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Zemaira®
[Alpha1-Proteinase Inhibitor (Human)] for Injection
Zemaira is a sterile, white, lyophilized preparation of purified Alpha1-Proteinase Inhibitor (Human) (A1-PI), also known as alpha1-antitrypsin, to be reconstituted and administered by the intravenous route. The specific activity of Zemaira is ≥ 0.7 mg of functional A1-PI per milligram of total protein. The purity (total A1-PI/total protein) is ≥ 90% A1-PI. Each vial contains approximately 1000 mg of functionally active A1-PI. The measured amount per vial of functionally active A1-PI as determined by its capacity to neutralize human neutrophil elastase (NE) is printed on the vial label and carton. Following reconstitution with 20 mL of Sterile Water for Injection, USP, the Zemaira solution contains 73 to 89 mM sodium, 33 to 42 mM chloride, 15 to 20 mM phosphate, and 121 to 168 mM mannitol. Hydrochloric acid and/or sodium hydroxide may have been added to adjust the pH. Zemaira contains no preservative.
All plasma used in the manufacture of Zemaira is obtained from US donors and is tested using serological assays for HBsAg and antibodies to HIV-½ and HCV. The plasma is tested with Nucleic Acid Testing (NAT) for HBV, HCV, HIV-1, and HAV, and found to be nonreactive (negative). The plasma is also tested by NAT for B19V. Only plasma that passed the virus screening is used for production. The limit for B19V in the fractionation pool is ≤ 104 International Units of B19V per mL.
Zemaira is manufactured from large pools of human plasma by cold ethanol fractionation according to a modified Cohn process followed by additional purification steps. The manufacturing process includes two virus clearance steps: heat treatment at 60°C for 10 hours in an aqueous solution with stabilizers; and nanofiltration. These virus clearance steps have been validated in a series of in vitro experiments for their capacity to inactivate/ remove both enveloped and non-enveloped viruses. Table 5 shows the virus clearance capacity of the Zemaira manufacturing process, expressed as mean log10 reduction factor.
Table 5: Cumulative (Log10) Virus Inactivation/Removal
in Zemaira
| Manufacturing Step | Virus Reduction Factor (Log10) | |||||
| Enveloped Viruses | Non-Enveloped Viruses | |||||
| HIV-1 | BVDV | WNV | PRV | HAV | CPV | |
| Heat treatment*† | ≥ 6.8 | ≥ 5.2 | ≥ 8.3 | 4.4 | ≥ 5.4 | na |
| Nanofiltration | ≥ 5.5 | ≥ 5.4 | . ≥ 8.4 | ≥ 6.3 | ≥ 5.3 | ≥ 6.4 |
| Cumulative Virus Reduction (log10) | ≥ 12.3 | ≥ 10.6 | ≥ 16.7 | ≥ 10.7 | ≥ 10.7 | ≥ 6.4 |
| HIV, human immunodeficiency virus type 1, a model for
HIV-1 and HIV-2. BVDV, bovine viral diarrhea virus, a model for HCV. WNV, West Nile virus. PRV, pseudorabies virus, a non-specific model for large DNA viruses, eg. herpes. HAV, hepatitis A virus. CPV, canine parvovirus, model for B19V. na, not applicable. * Studies using B19V, which are considered experimental in nature, have demonstrated a virus reduction factor of 1.9 log10. † At 60°C for 10 hours. |
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Zemaira is an alpha1-proteinase inhibitor (A1-PI) indicated for chronic augmentation and maintenance therapy in adults with A1-PI deficiency and clinical evidence of emphysema.
Zemaira increases antigenic and functional (anti-neutrophil elastase capacity [ANEC]) serum levels and lung epithelial lining fluid (ELF) levels of A1-PI.
Clinical data demonstrating the long-term effects of chronic augmentation therapy of individuals with Zemaira are not available.
The effect of augmentation therapy with Zemaira or any A1-PI product on pulmonary exacerbations and on the progression of emphysema in A1-PI deficiency has not been demonstrated in randomized, controlled clinical studies.
Zemaira is not indicated as therapy for lung disease patients in whom severe A1-PI deficiency has not been established.
For Intravenous Use After Reconstitution Only.
