Luxturna - summary of medicine characteristics

1. NAME OF THE MEDICINAL PRODUCT

Luxturna 5 × 1012 vector genomes/mL concentrate and solvent for solution for injection

2. QUALITATIVE AND QUANTITATIVE COMPOSITION2.1 General description

Voretigene neparvovec is a gene transfer vector that employs an adeno-associated viral vector serotype 2 (AAV2) capsid as a delivery vehicle for the human retinal pigment epithelium 65 kDa protein (hRPE65) cDNA to the retina. Voretigene neparvovec is derived from naturally occurring AAV using recombinant DNA techniques.

2.2 Qualitative and quantitative composition

Each mL of concentrate contains 5 × 1012 vector genomes (vg).

Each single-dose 2 mL vial of Luxturna contains 0.5 extractable mL of concentrate which requires a 1:10 dilution prior to administration, see section 6.6.

After dilution each dose of Luxturna contains 1.5 × 1011 vg in a deliverable volume of 0.3 mL.

For the full list of excipients, see section 6.1.

3. PHARMACEUTICAL FORM

Concentrate and solvent for solution for injection.

Following thaw from their frozen state, both the concentrate and the solvent are clear, colourless liquids with a pH of 7.3.

4. CLINICAL PARTICULARS4.1 Therapeutic indications

Luxturna is indicated for the treatment of adult and paediatric patients with vision loss due to inherited retinal dystrophy caused by confirmed biallelic RPE65 mutations and who have sufficient viable retinal cells.

4.2 Posology and method of administration

Treatment should be initiated and administered by a retinal surgeon experienced in performing macular surgery.

Posology

Patients will receive a single dose of 1.5 × 1011 vg voretigene neparvovec in each eye. Each dose will be delivered into the subretinal space in a total volume of 0.3 mL. The individual administration procedure to each eye is performed on separate days within a close interval, but no fewer than 6 days apart.

Immunomodulatory regimen

Prior to initiation of the immunomodulatory regimen and prior to administration of Luxturna, the patient must be checked for symptoms of active infectious disease of any nature, and in case of such infection the start of treatment must be postponed until after the patient has recovered.

Starting 3 days prior to the administration of Luxturna to the first eye, it is recommended that an immunomodulatory regimen is initiated following the schedule below (Table 1). Initiation of the immunomodulatory regimen for the second eye should follow the same schedule and supersede completion of the immunomodulatory regimen of the first eye.

Table 1 Pre- and post-operative immunomodulatory regimen for each eye

Special populations

Elderly

The safety and efficacy of voretigene neparvovec in patients >65 years old have not been established.

However, no adjustment in dosage is necessary for elderly patients.

Hepatic and renal impairment

The safety and efficacy of voretigene neparvovec have not been established in patients with hepatic or renal impairment. No dose adjustment is required in these patients (see section 5.2).

Paediatric population

The safety and efficacy of voretigene neparvovec in children aged up to 4 years have not been established. No data are available. No adjustment in dosage is necessary for paediatric patients.

Method of administration

Subretinal use.

Luxturna is a sterile concentrate solution for subretinal injection that requires thawing and dilution prior to administration (see section 6.6).

This medicinal product must not be administered by intravitreal injection.

Luxturna is a single-use vial for a single administration in one eye only. The product is administered as a subretinal injection after vitrectomy in each eye. It should not be administered in the immediate vicinity of the fovea to maintain foveal integrity (see section 4.4).

The administration of voretigene neparvovec should be carried out in the surgical suite under controlled aseptic conditions. Adequate anaesthesia should be given to the patient prior to the procedure. The pupil of the eye to be injected must be dilated and a broad-spectrum microbicide should be topically administered prior to the surgery according to standard medical practice.

Precaution to be taken before manipulating or administering the medicinal product

This medicinal product contains genetically modified organisms. Personal protective equipment (to include laboratory coat, safety glasses and gloves) should be worn while preparing or administering voretigene neparvovec (see section 6.6).

For instructions for preparation, accidental exposure to and disposal of Luxturna, see section 6.6.

Administration

Follow the steps below to administer voretigene neparvovec to patients:

• • Diluted Luxturna should be inspected visually prior to administration. If particulates,

cloudiness, or discoloration are visible, the medicinal product must not be used.

• • Connect the syringe containing the diluted product to the tubing and microcannula. The product

is slowly injected through the tubing and microcannula to eliminate any air bubbles in the system.

• • The volume of product available for injection is confirmed in the syringe, by aligning the

plunger tip with the line that marks 0.3 mL.

