Hubbry Logo
Recombinant factor VIIaRecombinant factor VIIaMain
Open search
Recombinant factor VIIa
Community hub
Recombinant factor VIIa
logo
7 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Recombinant factor VIIa
Recombinant factor VIIa
Recombinant factor VIIa
View on Wikipedia
from Wikipedia

Recombinant factor VIIa
INN: Eptacog alfa
Clinical data
Trade namesNovoseven, Sevenfact, others
Other namesrFVIIa, Coagulation factor VIIa (recombinant), Coagulation factor VIIa (recombinant)-jncw
BiosimilarsAryoseven
AHFS/Drugs.comMonograph
License data
Pregnancy
category
  • AU: B1
Routes of
administration		Intravenous injection
ATC code
Legal status
Legal status
Identifiers
CAS Number
DrugBank
ChemSpider
  • none
UNII
KEGG
Chemical and physical data
FormulaC1982H3054N560O618S28
Molar mass45513.22 g·mol−1

Recombinant factor VIIa (rfVIIa) is a form of blood factor VII that has been manufactured via recombinant technology.[4][5] It is administered via an injection into a vein.[6][4][5] It is used to treat bleeding episodes in people who have acquired hemophilia, among other indications.[7]

List of recombinant factor VIIa formulations
INN USAN Brand name Notes
Eptacog alfa (activated) coagulation factor VIIa (recombinant) Novoseven Oldest formulation, Baby hamster kidney cells (BHK).[7]
Eptacog alfa (activated) coagulation factor VIIa (recombinant) Novoseven RT Approved in the US in 2008.[2] BHK cells.[2]
Eptacog beta (activated) coagulation factor VIIa (recombinant)-jncw Sevenfact (US), Cevenfacta (EU) Produced through rabbit milk.[8] Approved in the US in 2020,[8][9] and in the EU in 2022.[5]

The most common side effects with Novoseven include venous thromboembolic events (problems caused by blood clots in the veins), rash, pruritus (itching), urticaria (hives), fever and reduced effectiveness of treatment.[4] The most common side effects with Cevenfacta include injection site discomfort and hematoma (a collection of blood under the skin) as well as injection-related reactions, an increase in body temperature, dizziness and headache.[5]

Novoseven was authorized for medical use in the European Union in February 1996,[4] and in the United States in March 1999.[10]

Medical uses

[edit]

Novoseven is indicated for the treatment of bleeding episodes and for the prevention of bleeding in surgical interventions or invasive procedures in people with acquired hemophilia.[10][7]

Novoseven RT is indicated for the treatment of bleeding episodes and peri-operative management in adults and children with hemophilia A or B with inhibitors, congenital factor VII deficiency, and Glanzmann's thrombasthenia with refractoriness to platelet transfusions, with or without antibodies to platelets and for the treatment of bleeding episodes and peri-operative management in adults with acquired hemophilia.[6][2]

Sevenfact [coagulation factor VIIa (recombinant)-jncw] is approved for use in the United States and is indicated for the treatment and control of bleeding episodes occurring in adults and adolescents twelve years of age and older with hemophilia A or B with inhibitors (neutralizing antibodies).[8][9][3]

As of 2012, recombinant factor VIIa is not supported by the evidence for treating most cases of major bleeding.[11] There is a significant risk of arterial thrombosis with its use and thus, other than in those with factor VII deficiency or acquired hemophilia, it should only be given in clinical trials.[11] Recombinant human factor VII, while initially looking promising in intracerebral hemorrhage, failed to show benefit following further study and is no longer recommended.[12][13]

In people with hemophilia type A and B who have a deficiency of factors VIII and IX, these two factors are administered for controlling bleeding or as prophylaxis medication before starting surgeries. However, in some cases they subsequently develop neutralizing antibodies, called inhibitors, against the drug. These inhibitors often increase over time and inhibit the action of coagulation in the body. Recombinant factor VIIa, which is an activated form of factor VII, bypasses factors VIII and IX and causes coagulation without the need for factors VIII and IX. It may be used in acquired hemophilia patients with higher inhibitor titers.[14] Other indications include use for patients with inherited deficiency of factor VII, and people with Glanzmann's thrombasthenia.[6]