The recommended dose of Zemaira is 60 mg/kg body weight administered once weekly. Dose ranging studies using efficacy endpoints have not been performed with Zemaira or any A1-PI product.
Follow the steps below to reconstitute Zemaira:
1. Ensure that the Zemaira (green cap) vial and diluent (white cap) vial are at room temperature.
2. Remove the plastic flip-top caps from the vials. Aseptically cleanse the rubber stoppers with antiseptic solution and allow
them to dry. Notes on Using the Transfer Device (Steps 3 through 7):
The transfer device (Figure 1) provided in the Zemaira carton has a white (diluent) end with a double orifice and a green (Zemaira) end with a single orifice.
Incorrect use of the transfer device will result in loss of vacuum and prevent transfer of the diluent, thereby prolonging or preventing reconstitution of Zemaira.
The transfer device is sterile. Once the protective covers have been removed (Steps 3 and 4), do not touch the exposed
ends of the spikes.
Figure 1
 |
3. Remove the protective cover from the white (diluent) end of the transfer device. Insert the white end of the transfer device into the center of the stopper of the upright diluent vial (Figure 2).
Figure 2
 |
4. Remove the protective cover from the green (Zemaira) end of the transfer device. Invert the diluent vial with the attached transfer device and, using minimum force, insert the green end of the transfer device into the center of the rubber stopper of the upright Zemaira vial (green top) (Figure 3). The flange of the transfer device should rest on the surface of the stopper so that the diluent flows into the Zemaira vial.
Figure 3
 |
5. Allow the vacuum in the Zemaira vial to pull the diluents into the Zemaira vial.
6. During diluent transfer, wet the lyophilized cake completely by gently tilting the Zemaira vial (Figure 4). Do not allow the air inlet filter to face downward. Care should be taken not to lose the vacuum, as this will prolong or prevent reconstitution.
Figure 4
 |
7. After diluent transfer is complete, the transfer device will allow filtered air into the Zemaira vial through the air filter; additional venting of the Zemaira vial is not required. When diluent transfer is complete, withdraw the transfer device from the diluent vial and discard the diluent vial and transfer device.
8. Gently swirl the Zemaira vial until the powder is completely dissolved (Figure 5). DO NOT SHAKE.
Figure 5
 |
If more than 1 vial of Zemaira is needed to achieve the required dose, use aseptic technique to transfer the reconstituted solution from the vials into the administration container (e.g., empty intravenous bag or glass bottle).
Zemaira is supplied in a single-use vial containing approximately 1000 mg of functionally active A1-PI as a lyophilized powder for reconstitution with 20 mL of Sterile Water for Injection, USP. The amount of functional A1-PI is printed on the vial label and carton.
Zemaira is supplied in a single use vial containing the amount of functionally active A1-PI printed on the label.
The product presentation includes a package insert and the following components:
| Presentation | Carton NDC Number | Components |
| 1000 mg of functionally active A1-PI | 0053-7201-02 |
|
When stored up to 25°C (77°F), Zemaira is stable for the period indicated by the expiration date on its label. Avoid freezing, which may damage the diluent vial.
Manufactured by: CSL Behring LLC, Kankakee, IL 60901 USA.
The most common adverse reactions (ARs) occurring in at least 5% of subjects receiving Zemaira in all pre-licensure clinical trials were headache, sinusitis, upper respiratory infection, bronchitis, asthenia, cough increased, fever, injection site hemorrhage, rhinitis, sore throat, and vasodilation. Serious adverse reactions reported following administration of Zemaira in pre-licensure clinical trials included one event each in separate subjects of bronchitis and dyspnea, and one event each in a single subject of chest pain, cerebral ischemia and convulsion.
In post-licensure trials, the exposure adjusted incidence rate (EAIR) of serious exacerbations of chronic obstructive pulmonary disease (COPD) among subjects was higher during the RAPID Extension trial as compared to the rate observed during the preceding RAPID trial [see Clinical Trials Experience below].
Serious adverse reactions identified during postmarketing use were hypersensitivity reactions [see WARNINGS AND PRECAUTIONS].
Because clinical trials are conducted under widely varying conditions, adverse reaction rates observed in the clinical trials of a drug product cannot be directly compared to rates in the clinical trials of another drug and may not reflect the rates observed in clinical practice.
