Shikha P. Barman, Integral BioSystems, LLC10.07.15
Age-related macular degeneration (AMD) is a leading cause of blindness among the elderly. In the U.S., more than 8 million people suffer from this disease; this number is projected to increase many-fold by 2020.1 AMD can be of the dry and wet form and is a consequence of excessive aging associated with alterations in the retinal pigment epithelium (RPE). In wet AMD, choroidal neovascularization (CNV) occurs with fluid build-up in the sub-retinal space. The dry form of AMD is associated with drusen formation and RPE atrophy.2 Diabetic Retinopathy often leads to neovascularization and macular edema and is the third leading cause of blindness in the US; macular edema is the swelling of the macula and occurs in approximately 10% of all diabetics.3
Endophthalmitis is another cause of blindness in the world. It is characterized by infection of the interior ocular space by micro-organisms, due to post-operative infections. These include gram positive bacteria such as s. aureus and streptococci.4, 5
Diseases that occur in the back-of-eye that potentially, can result in serious visual impairment and blindness include age-related macular degeneration (AMD), macular edema, uveitis, choroidal neovascularization (CNV), retinitis pigmentosa, cytomegalovirus retinitis (CMV), etc.
The clinical and experimental drugs for the posterior segment treatments include both small and large molecules (such as siRNA, antibodies, growth factors, DNA), but delivering these molecules to the target sites is problematic. When administered topically, drug concentrations in the retina and choroid are many-fold lower than the tear fluid. Drug delivery to the posterior segment of the eye is most efficiently achieved by local, ocular routes of administration, which includes intravitreal, subretinal, suprachoroidal and periocular injections.6, 7
Intravitreal injections and implants deliver drugs effectively to the retina and the choroid. For example, intravitreal injections of therapeutics are routinely used in the treatment of wet AMD (Lucentis, Macugen, Vitravene), macular inflammation (Triesence), etc.8 This mode of administration while efficacious is highly invasive; considerable risks exist to developing infections (endophthalmitis) and retinal detachment with repeated injections over a person’s lifetime. However, high concentrations of drug can be achieved with intravitreal injections with sustained presence due to the relative lack of fluid flow in the vitreous humor.
Triamcinolone acetonide is the most commonly used steroid treatment for AMD treatment and vitreoretinal disorders. To achieve a dose for prolonged duration and to minimize repeated injections, triamcinolone acetonide suspension must be injected at high concentrations. Due to the presence of high concentrations of drug in the vitreous, lateral drug diffusion into the aqueous humor leads to significant adverse events such as cataract formation, glaucoma induced by increased intra-ocular pressure and blurred vision due to blocking of the visual field.
In contrast, the periocular route is less invasive than intravitreal administration and it provides higher retinal and vitreal drug concentrations than eye-drops. Periocular delivery of therapies can be accomplished through injections or implantation of the drug to the sub-conjunctival, sub-tenon, or parabulbar space. However, the drug must penetrate through several barriers: sclera, choroid and RPE. Relatively high permeability of sclera to macromolecules has resulted in renewed interest to this route of drug administration. Macromolecules such as anti-angiogenic antibodies, oligonucleotides, trans-gene expression products and growth factors are proving to have immense therapeutic value in the treatment of back-of-the-eye diseases. Scleral permeability is dependent upon the molecular radius as opposed to the innate lipophilicity of the drug; macromolecules up to 70,000 Da can readily penetrate the sclera.9, 10
However, one technical challenge with delivery via the periocular route is the enhanced clearance of drugs due to fluid flow in these vascularized tissues. When injected into periocular tissues, both small molecules (ophthalmic steroids) and macromolecules (proteins) have determined to be rapidly eliminated into conjunctival lymphatics and episcleral veins. However, on a positive note, long term transscleral delivery can be obtained by utilizing drug-containing microspheres; retention of microspheres has been demonstrated at the site for approximately 2 months.11
Sustained Release Products: Approved and In-Testing
Ocular implants have been the platform for the sustained release of therapeutics, either from biodegradable or non-degradable matrices. Non-biodegradable implants can provide more accurate control of drug release and longer release periods than the biodegradable polymers do, but require surgical implant removal with its associated risks (1).