• • After vitrectomy is completed, Luxturna is administered by subretinal injection using a

subretinal injection cannula introduced via pars plana (Figure 1A).

• • Under direct visualisation, the tip of the subretinal injection cannula is placed in contact with

the retinal surface. The recommended site of injection should be located along the superior vascular arcade, at least 2 mm distal to the centre of the fovea (Figure 1B). A small amount of the product is slowly injected until an initial subretinal bleb is observed, and then the remaining volume is slowly injected until the total 0.3 mL is delivered.

Figure 1A Subretinal injection cannula introduced via pars plana

Figure 1B Tip of the subretinal injection cannula placed within the recommended site of injection (surgeon’s view)

• • At the completion of the injection, the subretinal injection cannula is removed from the eye.
• • After injection, any unused product must be discarded. The back-up syringe may not be

retained. Refer to local biosafety guidelines applicable for disposal of the product.

• • Fluid-air exchange is performed, carefully avoiding fluid drainage near the retinotomy created

for the subretinal injection.

• • Supine head positioning is initiated immediately in the post-operative period and upon

discharge should be maintained by the patient for 24 hours.

4.3 Contraindications

Hypersensitivity to the active substance(s) or to any of the excipients listed in section 6.1.

Ocular or periocular infection.

Active intraocular inflammation.

4.4 Special warnings and precautions for use

Proper aseptic techniques should always be used for the preparation and administration of Luxturna.

The following adverse reactions have been observed with the administration procedure:

• • Eye inflammation (including endophthalmitis), retinal tear and retinal detachment. Patients

should be instructed to report any symptoms suggestive of endophthalmitis or retinal detachment without delay and should be managed appropriately.

• • Retinal disorder (foveal thinning, loss of foveal function), macular hole, maculopathy (epiretinal

membrane, macular pucker) and eye disorder (foveal dehiscence).

• • Increase in intraocular pressure. Intraocular pressure should be monitored prior to and following

administration of the medicinal product and managed appropriately. Patients should be instructed to avoid air travel or other travel to high elevations until the air bubble formed as a result of administration of Luxturna has completely dissipated from the eye. A time period of up to one week or more following injection may be required before dissipation of the air bubble; this should be verified on ophthalmic examination. A rapid increase in altitude while the air bubble is still present can cause a rise in eye pressure and irreversible vision loss.

Temporary visual disturbances, such as blurred vision and photophobia, may occur during the weeks that follow the treatment. Patients should be instructed to contact their healthcare professional if visual disturbances persist. Patients should avoid swimming because of an increased risk of infection in the eye. Patients should avoid strenuous physical activity because of an increased risk of injury to the eye. Patients may resume swimming and strenuous activity, after a minimum of one to two weeks, on the advice of their healthcare professional.

Shedding

Transient and low-level vector shedding may occur in patient tears (see section 5.2). Patients/caregivers should be advised to handle waste material generated from dressings, tears and nasal secretion appropriately, which may include storage of waste material in sealed bags prior to disposal. These handling precautions should be followed for 14 days after administration of voretigene neparvovec. It is recommended that patients/caregivers wear gloves for dressing changes and waste disposal, especially in case of underlying pregnancy, breast-feeding and immunodeficiency of caregivers.

Patients treated with Luxturna should not donate blood, organs, tissues and cells for transplantation.

Immunogenicity

To reduce the potential for immunogenicity patients should receive systemic corticosteroids before and after the subretinal injection of voretigene neparvovec to each eye (see section 4.2). The corticosteroids may decrease the potential immune reaction to either vector capsid (adeno-associated virus serotype 2 [AAV2] vector) or transgene product (retinal pigment epithelial 65 kDa protein [RPE65]).

Traceability

In order to improve the traceability of biological medicinal products, the name and the batch number of the administered product should be clearly recorded.

Sodium content

This medicinal product contains less than 1 mmol sodium (23 mg) per dose, i.e. essentially ‘sodium-free’.

4.5 Interaction with other medicinal products and other forms of interaction

There are no known clinically significant interactions. No interaction studies have been performed.

4.6 Fertility, pregnancy and lactation

Based on non-clinical studies and clinical data from trials of AAV2 vectors, and considering the subretinal route of administration of Luxturna, inadvertent germ-line transmission with AAV vectors is highly unlikely.

Pregnancy

There are no or limited amount of data (less than 300 pregnancy outcomes) from the use of voretigene neparvovec in pregnant women. Animal studies do not indicate direct or indirect harmful effects with respect to reproductive toxicity (see section 5.3).