The following clinical trials were conducted with Zemaira:
Table 1 summarizes the ARs, expressed as events per subject-year, and the corresponding number of ARs per infusion, expressed as % of all infusions, for each treatment in prelicensure clinical trials of Zemaira.
Table 1: Overall Adverse Reactions (ARs) and Serious
ARs
| Number of Subjects* (Events per Sub-ject-Year†) | Number of Infusions‡ (% of all Infusions) | |||
| Zemaira (n=66, SY§=28.72) |
Prolastin (n=32), SY§=3.83) |
Zemaira (n=1296) |
Prolastin (n=160) |
|
| ARs (AEs assessed by investigator as at least possibly related or occurring during or within 72 hours after the end of the infusion or for which causality assessment was missing or indeterminate). | 54 (5.6) | 16 (3.8) | 160 (12.3) | 31 (19.4) |
| Serious ARs (Serious AEs assessed by investigator as at least possibly related or occurring during or within 72 hours after the end of the infusion or for which causality assessment was missing or indeterminate). | 4 (0.2) | 1 (1.0) | 6 (0.5) | 1 (0.6) |
| * Based on unique subjects. If a subject experienced more
than one AR, the subject was only counted once. † The exposure adjusted event rate was based on total exposure time presented in subject-years and the total number of adverse reactions in the database. ‡ If there were multiple occurrences of ARs following a single infusion, only one occurrence was counted. § SY=subject-year. |
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Table 2 summarizes the ARs occurring in 5% or more ( > 3) subjects, expressed as events per subject-year, and the corresponding number of ARs per infusion, expressed as % of all infusions, for each treatment in clinical trials of Zemaira.
Table 2: Adverse Reactions Occurring in ≥ 5% of
Subjects
| ARs (AEs assessed by investigator as at least possibly related or occurring during or within 72 hours after the end of the infusion or for which causality assessment was missing or indeterminate). | Number of Subjects* (Events per Sub-ject-Year†) | Number of Infusions‡ (% of all Infusions) | ||
| Zemaira (n=66, SY§=28.72) |
Prolastin (n=32, SY§=3.83) |
Zemaira (n=1296) |
Prolastin (n=160) |
|
| Headache | 13 (0.7) | 5 (1.3) | 19 (1.5) | 5 (3.1) |
| Sinusitis | 10 (0.5) | 1 (0.3) | 13 (1.0) | 1 (0.6) |
| Upper Respiratory Infection | 10 (0.4) | 1 (0.3) | 10 (0.8) | 1 (0.6) |
| Bronchitis | 5 (0.2) | 0 (0.0) | 6 (0.5) | 0 (0.0) |
| Asthenia | 5 (0.2) | 2 (0.5) | 5 (0.4) | 2 (1.3) |
| Cough Increased | 5 (0.2) | 1 (0.5) | 5 (0.4) | 2 (1.3) |
| Fever | 4 (0.1) | 0 (0.0) | 4 (0.3) | 0 (0.0) |
| Injection Site Hemorrhage | 4 (0.1) | 0 (0.0) | 4 (0.3) | 0 (0.0) |
| Rhinitis | 4 (0.1) | 0 (0.0) | 4 (0.3) | 0 (0.0) |
| Sore Throat | 4 (0.1) | 0 (0.0) | 4 (0.3) | 0 (0.0) |
| Vasodilation | 4 (0.1) | 1 (0.3) | 4 (0.3) | 1 (0.6) |
| * Based on unique subjects. If a subject experienced more
than one AR of the same type, the subject was only counted once. †The exposure adjusted event rate was based on total exposure time presented in subject-years and the total number of adverse reactions in the database. ‡ If more than one of the same type of an event occurred after an infusion, only one event was counted. § SY=subject-year. |
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Diffuse interstitial lung disease was noted on a routine chest x-ray of one subject at Week 24. Causality could not be determined.