The polymers commonly used for non-biodegradable implants are polyvinyl alcohol (PVA), ethylene vinyl acetate (EVA) and silicone, whereas for biodegradable implants, a variety of polymers can be used (PLA, PGA, PLGA, polycaprolactones, polyanhydrides and polyorthoesters). The erosion rate and spontaneous degradation of these polymers can be modulated to allow for the desired intraocular kinetics of drug release to take place. Moreover, biodegradable polymers can be used to form solid or injectable viscous/semi-solid implants in various shapes, which do not require their removal.
Vitrasert and Retisert (Bausch & Lomb, USA) are clinically used non-biodegradable implants. Vitrasert is the first implantable ganciclovir delivery device, approved by the FDA in 1996 for the treatment of cytomegalovirus (CMV) retinitis for up to 8 months and is the primary line of care of patients with CMV. However, occasional endophthalmitis and an increased rate of retinal detachments have been associated with this implant. Retisert contains fluocinolone acetonide; this product is utilized in the treatment of chronic non-infectious posterior uveitis. However, Retisert has been shown to increase intraocular pressure and cataract progression. Both of these indications could benefit from a re-formulation of the drug into precise micro-delivered matrices delivered into periocular space. Illuvien (Phase III trials) is a rod-shaped implant containing fluocinolone acetonide. The product releases the drug for up to three years. Another product, I-vation™ (releasing triamcinolone acetonide for 2 years) is in Phase I clinical trials to treat diabetic edema.
Recently, a biodegradable intravitreal implant, Ozurdex has been approved for the treatment of macular edema secondary to retinal vein occlusion and for non-infectious uveitis. This implant is comprised of PLGA and releases incorporated dexamethasone over 4-6 weeks.
EySite-InjecT: Injectable, Biodegradable, Precisely Modulated, Nano-Engineered Drug Delivery
EySite-InjecT encapsulates have been developed (by Integral BioSystems, LLC) to be a platform drug delivery system for all therapies that can benefit from sustained release treatment.
The delivery system has been engineered specifically for injection into target ocular tissues and spaces, including suprachoroidal, intravitreal, subconjunctival sites. The delivery system optimized for the specific drug molecule has certain cassette-like features that include proprietary compositions, process engineering methods, surface treatments and vehicle traits that allow injection through a 31G needle and long-term, precise and predictable release of drug in the ocular space. The delivery system utilizes only excipients that are present in approved parenteral injectable drug products. The process has been successfully enabled for the fabrication of EySite-InjecT encapsulates for water-soluble, small molecular weight and higher molecular weight peptides, oligonucleotides, DNA, proteins, ophthalmic steroids, antifungals, antibacterials and NSAIDs. Critical process parameters for larger scale production of EySite-InjecT have been developed for an ophthalmic steroidal drug and a water-soluble peptide.
High Loading: The process to fabricate EySite-Inject encapsulates has been optimized to have high drug content within the matrices. A maximum volume of 50µL can be injected into the vitreous humor or suprachoroidal space safely. Thus, the entire dose needs to be contained in that volume. This requires the drug to be potent, and the delivery system to be injected at a high concentration. For EySite encapsulates containing an ophthalmic steroid can be injected at a concentration of 400-500 mg matrix/mL, with 90% drug encapsulation achieved per gram of matrix, allowing release of 1-6 microgram steroid per day, for 180 days in-vitro (USP4 in-vitro release model).
Sustained Release, Predictable Release: One of the issues of sustained release from standard PLGA microspheres is erratic release of the drug in-vivo due to instant aggregation and eventual coagulation post-injection and the failure to maintain shape. Unpredictable release can result in sub-therapeutic drug levels, or dose dumping. EySite-InjecT encapsulates are designed to be non-aggregating and maintains shape due to a proprietary treatment prior to injection.