Pharmacology

[edit]

Mechanism of action

[edit]

This treatment results in activation of the extrinsic pathway of blood coagulation.[6] Recombinant factor VIIa activates factor X, which starts the clotting process and thereby provides control of the bleeding.[5] Because factor VII acts directly on factor X, independently from factors VIII and IX, recombinant factor VIIa can be used to restore haemostasis in their absence or in the presence of inhibitors.[5]

Coagulation factor VIIa (recombinant)-jncw

[edit]

Coagulation factor VIIa (recombinant)-jncw (Sevenfact) is expressed in the mammary gland of genetically engineered rabbits and secreted into the rabbits' milk. During purification and processing of the milk, FVII is converted into activated FVII (FVIIa).[8] The recombinant DNA (rDNA) construct in the genetically engineered rabbits used for the production of Sevenfact was approved by the FDA's Center for Veterinary Medicine.[8]

The safety and efficacy of coagulation factor VIIa (recombinant)-jncw were determined using data from a clinical study that evaluated 27 patients with hemophilia A or B with inhibitors, which included treatment of 465 mild or moderate, and three severe bleeding episodes.[8] The study assessed the efficacy of treatment twelve hours after the initial dose was given.[8] The proportion of mild or moderate bleeding episodes treated successfully both with the lower dose of 75mcg/kg and higher dose of 225 mcg/kg (requiring no further treatment for the bleeding episode, no administration of blood products and no increase in pain beyond 12 hours from initial dose) was approximately 86%.[8] The study also included three severe bleeding episodes that were treated successfully with the higher dose.[8]

Another study evaluated the safety and pharmacokinetics of three escalating doses of coagulation factor VIIa (recombinant)-jncw in 15 subjects with severe hemophilia A or B with or without inhibitors.[8] Results from this study were used to select the two doses, 75mcg/kg and 225 mcg/kg, that were evaluated in the study described above.[8]

The most common side effects of coagulation factor VIIa (recombinant)-jncw are headache, dizziness, infusion site discomfort, infusion related reaction, infusion site hematoma and fever.[8]

Coagulation factor VIIa (recombinant)-jncw is contraindicated in those with known allergy or hypersensitivity to rabbits or rabbit proteins.[8]

In 2022, the EU approved eptacog beta (Cevenfacta). Both are made by the same manufacturer (LFB) and through rabiit milk. Eptacog beta functions like coagulation factor VII.[5][15]

Society and culture

[edit]
[edit]

Novoseven was approved for use in the United States in March 1999, and indicated for the treatment of bleeding episodes in hemophilia A or B patients with inhibitors to Factor VIII or Factor IX.[10] It was approved in October 2006, and indicated for the treatment of bleeding episodes and for the prevention of bleeding in surgical interventions or invasive procedures in patients with acquired hemophilia.[10]

Novoseven RT was approved for use in the United States in May 2008 as a room-temperature stable formulation.[6] In January 2010, the label was updated to include a boxed warning on serious thrombotic adverse events associated with the use of Novoseven RT outside labeled indications.[6][2]

In April 2020, coagulation factor VIIa (recombinant)-jncw (Sevenfact) was approved for use in the United States.[9][8]

In May 2022, the Committee for Medicinal Products for Human Use (CHMP) of the European Medicines Agency (EMA) adopted a positive opinion, recommending the granting of a marketing authorization for the medicinal product Cevenfacta, intended for the treatment of bleeding episodes.[16][5] The applicant for this medicinal product is Laboratoire français du Fractionnement et des Biotechnologies (LFB).[16] Eptacog beta (activated) was authorized for medical use in the EU in July 2022.[5]

Military use

[edit]