In a retrospective analysis, during the 10-week blinded portion of the 24-week clinical trial, 6 subjects (20%) of the 30 treated with Zemaira had a total of 7 exacerbations of their chronic obstructive pulmonary disease (COPD). Nine subjects (64%) of the 14 treated with Prolastin had a total of 11 exacerbations of their COPD. The observed difference between groups was 44% (95% confidence interval [CI] from 8% to 70%). Over the entire 24-week treatment period, of the 30 subjects in the Zemaira treatment group, 7 subjects (23%) had a total of 11 exacerbations of their COPD.
In the 24-week double-blind trial, Zemaira-treated subjects were tested for HAV, HBV, HCV, HIV, and parvovirus B19 (B19V), and no evidence of virus transmission was observed. In the RAPID study 25 serious exacerbations of COPD were reported in 15 Zemaira subjects vs. 17 such events in 9 placebo subjects, corresponding to rates of 0.146 exacerbations per subject-year with Zemaira and 0.115 exacerbations per subject-year with placebo, (ratio Zemaira:Placebo [95% confidence interval]: 1.256 [0.457 - 3.454]).
Subjects who were randomized to Zemaira in the 2-year RAPID trial who then entered and received open-label Zemaira in the 2 year RAPID extension trial were in the “Early Start” group. Subjects who were randomized to Placebo in the 2-year RAPID trial who then entered and received open-label Zemaira in the 2 year RAPID extension trial were in the “Delayed Start” group. During the RAPID Extension trial 37 serious exacerbations of COPD were reported in 19 subjects (25%) in the Early Start group, corresponding to rates of 0.25 exacerbations per subject-year. In comparison, 20 serious exacerbations were reported in 11 subjects (17%) in the Delayed Start group corresponding to rates of 0.16 exacerbations per subject-year (ratio Early: Delayed [95% confidence interval]: 1.58 [0.68 – 3.66], Table 3). Among the Early Start subjects who entered the RAPID extension trial (N = 76), the exposure adjusted incidence rate of serious exacerbations during the RAPID extension trial (years 3-4) was 0.25 compared to 0.12 for those subjects during the earlier RAPID trial(years 1-2), (ratio RAPID Extension:RAPID: 2.10 [95% confidence interval: 1.21 – 3.67]). Among the Delayed Start subjects who entered the RAPID extension trial (N = 64), the exposure adjusted incidence rate of serious exacerbations during the RAPID extension trial (years 3-4) was 0.16 compared to 0.10 for those subjects during the earlier RAPID trial (years 1-2), (ratio RAPID Extension:RAPID: 1.56 [95% confidence interval: 0.80 – 3.03]).
Table 3: Comparison of Exposure-Adjusted Incidence
Rates for Serious COPD Exacerbations Occurring in the RAPID study between
Zemaira and Placebo subjects and in the RAPID Extension Studies between Early
Start and Delayed Start subjects
| Serious COPD Exacer- bations* | Episode | n | % | EAIR (95% CI) | Episode | n | % | EAIR 95% CI | Treatment Ratio for EIAR (95% CI)* |
| RAPID Study (Years 1 - 2) | Zemaira (N = 93) | Placebo (N = 87) | Zemaira: Placebo | ||||||
| 25 | 15 | 16.1 | 0.15 (0.10 -0.22) | 17 | 9 | 10.3 | 0.12 (0.07 -0.18) | 1.26 (0.46 -3.45) | |
| Extension Study (Years 3 - 4) | Early Start† (N = 76) | Delayed Start‡ (N = 64) | Early: Delayed | ||||||
| 37 | 19 | 25.0 | 0.25 (0.18 -0.35) | 20 | 11 | 17.2 | 0.16 (0.10 -0.25) | 1.58 (0.68 -3.66) | |
| N = total number of safety subjects, n = number of
subjects within a category, % = (n/N)*100, CI = Confidence Interval. Subject
time at risk: Zemaira = 171.14 years, Placebo = 147.75 years, Early Start Group
= 146.46 years, Delay Start Group = 124.71 years. EAIR = Exposure-Adjusted Incidence Rate (events/subject time at risk). The point estimates and confidence intervals for EAIR values were calculated using negative binomial models. *Episode = Serious exacerbations of COPD identified by investigators as meeting the Anthonisen criteria1 plus Serious Adverse Event (SAE) terms COPD, Condition Aggravated, Bronchitis, Lower Respiratory Tract Infection, Pneumonia. Serious exacerbation events that overlap or occur within 1 day of one another were counted as single exacerbation episodes. †Early Start Group subjects were randomized to Zemaira during the double-blind RAPID trial (years 1-2) and received open-label Zemaira during the RAPID extension trial (years 3-4). ‡Delayed Start Group subjects were randomized to Placebo during the double-blind RAPID trial (years 1-2) and received open-label Zemaira during the RAPID extension trial (years 3-4). |
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As with all therapeutic proteins, there is potential for immunogenicity. No anti-A1PI antibodies have been detected in clinical trials of Zemaira. The detection of antibody formation is highly dependent on the sensitivity and specificity of the assay. Additionally, the observed incidence of antibody (including neutralizing antibody) positivity in an assay may be influenced by several factors including assay methodology, sample handling, timing of sample collection, concomitant medications, and underlying disease. For these reasons, comparison of the incidence of antibodies to Zemaira with the incidence of antibodies to other products may be misleading.