As a precautionary measure, it is preferable to avoid the use of voretigene neparvovec during pregnancy.

Breast-feeding

Luxturna has not been studied in breast-feeding women. It is unknown whether voretigene neparvovec is excreted in human milk. A risk to the newborns/infants cannot be excluded. A decision must be made whether to discontinue breast-feeding or to discontinue/abstain from voretigene neparvovec therapy taking into account the benefit of breast-feeding for the child and the benefit of therapy for the woman.

Fertility

No clinical data on the effect of the medicinal product on fertility are available. Effects on male and female fertility have not been evaluated in animal studies.

4.7 Effects on ability to drive and use machines

Voretigene neparvovec has minor influence on the ability to drive and use machines. Patients may experience temporary visual disturbances after receiving subretinal injection of Luxturna. Patients should not drive or use heavy machines until visual function has recovered sufficiently, as advised by their ophthalmologist.

4.8 Undesirable effects

Summary of the safety profile

There were three non-serious adverse reactions of retinal deposits in three of 41 (7%) subjects that were considered to be related to voretigene neparvovec. All three of these events were a transient appearance of asymptomatic subretinal precipitates inferior to the retinal injection site, 1–6 days after injection and resolved without sequelae.

Serious adverse reactions related to the administration procedure were reported in three subjects during the clinical programme. One of 41 (2%) subjects reported a serious event of intraocular pressure increased (secondary to administration of depo-steroid) that was associated with treatment for endophthalmitis related to the administration procedure and resulted in optic atrophy, and one of 41 (2%) subjects reported a serious event of retinal disorder (loss of foveal function) that was assessed as related to the administration procedure. One of 41 (2%) subjects reported a serious event of retinal detachment that was assessed as related to the administration procedure.

The most common adverse reactions (incidence >5%) related to the administration procedure were conjunctival hyperaemia, cataract, increased intraocular pressure, retinal tear, dellen, macular hole, subretinal deposits, eye inflammation, eye irritation, eye pain and maculopathy (wrinkling on the surface of the macula).

Tabulated list of adverse reactions

The adverse reactions are listed by system organ class and frequency using the following convention: very common (>1/10), common >1/100 to <1/10), uncommon (>1/1,000 to <1/100), rare (>1/10,000 to <1/1,000), very rare (<1/10,000), not known (cannot be estimated from the available data).

Table 2 Adverse reactions related to voretigene neparvovec

Table 3 Adverse reactions related to administration procedure

*This adverse reaction has been reported during post-marketing experience.

Includes retinal degeneration, retinal depigmentation and injection site atrophy

Description of select adverse reactions

Chorioretinal atrophy

Chorioretinal atrophy was reported as progressive in some patients. Events were temporally related to treatment and occurred in the estimated treated area of the bleb site. In reported post-injection retinal atrophies, there was no evidence of foveal involvement or significant visual functional impairment reported in patients.

Reporting of suspected adverse reactions

Reporting suspected adverse reactions after authorisation of the medicinal product is important. It allows continued monitoring of the benefit/risk balance of the medicinal product. Healthcare professionals are asked to report any suspected adverse reactions via the national reporting system listed in

4.9 Overdose

There is no clinical experience with overdose of voretigene neparvovec. Symptomatic and supportive treatment, as deemed necessary by the treating physician, is advised in case of overdose.

5. PHARMACOLOGICAL PROPERTIES5.1 Pharmacodynamic properties

Pharmacotherapeutic group: Ophthalmologicals, other ophthalmologicals, ATC code: S01XA27.

Mechanism of action

The retinal pigment epithelium-specific 65 kilodalton protein (RPE65) is located in the retinal pigment epithelial cells and converts all-trans-retinol to 11-cis-retinol, which subsequently forms the chromophore, 11-cis-retinal, during the visual (retinoid) cycle. These steps are critical in the biological conversion of a photon of light into an electrical signal within the retina. Mutations in the RPE65 gene lead to reduced or absent RPE65 all-trans-retinyl isomerase activity, blocking the visual cycle and resulting in vision loss. Over time, accumulation of toxic precursors leads to the death of retinal pigment epithelial cells, and subsequently to progressive photoreceptor cell death. Individuals with biallelic RPE65 mutation-associated retinal dystrophy exhibit vision loss, including impaired visual function parameters such as visual acuity and visual fields often during childhood or adolescence; this loss of vision ultimately progresses to complete blindness.

Injection of voretigene neparvovec into the subretinal space results in transduction of retinal pigment epithelial cells with a cDNA encoding normal human RPE65 protein (gene augmentation therapy), providing the potential to restore the visual cycle.

