclerectomy or retina can be used to insert the implant. Eye diseases that can be treated by the device of the invention and other uses of the device of the invention include, but are not limited to, intraocular cancer, ie, retinal neuroblastoma melanoma, plaque deterioration, transmission growth factor, anti-angiogenic factor, photosensitizer ( The invention is applicable to the treatment of glaucoma by using the device of the present invention, that is, the transilluminating agent directly passes through the sclera to the ciliary body by the device of the present invention, that is, the posterior pole of the eyeball (ie, the colloid and the layer) . The device of the present invention can also be applied to the treatment of retinitis of the pigmentation to deliver a growth factor or immunosuppressive drug to protect the transplanted retina or RPE layer without jeopardizing the intraocular surgery of the transplanted plant. The present invention is designed for applications that are implanted rather than body surfaces. A specific organization within the body or eye can be calibrated by this month. • It is also considered that many drugs are in fact only specific to a particular tissue or cell (rather than other tissues or cells). In the case where the peripheral solid tissue may be injured by a drug delivery, the present invention provides a system superior to the prior art by delivering the drug to a specific tissue. In addition to treating localized diseases, the present invention also has systemic advantages. The use of the device system of the present invention to deliver growth factors to the pancreas of a diabetic patient can alter the condition of the systemic disease. The use of the system of the present invention to administer an appropriate agent to an inoperable liver such as chronic hepatitis caused by rectal cancer reduces the volume of the tumor and allows the condition to return to a retracted state. In addition to treatment, the device of the present invention can also be used to treat a patient's quality of life in order to avoid the use of more aggressive interventions such as surgical resection. Therefore, even palliative care can be accomplished by means of the present invention. The device of the present invention is particularly useful for having a tumor or a subject to be treated which can seal the interface window of the device of the present invention to facilitate drug delivery and a unique surface. The method of delivering the drug loaded by the device of the present invention may involve a variety of manual or syringe implant techniques. The device of the present invention can be implanted in a manner that can be directly visualized or directly visualized, such as ultrasound, MRI, CT scan, laparoscopic, and the like. Although the technical content of the present invention has been described by way of example, there are many variations or modifications not described in the description of the present invention, and such changes or improvements are considered to remain the present invention. Invention threats.

[The diagram simply illustrates J. The first circle is a schematic view of the cross section of the eye; the second circle is the cross section of the tissue of the eye; 34 1323667 is the top view of the device of the present invention; the fourth is the device seal of the present invention. The cross-section to the back of the eye is indicative of 囷; the fifth is a device of the invention having two biocompatible storage tanks, the sixth device being the front of the device of the invention having two biocompatible storage tanks Depending on the 囷, its sealed base and the inner layer of the bio-adhesive layer; Figure 7 is a front view of the device of the present invention, shown in its relationship with the suture ballast, the storage tank, the sealing seat and the viscous coating Figure 8 is a schematic view of the eye and the system and method of use of the present invention; Figure 9 is a top view ret · circle of the relationship between the device and the organ or tissue surface of the present invention, and Figure 10 is a single cavity of the present invention Front view of the relationship between the chamber device and the sealing seat and the viscous plating; Figure 11 is a schematic view showing the relationship between the device and the surface of the device and the method of subcutaneous sealing to the target tissue; Figure 12 is a view of the device of the present invention applied to the eye Cross section Figure 13 is a cross-sectional view showing the method of applying the device to the eye and filling the storage tank thereof; Figure 14 is a front view showing the relationship between the system of the present invention and its storage tank, filling bowl, suture ballast and sealing seat; Figure 15 is a top view of the relationship between the system of the present invention and its filling cartridge (which can be distinguished from the outer surface), the storage tank and the sealing seat; 35 1323667 Figure 16 is a view of the device of the present invention applied to the surface of an organ and through the base with surrounding sutures A top view of a method of sealing a device to the skin under a skin; a 17th view is a plan view circle of the method of the present invention applied to the surface of an eye sclera and sealing the base thereof under the skin of the target tissue: Figure 18 is a design for fixing a a barrel or an annular band ballast that seals the base of the device to the surface of the tissue; Figure 19 is a plan view of the method of applying the device to the eye and sealing it to the surface of the sclera by using a ring member; Rear view and cross-sectional view of a device of the invention applied and sealed to a human eye sclera using a ring member: Figure 21 is a biodegradable polymer plated A front view of the apparatus of the present invention providing stability of the contained storage tank; Figure 22 is a front view showing the relationship between the apparatus of the present invention and the biodegradable layer therein and a sealing device such as a suture ballast and a surrounding adhesive coating Top view