Injectability, Dispersability, Biodegradability: Achieving a target release of an ophthalmic steroid for 6 months in-vivo, relatively large PLGA microspheres or implants are required—neither mode of administration is injectable through 31G needles. EySite InjecT encapsulates are injectable through a 31G needle in any ocular space (suprachoroidal, intravitreal, periocular). Steroid-containing EySite-InjecT encapsulates have been engineered to bioabsorb in generally an equivalent time frame for 100% drug release.
Figure 2 demonstrates the feasibility of long-term release of an ophthalmic steroid from biodegradable EySite-InjecT formulations, tested in vitro at 37ºC, pH 7.4. The release profiles demonstrate modulation of release rates to meet target specifications.
Figure 3 demonstrates release modulation of a highly water-soluble peptide from EySite-InjecT encapsulates, tested in-vitro, at 37ºC, pH 7.4. The data demonstrates that the internal microstructure of encapsulates influence the release rate of a drug.
Encapsulates with a honey-combed internal structure.
While this can be utilized as a handle to control release, achievement of reproducible internal structure is no small feat. The proprietary process to fabricate EySite-Inject encapsulates produces reproducible microstructure.
Studies are underway to further test and characterize these products.
The Big Picture
A balanced, realistic and strategic approach must be adopted by clinicians to achieve therapeutic concentrations of drug at the target site, considerations that must depend upon the acuteness of the disease and the need for repeated injections.
For example, an acute and severe infection in the posterior chamber may require treatment via direct injection into the vitreous to enable efficient eradication of the infection by achieving high drug concentrations at the target site. Acute inflammatory reactions should likely be treated in a similar manner, to enable a rapid and efficient effect. However, therapy of chronic conditions like diabetic edema and AMD should be addressed via injections to periocular tissue spaces such as the choroid, sub-tenon, parabulbar, sclera, etc. and a strategy for disease management developed. For example, an intra-vitreous injection of the drug every six months may be considered minimally invasive and feasible, if such sustained release options exist and have been validated. Likewise, treatment of retinoblastoma should likely be addressed by direct intra-vitreal injection, as opposed to risking rapid drug clearance rates seen in barrier-compromised cancer patients.
On the other hand, continuous presence of an anti-inflammatory drug at high concentrations in the vitreous can induce glaucoma and cataract formation; treatment of inflammation for a chronic condition is best approached via suprachoroidal delivery. Thus, key considerations in developing an appropriate therapy for a posterior eye condition are: (a) the disease being treated (acute, or chronic) and (b) drug properties. Highly water-soluble small molecule therapeutics such as peptides are extremely difficult to encapsulate with high loading in biodegradable polymer matrices, due to process challenges. Additionally, a highly water soluble compound has limited extraction into lipophilic ocular tissues; thus, clearance rates are typically much higher for these molecules than lipophilic molecules. A highly water-soluble small molecule drug for a retinal disorder may be best suited for intra-vitreal injections to achieve sustained levels at the target site. In contrast, highly lipophilic molecules such as Triamcinolone Acetonide and Dexamethasone can be successfully delivered to the suprachoroidal space to treat inflammation in the vitreous. Mechanical microneedle-based devices can be utilized to deliver to the suprachoroidal space.
In envisioning drug delivery systems, matching the biodegradability of the matrix to the drug release profile is relevant; the matrix should be cleared from the site to ensure that components from the matrix do not cause adverse effects of local toxicity. The ideal target profile of an injectable, sustained release product for the treatment of posterior chamber diseases is:
(a) injectable via a 27-31G needle
(b) precise, predictable drug release and
(c) bioabsorbable and biocompatible.
References
Endophthalmitis is another cause of blindness in the world. It is characterized by infection of the interior ocular space by micro-organisms, due to post-operative infections. These include gram positive bacteria such as s. aureus and streptococci.4, 5
Diseases that occur in the back-of-eye that potentially, can result in serious visual impairment and blindness include age-related macular degeneration (AMD), macular edema, uveitis, choroidal neovascularization (CNV), retinitis pigmentosa, cytomegalovirus retinitis (CMV), etc.