Recombinant factor VIIa was used routinely in severely wounded American troops during the Iraq War, credited with saving many lives but also resulting in a high number of deep venous thromboses and pulmonary emboli, as well as unexpected strokes, heart attacks, and deaths.[17][18]

Research

[edit]

A possible role in severe postpartum hemorrhage has been suggested.[19]

References

[edit]

Further reading

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Recombinant factor VIIa

View on Grokipedia
from Grokipedia
Recombinant factor VIIa (rFVIIa), also known as eptacog alfa, is a bioengineered, recombinant analog of the human coagulation protein factor VIIa, primarily used as an intravenous hemostatic agent to treat and prevent bleeding episodes in patients with hemophilia A or B who have developed inhibitors to clotting factors VIII or IX. It is marketed under brand names such as NovoSeven (developed by ), first approved by the in 1999, and Sevenfact (developed by LFB S.A. and approved by the FDA in 2020), both for hemophilia patients with inhibitors. Sevenfact is indicated for patients aged 12 years and older, while NovoSeven has broader approvals including congenital factor VII deficiency and acquired hemophilia. The mechanism of action of rFVIIa involves binding to exposed at sites of vascular injury, forming a complex that activates to factor Xa and to factor IXa, thereby initiating the extrinsic coagulation pathway and promoting thrombin generation for clot formation. This bypassing activity allows rFVIIa to restore independently of factors VIII and IX, making it effective in inhibitor-related scenarios. Approved indications also include management in congenital factor VII deficiency and acquired hemophilia. Dosing varies by indication and product; for hemophilia A or B with inhibitors, it is typically 90 μg/kg every 2 hours with NovoSeven until is achieved. Beyond its labeled uses, rFVIIa has been employed off-label for severe bleeding in non-hemophilic conditions, such as trauma, , , and reversal of anticoagulant-associated bleeding, though evidence for these applications varies and thrombotic risks must be considered. Developed through technology in mammalian cell lines to avoid human plasma-derived pathogens, rFVIIa represents a key advancement in hemophilia , with over two decades of global clinical use demonstrating efficacy in reducing transfusion requirements and improving outcomes in refractory bleeding. Safety concerns include rare thrombotic events (incidence <1:10,000 exposures), particularly in patients with underlying cardiovascular disease, necessitating careful monitoring.

History and development

Discovery

In the early 1970s, hematologist Ulla Hedner at the University of Lund in Sweden began investigating the procoagulant properties of activated factor VII (FVIIa) as a potential treatment for bleeding disorders in hemophilia patients who had developed inhibitors to factors VIII or IX. These inhibitors rendered standard replacement therapies ineffective, leaving patients vulnerable to life-threatening hemorrhages. Hedner's observations stemmed from studies of prothrombin complex concentrates (PCCs), which unexpectedly restored hemostasis in such patients despite containing trace amounts of FVIIa; she hypothesized that FVIIa could circumvent the need for the inhibited factors by directly activating downstream coagulation pathways. Key experiments in the late 1970s and early 1980s substantiated this mechanism. In vitro assays and animal models, including studies on hemophilic dogs, demonstrated that FVIIa, in the presence of tissue factor, could activate factor X independently of factors VIII and IX, thereby generating thrombin and promoting clot formation at sites of vascular injury. These findings built on earlier speculations from 1979 collaborations with researchers like Earl Davie and Sam Rapaport, who linked elevated FVIIa in PCCs to their clinical efficacy. Hedner's work emphasized FVIIa's localized action, minimizing systemic risks compared to other bypassing agents like activated PCCs, which carried higher thrombotic potential. Initial clinical studies with plasma-derived FVIIa commenced in the 1980s, marking proof-of-concept for its hemostatic utility. In 1980, Hedner and Walter Kisiel administered purified human FVIIa to two hemophilia A patients with high-titer inhibitors during bleeding episodes; intravenous doses as low as 18–35 μg/kg achieved rapid hemostasis without adverse effects, confirming the bypass capability in humans. Subsequent small-scale trials in the mid-1980s involving inhibitor patients further validated efficacy, with response rates around 60–70% for mild to moderate bleeds, though production challenges limited scalability. The transition from plasma-derived to recombinant FVIIa was driven by escalating safety concerns over viral transmission in plasma products during the 1980s HIV and hepatitis epidemics, which infected many hemophilia patients via contaminated concentrates. Purification of FVIIa from plasma was technically demanding and costly, yielding low quantities prone to pathogen risks despite emerging viral inactivation methods. In June 1986, Novo Nordisk initiated recombinant production using baby hamster kidney cells transfected with the human FVII gene, ensuring a virus-free, scalable alternative that retained full biological activity.