Because postmarketing reporting of adverse reactions is voluntary and from a population of uncertain size, it is not always possible to reliably estimate the frequency of these reactions or establish a causal relationship to product exposure.
Table 4 lists the ARs that have been identified during postmarketing use of Zemaira. This list does not include reactions already reported in clinical trials with Zemaira [see Clinical Trials Experience above].
Table 4: ARs Reported During the Postmarketing Use of
Zemaira
| System Organ Class | Preferred Term/Symptoms |
| Blood and lymphatic system disorders | Lymph node pain |
| Gastrointestinal disorders | Nausea |
| General disorders and administration site conditions | Chills, infusion site reactions, facial, periorbital, lip and extremity swelling, chest pain |
| Immune system disorders | Hypersensitivity, anaphylactic reactions, tachycardia, hypotension, confusion, syncope, oxygen consumption decreased, pharyngeal edema |
| Nervous system disorders | Hypoesthesia, paresthesia, dizziness |
| Skin disorders | Hyperhidrosis, pruritus, rash including exfoliative and generalized, urticaria |
| Vascular disorders | Flushing |
No information provided.
Included as part of the PRECAUTIONS section.
Caution should be used when administering Zemaira to individuals who have experienced anaphylaxis or severe systemic reaction to another A1-PI product. IF ANAPHYLACTIC OR SEVERE ANAPHYLACTOID REACTIONS OCCUR, DISCONTINUE THE INFUSION IMMEDIATELY. Have epinephrine and other appropriate supportive therapy available for the treatment of any acute anaphylactic or anaphylactoid reaction. Zemaira is contraindicated in patients with a history of anaphylaxis or severe systemic reactions to Zemaira or A1-PI protein.
Zemaira may contain trace amounts of IgA. Patients with selective or severe IgA deficiency can develop antibodies to IgA and, therefore, have a greater risk of developing potentially severe hypersensitivity and anaphylactic reactions. IF ANAPHYLACTIC OR SEVERE ANAPHYLACTOID REACTIONS OCCUR, DISCONTINUE THE INFUSION IMMEDIATELY. Have epinephrine and other appropriate supportive therapy available for the treatment of any acute anaphylactic or anaphylactoid reaction. Zemaira is contraindicated in IgA-deficient patients with antibodies against IgA, due to the risk of severe hypersensitivity.
Because Zemaira is made from human plasma, it may carry a risk of transmitting infectious agents (e.g., viruses, and theoretically the Creutzfeldt-Jakob disease [CJD] agent). The risk of infectious agent transmission has been reduced by screening plasma donors for prior exposure to certain viruses, testing for the presence of certain current virus infections, and including virus inactivation/removal steps in the manufacturing process for Zemaira [see DESCRIPTION]. Despite these measures, Zemaira, like other products made from human plasma, may still potentially contain human pathogenic agents, including those not yet known or identified. Thus, the risk of transmission of infectious agents cannot be totally eliminated.
All infections thought by a physician to have been possibly transmitted by this product should be reported by the physician or other healthcare provider to the CSL Behring Pharmacovigilance Department at 1-866-915-6958 or FDA at 1-800-FDA-1088 or www. fda.gov/medwatch.
Long-term studies in animals to evaluate carcinogenesis, mutagenesis, or impairment of fertility have not been conducted.