The clinical and experimental drugs for the posterior segment treatments include both small and large molecules (such as siRNA, antibodies, growth factors, DNA), but delivering these molecules to the target sites is problematic. When administered topically, drug concentrations in the retina and choroid are many-fold lower than the tear fluid. Drug delivery to the posterior segment of the eye is most efficiently achieved by local, ocular routes of administration, which includes intravitreal, subretinal, suprachoroidal and periocular injections.6, 7
Intravitreal injections and implants deliver drugs effectively to the retina and the choroid. For example, intravitreal injections of therapeutics are routinely used in the treatment of wet AMD (Lucentis, Macugen, Vitravene), macular inflammation (Triesence), etc.8 This mode of administration while efficacious is highly invasive; considerable risks exist to developing infections (endophthalmitis) and retinal detachment with repeated injections over a person’s lifetime. However, high concentrations of drug can be achieved with intravitreal injections with sustained presence due to the relative lack of fluid flow in the vitreous humor.
Triamcinolone acetonide is the most commonly used steroid treatment for AMD treatment and vitreoretinal disorders. To achieve a dose for prolonged duration and to minimize repeated injections, triamcinolone acetonide suspension must be injected at high concentrations. Due to the presence of high concentrations of drug in the vitreous, lateral drug diffusion into the aqueous humor leads to significant adverse events such as cataract formation, glaucoma induced by increased intra-ocular pressure and blurred vision due to blocking of the visual field.
In contrast, the periocular route is less invasive than intravitreal administration and it provides higher retinal and vitreal drug concentrations than eye-drops. Periocular delivery of therapies can be accomplished through injections or implantation of the drug to the sub-conjunctival, sub-tenon, or parabulbar space. However, the drug must penetrate through several barriers: sclera, choroid and RPE. Relatively high permeability of sclera to macromolecules has resulted in renewed interest to this route of drug administration. Macromolecules such as anti-angiogenic antibodies, oligonucleotides, trans-gene expression products and growth factors are proving to have immense therapeutic value in the treatment of back-of-the-eye diseases. Scleral permeability is dependent upon the molecular radius as opposed to the innate lipophilicity of the drug; macromolecules up to 70,000 Da can readily penetrate the sclera.9, 10
However, one technical challenge with delivery via the periocular route is the enhanced clearance of drugs due to fluid flow in these vascularized tissues. When injected into periocular tissues, both small molecules (ophthalmic steroids) and macromolecules (proteins) have determined to be rapidly eliminated into conjunctival lymphatics and episcleral veins. However, on a positive note, long term transscleral delivery can be obtained by utilizing drug-containing microspheres; retention of microspheres has been demonstrated at the site for approximately 2 months.11
Sustained Release Products: Approved and In-Testing
Ocular implants have been the platform for the sustained release of therapeutics, either from biodegradable or non-degradable matrices. Non-biodegradable implants can provide more accurate control of drug release and longer release periods than the biodegradable polymers do, but require surgical implant removal with its associated risks (1).
The polymers commonly used for non-biodegradable implants are polyvinyl alcohol (PVA), ethylene vinyl acetate (EVA) and silicone, whereas for biodegradable implants, a variety of polymers can be used (PLA, PGA, PLGA, polycaprolactones, polyanhydrides and polyorthoesters). The erosion rate and spontaneous degradation of these polymers can be modulated to allow for the desired intraocular kinetics of drug release to take place. Moreover, biodegradable polymers can be used to form solid or injectable viscous/semi-solid implants in various shapes, which do not require their removal.
Vitrasert and Retisert (Bausch & Lomb, USA) are clinically used non-biodegradable implants. Vitrasert is the first implantable ganciclovir delivery device, approved by the FDA in 1996 for the treatment of cytomegalovirus (CMV) retinitis for up to 8 months and is the primary line of care of patients with CMV. However, occasional endophthalmitis and an increased rate of retinal detachments have been associated with this implant. Retisert contains fluocinolone acetonide; this product is utilized in the treatment of chronic non-infectious posterior uveitis. However, Retisert has been shown to increase intraocular pressure and cataract progression. Both of these indications could benefit from a re-formulation of the drug into precise micro-delivered matrices delivered into periocular space. Illuvien (Phase III trials) is a rod-shaped implant containing fluocinolone acetonide. The product releases the drug for up to three years. Another product, I-vation™ (releasing triamcinolone acetonide for 2 years) is in Phase I clinical trials to treat diabetic edema.