Clinical development and approval

Development of recombinant factor VIIa (rFVIIa) was initiated by Novo Nordisk A/S in Denmark in June 1986, with the human FVII gene cloned and expressed in baby hamster kidney (BHK) cells to produce the active form for therapeutic use. This recombinant approach aimed to provide a safer alternative to plasma-derived products, avoiding risks associated with blood-borne pathogens. Production involved secretion of single-chain FVII from BHK cells, followed by purification and activation to rFVIIa during processing. Key phase I/II trials in the early 1990s evaluated the safety and efficacy of rFVIIa in patients with hemophilia A or B and inhibitors, focusing on dose-finding for hemostatic control. These studies, involving previously treated patients, tested bolus doses ranging from 35 to 90 mcg/kg every 2-3 hours, demonstrating effective bleeding resolution in joint, muscle, and mucocutaneous episodes without significant immunogenicity. For surgical settings, randomized comparisons confirmed higher doses (90 mcg/kg) achieved better hemostasis rates (100% satisfactory at 48 hours) compared to lower doses (73%). The European Medicines Agency (EMA) granted marketing authorization for rFVIIa (NovoSeven) on February 23, 1996, for treating bleeding episodes and preventing hemorrhage in surgery for hemophilia A or B patients with inhibitors. The U.S. Food and Drug Administration (FDA) approved it on March 25, 1999, under the same indications, marking its availability as the first bypassing agent for inhibitor patients. Subsequent regulatory expansions broadened rFVIIa's indications. In 2005, the FDA approved its use for bleeding episodes and perioperative management in congenital factor VII deficiency, based on data from 70 treated patients showing effective hemostasis at doses of 15-30 mcg/kg. The EMA approved use in in 2004, and the FDA followed in July 2014 for patients with refractoriness to platelets, with or without antibodies, supported by registry data on over 200 bleeding episodes. In the 2010s, biosimilars of rFVIIa emerged, particularly in Asia and emerging markets, to enhance accessibility. For instance, AryoSeven, a biosimilar to NovoSeven, received approval in Iran in 2012, demonstrating comparable efficacy and safety in treating acute joint bleeds in hemophilia patients with inhibitors. These developments included approvals in countries like India and South Korea, where local manufacturers produced versions with similar pharmacokinetic profiles, though no biosimilars were centrally approved in Europe or the U.S. by the end of the decade. In parallel, French company LFB S.A. developed an alternative recombinant product, Sevenfact (coagulation factor VIIa (recombinant)-jncw), produced in rabbit mammary gland cell lines; it received FDA approval on April 6, 2020, for treating and controlling bleeding episodes in patients with hemophilia A or B with inhibitors. In April 2022, the EMA extended approval of NovoSeven for the treatment of severe postpartum haemorrhage in adults when standard therapy fails.