Clinical efficacy and safety

The long-term safety and efficacy of Luxturna were assessed in a Phase 1 safety and dose escalation study (101), in which 12 subjects received unilateral subretinal injections of voretigene neparvovec; a follow-on study (102) in which voretigene neparvovec was administered to the contralateral eye in 11 of the 12 subjects who participated in the dose escalation study; a one-year, open-label Phase 3 controlled study (301) in which 31 subjects were randomised at two sites; and the continuation of the Phase 3 study, in which the 9 control subjects crossed over and received the intervention. A total of 41 subjects (81 eyes injected [one Phase 1 subject did not meet eligibility criteria for a second injection]) participated in the clinical programme. All participants had a clinical diagnosis of Leber congenital amaurosis, and some may have also had prior or additional clinical diagnoses, including retinitis pigmentosa. Confirmed biallelic RPE65 mutations and the presence of sufficient viable retinal cells (an area of retina within the posterior pole of >100 micron thickness, as estimated by optical coherence tomography [OCT]) were established for all participants.

Phase 3 study

Study 301 was an open-label, randomised, controlled study. 31 subjects were enrolled, 13 males and 18 females. The average age was 15 years (range 4 to 44 years), including 64% paediatric subjects (n=20, age from 4 to 17 years) and 36% adults (n=11). All subjects had a diagnosis of Leber’s congenital amaurosis owing to RPE65 mutations confirmed by genetic analysis in a certified laboratory.

21 subjects were randomised to receive subretinal injection of voretigene neparvovec. Visual acuity (LogMAR) of the first eye of these subjects at baseline was 1.18 (0.14), mean (SE). One subject discontinued from the study prior to treatment. 10 subjects were randomised to the control (non-intervention) group. Visual acuity (LogMAR) of the first eye of these subjects at baseline was 1.29 (0.21), mean (SE). One subject in the control group withdrew consent and was discontinued from the study. The nine subjects who were randomised to the control group were crossed over to receive subretinal injection of voretigene neparvovec after one year of observation. Each eye was administered a single subretinal injection of 1.5 × 1011 vg voretigene neparvovec in a total volume of 300 |iL. The interval between injection to the eyes for each subject was from 6 to 18 days.

The primary endpoint of the Phase 3 study measured the mean change from baseline to one year in binocular multi-luminance mobility testing (MLMT) between the intervention and control groups. The MLMT was designed to measure changes in functional vision, specifically the ability of a subject to navigate a course accurately and at a reasonable pace at different levels of environmental illumination. This ability depends on the subject’s visual acuity, visual field and the extent of nyctalopia (decreased ability to perceive and/or see in dim light), each of which are functions specifically affected by the retinal disease associated with RPE65 mutations. In the Phase 3 study, the MLMT used seven levels of illumination ranging from 400 lux to 1 lux (corresponding to, for example, a brightly lit office down to a moonless summer night). The testing of each subject was videotaped and assessed by independent graders. A positive change score reflects passing the MLMT at a lower light level and a lux score of 6 reflects the maximum possible MLMT improvement. Three secondary endpoints were also tested: full-field light sensitivity threshold (FST) testing using white light; the change in MLMT score for the first assigned eye; and visual acuity (VA) testing.

At baseline, subjects achieved pass marks on the mobility test at between 4 and 400 ambient lux.

Table 4 Changes in MLMT score: year 1, compared to baseline (ITT population: n=21 intervention, n=10 control)

The monocular MLMT change score significantly improved in the treatment group and was similar to the binocular MLMT results (see Table 4).

Figure 2 shows the effect of the medicinal product over the three-year period in the voretigene neparvovec treatment group, as well as the effect in the control group after crossing over to receive subretinal injection of voretigene neparvovec. Significant differences in binocular MLMT performance were observed for the voretigene neparvovec treatment group at day 30 and were maintained over the remaining follow-up visits throughout the three-year period, compared to no change in the control group. However, after crossing-over to receive subretinal injection of voretigene neparvovec, the subjects in the control group showed a similar response to the voretigene neparvovec as compared to the subjects in the voretigene neparvovec treatment group.

Figure 2 Change in MLMT score using binocular vision versus time before / after exposure to voretigene neparvovec

Each box represents the middle 50% of distribution of MLMT score change. Vertical dotted lines represent additional 25% above and below the box. The horizontal bar within each box represents the median. The dot within each box represents the mean. The solid line connects the mean MLMT score changes over visits for the treatment group. The dotted line connects the mean MLMT score change over visits for the control group, including five visits during the first year without receiving voretigene neparvovec. The control group was administered voretigene neparvovec after 1 year of observation.