Recently, a biodegradable intravitreal implant, Ozurdex has been approved for the treatment of macular edema secondary to retinal vein occlusion and for non-infectious uveitis. This implant is comprised of PLGA and releases incorporated dexamethasone over 4-6 weeks.
EySite-InjecT: Injectable, Biodegradable, Precisely Modulated, Nano-Engineered Drug Delivery
EySite-InjecT encapsulates have been developed (by Integral BioSystems, LLC) to be a platform drug delivery system for all therapies that can benefit from sustained release treatment.
The delivery system has been engineered specifically for injection into target ocular tissues and spaces, including suprachoroidal, intravitreal, subconjunctival sites. The delivery system optimized for the specific drug molecule has certain cassette-like features that include proprietary compositions, process engineering methods, surface treatments and vehicle traits that allow injection through a 31G needle and long-term, precise and predictable release of drug in the ocular space. The delivery system utilizes only excipients that are present in approved parenteral injectable drug products. The process has been successfully enabled for the fabrication of EySite-InjecT encapsulates for water-soluble, small molecular weight and higher molecular weight peptides, oligonucleotides, DNA, proteins, ophthalmic steroids, antifungals, antibacterials and NSAIDs. Critical process parameters for larger scale production of EySite-InjecT have been developed for an ophthalmic steroidal drug and a water-soluble peptide.
High Loading: The process to fabricate EySite-Inject encapsulates has been optimized to have high drug content within the matrices. A maximum volume of 50µL can be injected into the vitreous humor or suprachoroidal space safely. Thus, the entire dose needs to be contained in that volume. This requires the drug to be potent, and the delivery system to be injected at a high concentration. For EySite encapsulates containing an ophthalmic steroid can be injected at a concentration of 400-500 mg matrix/mL, with 90% drug encapsulation achieved per gram of matrix, allowing release of 1-6 microgram steroid per day, for 180 days in-vitro (USP4 in-vitro release model).
Sustained Release, Predictable Release: One of the issues of sustained release from standard PLGA microspheres is erratic release of the drug in-vivo due to instant aggregation and eventual coagulation post-injection and the failure to maintain shape. Unpredictable release can result in sub-therapeutic drug levels, or dose dumping. EySite-InjecT encapsulates are designed to be non-aggregating and maintains shape due to a proprietary treatment prior to injection.
Injectability, Dispersability, Biodegradability: Achieving a target release of an ophthalmic steroid for 6 months in-vivo, relatively large PLGA microspheres or implants are required—neither mode of administration is injectable through 31G needles. EySite InjecT encapsulates are injectable through a 31G needle in any ocular space (suprachoroidal, intravitreal, periocular). Steroid-containing EySite-InjecT encapsulates have been engineered to bioabsorb in generally an equivalent time frame for 100% drug release.
Figure 2 demonstrates the feasibility of long-term release of an ophthalmic steroid from biodegradable EySite-InjecT formulations, tested in vitro at 37ºC, pH 7.4. The release profiles demonstrate modulation of release rates to meet target specifications.
Figure 3 demonstrates release modulation of a highly water-soluble peptide from EySite-InjecT encapsulates, tested in-vitro, at 37ºC, pH 7.4. The data demonstrates that the internal microstructure of encapsulates influence the release rate of a drug.
Encapsulates with a honey-combed internal structure.
While this can be utilized as a handle to control release, achievement of reproducible internal structure is no small feat. The proprietary process to fabricate EySite-Inject encapsulates produces reproducible microstructure.
Studies are underway to further test and characterize these products.
The Big Picture
A balanced, realistic and strategic approach must be adopted by clinicians to achieve therapeutic concentrations of drug at the target site, considerations that must depend upon the acuteness of the disease and the need for repeated injections.