Pregnancy Category C. Animal reproduction studies have not been conducted with Zemaira. Safety and effectiveness in pregnancy have not been established. Zemaira should be given to a pregnant woman only if clearly needed.
It is not known whether Zemaira is excreted in human milk. Use Zemaira only if clearly needed when treating nursing women.
Safety and effectiveness in the pediatric population have not been established.
The safety and efficacy of Zemaira in the geriatric population have not been established due to an insufficient number of subjects.
REFERENCES
1. Anthonisen NR, Connett, JE, Kiley, JP, et al. Effects of Smoking Intervention and the Use of an Inhaled Anticholinergic Bronchodilator and on the Rate of Decline of FEV1 – The Lung Study. JAMA. 1994;272(19):1497-1505.
No information provided.
A1-PI deficiency is a chronic, hereditary, autosomal, co-dominant disorder that is usually fatal in its severe form. Low blood levels of A1-PI (i.e., below 11 μM) are most commonly associated with progressive, severe emphysema that becomes clinically apparent by the third to fourth decade of life. In addition, PiSZ individuals, whose serum A1-PI levels range from approximately 9 to 23 mM, are considered to have a moderately increased risk for developing emphysema, regardless of whether their serum A1-PI levels are above or below 11 mM.2 Not all individuals with severe genetic variants of A1-PI deficiency have emphysema. Augmentation therapy with Alpha1-Proteinase Inhibitor (Human) is indicated only in patients with severe congenital A1-PI deficiency who have clinically evident emphysema. A registry study showed 54% of A1-PI deficient subjects had emphysema.3 Another registry study showed 72% of A1-PI deficient subjects had pulmonary symptoms.4 Smoking is an important risk factor for the development of emphysema in patients with A1-PI deficiency.
Approximately 100 genetic variants of A1-PI deficiency can be identified electrophoretically, only some of which are associated with the clinical disease.5,6 Ninety-five percent of clinically symptomatic A1-PI deficient individuals are of the severe PiZZ phenotype. Up to 39% of A1-PI deficient patients may have an asthmatic component to their lung disease, as evidenced by symptoms and/or bronchial hyperreactivity.3 Pulmonary infections, including pneumonia and acute bronchitis, are common in A1-PI deficient patients and contribute significantly to the morbidity of the disease.
Augmenting the levels of functional protease inhibitor by intravenous infusion is an approach to therapy for patients with A1-PI deficiency. However, the efficacy of augmentation therapy in affecting the progression of emphysema has not been demonstrated in randomized, controlled clinical studies. The intended theoretical goal is to provide protection to the lower respiratory tract by correcting the imbalance between NE and protease inhibitors.
Whether augmentation therapy with Zemaira or any A1-PI product actually protects the lower respiratory tract from progressive emphysematous changes has not been evaluated. Individuals with endogenous levels of A1-PI below 11 mM, in general, manifest a significantly increased risk for development of emphysema above the general population background risk.6,7,8,9 Although the maintenance of blood serum levels of A1-PI (antigenically measured) above 11 mM has been historically postulated to provide therapeutically relevant antineutrophil elastase protection10, this has not been proven. Individuals with severe A1-PI deficiency have been shown to have increased neutrophil and NE concentrations in lung epithelial lining fluid compared to normal PiMM individuals, and some PiSZ individuals with A1-PI above 11 mM have emphysema attributed to A1-PI deficiency.2 These observations underscore the uncertainty regarding the appropriate therapeutic target serum level of A1- PI during augmentation therapy.
Pulmonary disease, particularly emphysema, is the most frequent manifestation of A1-PI deficiency.6 The pathogenesis of emphysema is understood to evolve as described in the “protease-antiprotease imbalance” model. A1-PI is now understood to be the primary antiprotease in the lower respiratory tract, where it inhibits NE.11 Normal healthy individuals produce sufficient A1-PI to control the NE produced by activated neutrophils and are thus able to prevent inappropriate proteolysis of lung tissue by NE. Conditions that increase neutrophil accumulation and activation in the lung, such as respiratory infection and smoking, will in turn increase levels of NE. However, individuals who are severelydeficient in endogenous A1-PI are unable to maintain an appropriate antiprotease defense and are thereby subject to more rapid proteolysis of the alveolar walls leading to chronic lung disease. Zemaira serves as A1-PI augmentation therapy in this patient population, acting to increase and maintain serum levels and (ELF) levels of A1-PI.