El Garden, Figure 23 is a cross-sectional view of the device of the present invention comprising a biodegradable inner layer, a sealed base, and a bioadhesive coating, and its relationship to the sclera. [Simplified description of the symbol of the component] 1 Sclera 2 Choroidal 3 Retina 4 Vitreous gel 6 Peripheral tissue 36 Ciliary body Corneal vitreous gel 8 Body fluid solution 10 Flat section 12 Retinal RPE complex 14 Choroidal sclera 16 Structure 18 Seal Seat outer surface 20 drug storage tank sealing seat 22 adhesive layer 24 tissue surface stitching ballast 27 inner wall 29 arc surface 31 inner wall storage tank 33 adhesive layer sealing base 35 sealing base 37 adhesive layer 37 stitching stabilizer 39 outer surface Muscle 41 Scleral surface seal base 43 Ballast 45 Suture tissue 47 Stitch ballast suture 49 Implant seal base 53 Adhesive layer seal base 55 Interface window seal base 59 Adhesive layer

37 interface between the storage tank and the tissue 63 sealing base adhesive layer device outer surface filling quilting line ballast filling 埠 adhesive layer filling 埠 tissue surface device sealing base stitching device of the invention device channel sealing base device biological Decomposed poly stitch line stabilizer layer biodegradable layer biodegradable plating 65 67 71 73 75 77 79 83 85 87 89 93 95 97 99 Compound 101 103 105 108 Scleral single cavity scleral outer surface sealing base storage groove outer surface Multiple hole sealing base, the invention has a scleral ring element device, an outer surface, a ring element, a gas sealing position, an adhesive layer, a main body sealing base, a single cavity

38

Claims (1)