BL: baseline;

D30, D90, D180: 30, 90 and 180 days after start of study;

Y1, Y2, Y3: one, two and three years after start of study;

XBL; XD30; XD90; XD180 : baseline, 30, 90 and 180 days after start of study for control crossover group;

XY1; XY2 : one and two years after start of study for control crossover group.

Results of full-field light sensitivity testing at the first study year: white light [Log10(cd.s/m2)] are shown in Table 5 below.

Table 5 Full-field light sensitivity testing

Improvement in full-field light sensitivity was maintained for up to 3 years after exposure to voretigene neparvovec.

At one year after exposure to voretigene neparvovec, improvement in visual acuity of at least 0.3 LogMAR occurred in 11/20 (55%) of the first-treated eyes and 4/20 (20%) of the second-treated eyes in the intervention group; no one in the control group displayed such an improvement of visual acuity in either the first or second eye.

5.2 Pharmacokinetic properties

Voretigene neparvovec is expected to be taken up by cells through heparin sulphate proteoglycan receptors and be degraded by endogenous proteins and DNA catabolic pathways.

Nonclinical biodistribution

Biodistribution of Luxturna was evaluated at three months following subretinal administration in non-human primates. The highest levels of vector DNA sequences were detected in intraocular fluids (anterior chamber fluid and vitreous) of vector-injected eyes. Low levels of vector DNA sequences were detected in the optic nerve of the vector-injected eye, optic chiasm, spleen and liver, and sporadically in the stomach and lymph nodes. In one animal administered with Luxturna at

7.5 × 1011 vg (5 times the recommended per eye dose), vector DNA sequences were detected in colon, duodenum and trachea. Vector DNA sequences were not detected in gonads.

Clinical pharmacokinetics and shedding

The vector shedding and biodistribution were evaluated in tears from both eyes, serum and whole blood of subjects in the Phase 3 clinical study. In 13/29 (45%) subjects receiving bilateral administrations, Luxturna vector DNA sequences were detected in tear samples; most of these subjects were negative after the day 1 post-injection visit, however, four of these subjects had positive tear samples beyond the first day, one subject up to day 14 post-second eye injection. Vector DNA sequences were detected in serum in 3/29 (10%) subjects, including two with positive tear samples, and only up to day 3 following each injection. Overall, transient and low levels of vector DNA were detected in tear and occasional serum samples from 14/29 (48%) of subjects in the Phase 3 study.

Pharmacokinetics in special populations

No pharmacokinetic studies with voretigene neparvovec have been conducted in special populations.

Hepatic and renal impairment

Luxturna is injected directly into the eye. Liver and kidney function, cytochrome P450 polymorphisms and ageing are not expected to influence the clinical efficacy or safety of the product. Therefore, no adjustment in dosage is necessary for patients with hepatic or renal impairment.

5.3 Preclinical safety data

6.  PHARMACEUTICAL PARTICULARS

6.1 List of excipients

Concentrate

Sodium chloride

Sodium dihydrogen phosphate monohydrate (for pH adjustment)

Disodium hydrogen phosphate dihydrate (for pH adjustment) Poloxamer 188

Water for injections

Solvent

Sodium chloride

Sodium dihydrogen phosphate monohydrate (for pH adjustment)

Disodium hydrogen phosphate dihydrate (for pH adjustment) Poloxamer 188

Water for injections

6.2 Incompatibilities

In the absence of compatibility studies, this medicinal product must not be mixed with other medicinal products.

6.3 Shelf life

Unopened frozen vials

2 years

After thawing and dilution

Once thawed, the medicinal product should not be re-frozen and be left at room temperature (below

25 °C).

Following dilution under aseptic conditions, the solution must be used immediately; if not used immediately, the storage time at room temperature (below 25 °C) should be no longer than 4 hours.

6.4 Special precautions for storage

Concentrate and solvent must be stored and transported frozen at ← 65 °C.

For storage conditions after thawing and dilution of the medicinal product, see section 6.3.

6.5 Nature and contents of container

6.6   Special precautions for disposal and other handling

7. MARKETING AUTHORISATION HOLDER

Novartis Europharm Limited

Vista Building

Elm Park, Merrion Road

Dublin 4

Ireland

8. MARKETING AUTHORISATION NUMBER(S)

EU/1/18/1331/001

9. DATE OF FIRST AUTHORISATION/RENEWAL OF THE AUTHORISATION

22 November 2018