Weekly repeated infusions of A1-PI at a dose of 60 mg/kg lead to serum A1-PI levels above the historical target threshold of 11 mM.
The clinical benefit of the increased blood levels of A1-PI at the recommended dose has not been established for any A1-PI product.
A double-blind, randomized, active-controlled, crossover pharmacokinetic study was conducted in 13 males and 5 females with A1-PI deficiency, ranging in age from 36 to 66 years. Nine subjects received a single 60 mg/kg dose of Zemaira followed by Prolastin, and 9 subjects received Prolastin followed by a single 60 mg/kg dose of Zemaira, with a washout period of 35 days between doses. A total of 13 post-infusion serum samples were taken at various time points up to Day 21. Table 6 shows the mean results for the Zemaira pharmacokinetic parameters.
Table 6: Pharmacokinetic Parameters for Antigenic A1-PI
in 18 Subjects Following a Single 60 mg/kg Dose of Zemaira
| Pharmacokinetic Parameter | Mean (SD)* |
| Area under the curve (AUC0-∞) | 144 (±27) μM x day |
| Maximum concentration (Cmax) | 44.1 (±10.8) μM |
| Terminal half-life (t½β) | 5.1 (±2.4) days |
| Total clearance | 603 (±129) mL/day |
| Volume of distribution at steady state | 3.8 (±1.3) L |
| * n=18 subjects. | |
In a safety pharmacology study, dogs were administered a 60 or 240 mg/kg intravenous dose of Zemaira. At the clinical dose of 60 mg/kg, no changes in cardiovascular and respiratory parameters or measured hematology, blood chemistry, or electrolyte parameters were attributed to the administration of Zemaira. A minor transient decrease in femoral resistance and increase in blood flow were observed after administration of the 240 mg/ kg dose.
In single-dose studies, mice and rats were administered a 0, 60, 240, or 600 mg/kg intravenous dose of Zemaira and observed twice daily for 15 days. No signs of toxicity were observed up to 240 mg/kg. Transient signs of distress were observed in male mice and in male and female rats after administration of the highest dose (600 mg/kg).
In repeat-dose toxicity studies, rats and rabbits received 0, 60, or 240 mg/kg intravenous doses of Zemaira once daily for 5 consecutive days. No treatment-related effects on clinical signs, body weight, hematology, coagulation, or urinalysis were observed in rats administered up to 240 mg/kg. No signs of toxicity were observed in rabbits administered 60 mg/kg. Changes in organ weights and minimal epidermal ulceration were observed in rabbits administered 240 mg/kg, but had no clinical effects.
The local tolerance of Zemaira was evaluated in rabbits following intravenous, perivenous,and intraarterial administration. No treatment-related local adverse reactions were observed.
Clinical trials were conducted pre-licensure with Zemaira in 89 subjects (59 males and 30 females). The subjects ranged in age from 29 to 68 years (median age 49 years). Ninety-seven percent of the treated subjects had the PiZZ phenotype of A1-PI deficiency, and 3% had the MMALTON phenotype. At screening, serum A1-PI levels were between 3.2 and 10.1 mM (mean of 5.6 mM). The objectives of the clinical trials were to demonstrate that Zemaira augments and maintains serum levels of A1-PI above 11 mM (80 mg/dL) and increases A1-PI levels in ELF of the lower lung.
In a double-blind, controlled clinical trial to evaluate the safety and efficacy of Zemaira, 44 subjects were randomized to receive 60 mg/kg of either Zemaira or Prolastin once weekly for 10 weeks. After 10 weeks, subjects in both groups received Zemaira for an additional 14 weeks. Subjects were followed for a total of 24 weeks to complete the safety evaluation [see ADVERSE REACTIONS]. The mean trough serum A1-PI levels at steady state (Weeks 7-11) in the Zemaira-treated subjects were statistically equivalent to those in the Prolastin-treated subjects within a range of ±3 mM. Both groups were maintained above 11 mM. The mean (range and standard deviation [SD]) of the steady state trough serum antigenic A1-PI level for Zemaira-treated subjects was 17.7 mM (range 13.9 to 23.2, SD 2.5) and for Prolastin-treated subjects was 19.1 mM (range 14.7 to 23.1, SD 2.2). The difference between the Zemaira and the Prolastin groups was not considered clinically significant and may be related to the higher specific activity of Zemaira.