For example, an acute and severe infection in the posterior chamber may require treatment via direct injection into the vitreous to enable efficient eradication of the infection by achieving high drug concentrations at the target site. Acute inflammatory reactions should likely be treated in a similar manner, to enable a rapid and efficient effect. However, therapy of chronic conditions like diabetic edema and AMD should be addressed via injections to periocular tissue spaces such as the choroid, sub-tenon, parabulbar, sclera, etc. and a strategy for disease management developed. For example, an intra-vitreous injection of the drug every six months may be considered minimally invasive and feasible, if such sustained release options exist and have been validated. Likewise, treatment of retinoblastoma should likely be addressed by direct intra-vitreal injection, as opposed to risking rapid drug clearance rates seen in barrier-compromised cancer patients.
On the other hand, continuous presence of an anti-inflammatory drug at high concentrations in the vitreous can induce glaucoma and cataract formation; treatment of inflammation for a chronic condition is best approached via suprachoroidal delivery. Thus, key considerations in developing an appropriate therapy for a posterior eye condition are: (a) the disease being treated (acute, or chronic) and (b) drug properties. Highly water-soluble small molecule therapeutics such as peptides are extremely difficult to encapsulate with high loading in biodegradable polymer matrices, due to process challenges. Additionally, a highly water soluble compound has limited extraction into lipophilic ocular tissues; thus, clearance rates are typically much higher for these molecules than lipophilic molecules. A highly water-soluble small molecule drug for a retinal disorder may be best suited for intra-vitreal injections to achieve sustained levels at the target site. In contrast, highly lipophilic molecules such as Triamcinolone Acetonide and Dexamethasone can be successfully delivered to the suprachoroidal space to treat inflammation in the vitreous. Mechanical microneedle-based devices can be utilized to deliver to the suprachoroidal space.
In envisioning drug delivery systems, matching the biodegradability of the matrix to the drug release profile is relevant; the matrix should be cleared from the site to ensure that components from the matrix do not cause adverse effects of local toxicity. The ideal target profile of an injectable, sustained release product for the treatment of posterior chamber diseases is:
(a) injectable via a 27-31G needle
(b) precise, predictable drug release and
(c) bioabsorbable and biocompatible.
References
- Jager, R.D., Mieler, W.F., Miller. J.W. 2008. “Age-related macular degeneration”. N. Engl. J. Med. 358, 2606-2617.
- Seddon, J.M. 2001. “Epidemiology of age-related macular degeneration, in A.P. Schachat, S.J. Ryan, Retina, 3rd ed., Mosby, St. Louis, MO, 2001, pp. 1039-1050.
- Klein, R., Klein, B.E.K, Klein, S.E., Moss, et al., “The Wisconsin Epidemiologic Study of Diabetic Retinopathy: Diabetic Macular Edema”, Ophthalmology, 91 (1984) 1464-1474.
- Wilson, F.M., “Causes and Prevention of Endophthalmitis”, Int. Ophthalmol. Clin. 27 (1987) 67-73.
- Mandelbaum, S., “Post-operative Endophthalmitis”. Int. Ophthalmol. Clin. 27 (1987) 95-106.
- Geroski, D.H., Edelhauser, H.F. “Transscleral Drug Delivery for Posterior Segment Disease”. Adv. Drug Deliv. Rev. 52(1)(2001) 37-48.
- Ambati, J., Adamis, A.P., “Transscleral drug delivery to the retina and choroid”, Prog. Retin. Eye Res. 21(2)(2002) 145-151.
- Raghava, S., Hammond, M., Kompella, U.B., “Periocular Routes for Retinal Drug Delivery”. Expert Opin. Drug Deliv. 1, 99-114.
- Amrite, A.C., Ayalasomayajula, S.P., Cheruvu, S.P., Kompella, U.B., “Single Periocular Injections of Celecoxib-PLGA microparticles inhibits diabetes-induced elevations in retinal PGE2, VEGF and vascular leakage”, Invest. Ophthalmol. Vis. Sci. 47, 1149-1160.