1323667 Pickup, Patent Application Range 1. A deliverable at least one type of delivery device comprising at least: an implanted tissue of a target tissue comprising: a drug releasing bar agent to a target tissue Stored to y—first ^ ^ The storage tank I is substantially incapable of being stored in its trough with at least one first wall, Τ<first medicament reading. - Sealing base for sealing ο The drug is enclosed by the drug in which the drug is released to the target tissue: in addition to being released from the drug: (4) the storage tank release peak is the physical A method from the device A other location is delivered to the target tissue; and a connection mechanism is used to help release the drug ^ ^ ^ ^ flying material to a target group ^ ^ from the following components, including a sufficient amount of the sealing base Adhesive to a π 2 woven adhesive, a suture anchor to operatively at least one suture • any surrounding tissue, and - the device can be operatively coupled to the target tissue Ribbon element. 2. The implantable delivery device of claim 2, wherein the drug release raft has a length of one week and the perimeter forms at least a portion of the sealed base. 3. The implantable delivery device of claim 1, wherein the attachment mechanism comprises the suture holder, the drug release crotch has a one-week length, and the suture holder comprises at least one flange At least a portion of the perimeter protrudes 'where the at least one flange can secure the at least one rifling to secure the device 39 1323667 to a target tissue such that the drug release raft can be sealed to the tissue 4. As claimed in the patent application The implantable delivery device of claim 1, wherein the attachment mechanism comprises the suture holder, the drug release tab having a circumference, the suture holder comprising at least one protrusion protruding from the first wall, wherein The at least one protrusion can secure at least one suture to secure the device to a target tissue such that the drug release raft can be sealed to the tissue. 5. The implantable delivery device of claim 1, wherein the attachment mechanism comprises the suture holder, the drug release tab having a circumference, the suture holder comprising at least one groove therein In the first wall, wherein the at least one recess can secure at least one suture to secure the device to a target tissue such that the drug release raft can be sealed to the tissue. 6. The implantable delivery device of claim 1, wherein the at least one first wall forms the storage tank and comprises at least one material selected from the group consisting of an elastic material and a deformable material. Among the ethnic groups. 7. The implantable delivery device of claim 1, wherein the at least one first wall comprises at least one material selected from the group consisting of polyethylene, anthrone polymer, hydrated glue, and polyoxalic acid. , in the group consisting of polylactic acid, polycaprolactone, polyvinyl alcohol, poly-o-ester and polyvinylpyrrolidone. The implantable transfer device of claim 1, wherein the at least one first wall comprises at least one material selected from the group consisting of polyethylene and a fluorenone polymer. . 9. The implantable delivery device of claim 1, wherein the device further comprises a filling cartridge. 10. The implantable delivery device of claim 9, wherein the filling tether is distinguishable from the first wall by the naked eye. 11. The implantable delivery device of claim 9, wherein the filling cartridge is formed from a self-sealing polymer. 12. The implantable delivery device of claim 9, wherein the filling cartridge comprises a biocompatible dye, a radiosensitive marker, and a reflectable wavelength marker ( An implantable delivery device according to claim 9, wherein the filling device protrudes outwardly from the device to aid in filling or aspiration. 14. The implantable delivery device of claim 1, further comprising a first medicament or a prophylactic agent. 41 1323667 15. The apparatus according to claim 14, wherein the first agent is selected from the group consisting of an anti-proliferative agent, a peptide, an anti-Zhao, a middle hormone, a protein, a radiation sensitizer, In the group consisting of photosensitizers, sputum sputum, chemotherapeutic sensitizers, stimuli & cells, viruses, bacteria and nucleic acids. Porous animals are further included. 16. Implantation as described in the scope of the patent application The delivery device comprises a cytotoxic agent. 17. The implantable delivery of a carrier containing the agent according to claim 14 of the patent application. Further comprising: 18. implanted as described in claim 17 a <clothing, wherein the sputum carrier comprises at least one material selected from the group consisting of poly vinegar, polyoxalic acid, polylactic acid, polycaprolactone, acrylate, cellulose, polyethyl alcohol, polyethylene The sputum net, the dextran, the hyaluronic acid, the fiber sputum (called collagen, and the gelatin. 19. The implantable delivery device of claim 17 wherein the state of the carrier is selected from the following Groups, including solid, liquid, and gelatinous The pharmaceutical system is selected from the group consisting of solid, liquid, and gel. The implantable delivery device of claim 15 further comprising at least one enhancer enhancer It is selected from the group consisting of an enzyme, a co-administration agent (a co_drug), and a substance of the drug 42 13,23667. 21. The plant as claimed in claim 15 An in-line delivery device further comprising at least one enhancing agent comprising a protein. The implantable delivery device of claim 21, wherein the protein comprises albumin. The implantable delivery device of claim 15 further comprising a perfusion enhancer that helps to enhance penetration of the agent or the prophylactic agent into a target tissue. 24. The implantable delivery device of claim 23, wherein the reinforcing infusion comprises at least one compound selected from the group consisting of an enzyme, a former The implantable delivery device of claim 24, wherein the enzyme comprises at least one enzyme selected from the group consisting of collagenase and a matrix metalloproteinase. 26. The implantable delivery device of claim 1, further comprising a barrier layer covering the drug release raft. 2 7. As described in claim 26 An implantable delivery device, wherein the barrier layer comprises a material selected from the group consisting of gelatin, hyaluronic acid, methyl vesin, polyoxalic acid, and polylactic acid. The implantable delivery device of claim 6, wherein the device is sufficiently flexible to allow it to pass through a slit that is smaller than the maximum circumference of the device and is sealingly connected to the irregularity. The surface of the tissue. The implantable delivery device of claim 1, wherein the attachment mechanism comprises a sufficient amount of adhesive to adhere the sealing base to a target tissue. The implantable delivery device of claim 1, wherein the attachment mechanism comprises a suture anchor for operatively attaching at least one suture to the surrounding tissue. The implantable delivery device of claim 1, wherein the band member is annularly encased in the device and a portion of an organ, wherein the device is attached to the organ. 32. The implantable delivery device of claim 1, wherein the element comprises a sclera buckle β 33. The implantable transfer device of claim 1 wherein The device has the shape of a (four) ribbon element aligned to a solid (4) device to a surface 44 13,23667. 3. The implantable delivery device of claim 14, wherein the medicament is in a sealed state. 3. The implantable delivery device of claim 14, wherein the medicament is incorporated into a fat microparticle or microsphere. 3. The implantable delivery device of claim 14, wherein the medicament is in an inactive state. 37. The implantable delivery device of claim 17, wherein the carrier comprises at least one substance selected from the group consisting of a polymer, a copolymer, and a tissue. 38. The implantable delivery device of claim 17, wherein the carrier acts with the agent to control its rate of release. 39. The implantable delivery device of claim 14, further comprising a substance that controls release of the medicament. 40. The implantable delivery device of claim 1, wherein the reservoir comprises at least two chambers. 45 1323667 41. The implantable delivery device of claim 40, wherein at least two chambers are separated by a wall, the wall simultaneously separating the release into respectively corresponding to the at least two chambers At least two outlets of the chamber, at least a portion of the wall system can be sealed to the tissue when the dense seat is attached to the tissue, wherein each of the at least two chambers contains a plurality of medicaments and the other 42. The implantable device of claim 29, wherein the adhesive comprises at least one selected from the group consisting of fibrin, hydrogel, and hyaluronic acid. Salt (hyalur〇nate). 43. The implantable delivery device of claim 29, wherein the adhesive comprises an acrylate. 44. The implantable delivery device of claim 14, comprising a second medicament or a prophylactic agent, wherein the second medicament is delivered to the first medicament or the preventive medicament The target organization is transferred to the target organization. 45. The implantable delivery device of claim 14, which comprises an osmotic agent. 46. The implantable delivery device of claim 26, wherein the barrier layer is biodegradable. In the middle of the hydration, the portion of the hydration is further included in the sump. The splicing device of the invention of claim 29 is further included in the adhesive. a peelable layer on the agent. 47