In a subgroup of subjects enrolled in the trial (10 Zemaira-treated subjects and 5 Prolastintreated subjects), bronchoalveolar lavage was performed at baseline and at Week 11.Four A1-PI related analytes in ELF were measured: antigenic A1-PI, A1-PI:NE complexes, free NE, and functional A1-PI (ANEC). A blinded retrospective analysis, which revised the prospectively established acceptance criteria showed that within each treatment group, ELF levels of antigenic A1-PI and A1-PI:NE complexes increased from baseline to Week 11 (Table 7). Free elastase was immeasurably low in all samples. The post-treatment ANEC values in ELF were not significantly different between the Zemaira-treated and Prolastin-treated subjects (mean 1725 nM vs. 1418 nM). No conclusions can be drawn about changes of ANEC values in ELF during the trial period as baseline values in the Zemaira-treated subjects were unexpectedly high. No A1-PI analytes showed any clinically significant differences between the Zemaira and Prolastin treatment groups.
Table 7: Change in ELF From Baseline to Week 11 in a
Subgroup Analysis
| Analyte | Treatment | Mean Change From Baseline | 90% CI |
| A1-PI (nM) | Zemaira* | 1358.3 | 822.6 to 1894.0 |
| Prolastin† | 949.9 | 460.0 to 1439.7 | |
| ANEC (nM) | Zemaira | -588.1 | -2032.3 to 856.1 |
| Prolastin | 497.5 | -392.3 to 1387.2 | |
| A1-PI:NE Complexes (nM) | Zemaira | 118.0 | 39.9 to 196.1 |
| Prolastin | 287.1 | 49.8 to 524.5 | |
| CI, confidence interval. * n=10 subjects. † n=5 subjects. |
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The clinical efficacy of Zemaira or any A1-PI product in influencing the course of pulmonary emphysema or pulmonary exacerbations has not been demonstrated in adequately powered, randomized, controlled clinical trials.
REFERENCES
2. Turino GM, Barker AF, Brantly ML, et al. Clinical features of individuals with PI*SZ phenotype of α1-antitrypsin deficiency. Am J Respir Crit Care Med. 1996;154:1718-1725.
3. Stoller JK, Brantly M, et al. Formation and current results of a patient-organized registry for α1-antitrypsin deficiency. Chest. 2000;118(3):843-848.
4. McElvaney NG, Stoller JK, et al. Baseline characteristics of enrollees in the National Heart, Lung, and Blood Institute Registry of α1-Antitrypsin Deficiency. Chest. 1997;111:394-403.
5. Crystal RG. α1-antitrypsin deficiency, emphysema, and liver disease; genetic basis and strategies for therapy. J Clin Invest. 1990;85:1343-1352.
6. World Health Organization. Alpha-1-antitrypsin deficiency; Report of a WHO Meeting. Geneva. 18-20 March 1996.
7. Eriksson S. Pulmonary emphysema and alpha1-antitrypsin deficiency. ACTA Med Scand. 1964;175(2):197-205.
8. Eriksson S. Studies in α1-antitrypsin deficiency. ACTA Med Scan Suppl. 1965;432:1-85.
9. Gadek JE, Crystal RG. α1-antitrypsin deficiency. In: Stanbury JB, Wyngaarden JB, Frederickson DS, et al., eds. The Metabolic Basis of Inherited Disease. 5th ed. New York, NY: McGraw-Hill; 1983:1450-1467.
10. American Thoracic Society. Guidelines for the approach to the patient with severehereditary alpha-1-antitrypsin deficiency. Am Rev Respir Dis. 1989;140:1494-1497.
11. Gadek JE, Fells GA, Zimmerman RL, Rennard SI, Crystal RG. Antielastases of the human alveolar structures; implications for the protease-antiprotease theory of emphysema. J Clin Invest. 1981;68:889-898.