Pharmacology

Structure and properties

Recombinant factor VIIa (rFVIIa) is a vitamin K-dependent glycoprotein consisting of 406 amino acids with a molecular weight of approximately 50 kDa. It features a modular structure comprising a γ-carboxyglutamic acid (Gla) domain at the N-terminus, two epidermal growth factor-like (EGF) domains, and a C-terminal serine protease domain responsible for its catalytic activity. The Gla domain contains 10 γ-carboxyglutamic acid residues that enable calcium-dependent binding to phospholipid membranes, facilitating localization to sites of vascular injury. rFVIIa is produced recombinantly by expressing the human factor VII gene in mammalian expression systems; for example, baby hamster kidney (BHK) cells for NovoSeven or the mammary glands of genetically engineered rabbits for Sevenfact. These production methods undergo post-translational modifications essential for functionality. These modifications include N- and O-linked glycosylation at specific asparagine and serine/threonine residues, as well as vitamin K-dependent γ-carboxylation of glutamic acid residues in the Gla domain, which are critical for the protein's calcium-binding affinity and membrane interaction. Glycosylation patterns may vary by production method but do not significantly affect functionality. The production process avoids the use of human plasma or added human proteins, minimizing risks of viral transmission and immunogenicity. The zymogen form, factor VII, is a single-chain molecule that is activated to rFVIIa through proteolytic cleavage at the Arg152-Ile153 bond, yielding a light chain (residues 1-152) and a heavy chain (residues 153-406) linked by a disulfide bond. This activation exposes the active site in the serine protease domain, enabling catalytic function in the coagulation cascade. In recombinant production, this cleavage occurs via autocatalysis during purification. For clinical use, rFVIIa is formulated as a sterile, lyophilized powder in single-use vials, which is reconstituted for intravenous administration. Formulations vary by product; for example, NovoSeven is reconstituted with a histidine-based diluent and remains active for up to 3 hours at room temperature, while Sevenfact uses sterile water for injection. Both contain no preservatives or human-derived components. Detailed formulations are described in the Formulations section.

Mechanism of action

Recombinant factor VIIa (rFVIIa) initiates hemostasis by binding to exposed tissue factor (TF) at sites of vascular injury, forming the TF-FVIIa complex that activates factor X (FX) to FXa, thereby initiating the extrinsic coagulation pathway. This complex, in association with factor Va, generates initial traces of FXa and thrombin, which activate platelets and provide a procoagulant surface for further amplification. In conditions such as hemophilia with inhibitors to factors VIII or IX, rFVIIa bypasses the intrinsic pathway by directly activating FX on the surface of activated platelets in a TF-independent manner, enhancing thrombin generation at the injury site. This platelet-dependent activity restores the propagation phase of coagulation, promoting localized clot formation without requiring the inhibited factors. The coagulation process is amplified through a feedback loop involving FVIIa and FXa, which leads to a burst of thrombin production, subsequent fibrin formation, and further platelet activation, all confined to the site of injury to avoid systemic hypercoagulability. Thrombin activates factor XI and additional platelets, while FXa with Va sustains the prothrombinase complex, ensuring stable hemostatic plug development. The effects of rFVIIa are dose-dependent: at low doses, activity primarily relies on TF exposure for efficient FX activation, whereas supraphysiological doses enable robust TF-independent activation on platelet surfaces, enhancing overall thrombin generation. This dose responsiveness allows tailored hemostatic support based on the severity of bleeding and availability of TF.

Pharmacokinetics

Recombinant factor VIIa is administered intravenously, typically as a bolus injection or continuous infusion for certain clinical scenarios. Pharmacokinetic parameters vary slightly by product. For NovoSeven, following administration, the drug exhibits rapid distribution, characterized by an initial (alpha) half-life of approximately 0.3 hours and a terminal half-life of 2.3 to 3.5 hours in adults with hemophilia A or B; for Sevenfact, the terminal half-life is approximately 1.6 hours. The pharmacokinetics demonstrate dose proportionality across the range of 17.5 to 90 mcg/kg, with near-complete bioavailability of approximately 100% via the intravenous route. Clearance occurs primarily in the liver through receptor-mediated endocytosis, including involvement of low-density lipoprotein receptor-related protein 1 (LRP1), and remains independent of dose, leading to no accumulation with repeated dosing when intervals exceed the half-life. For NovoSeven, in pediatric patients aged 2 to 12 years, clearance is higher at approximately 58 mL/h/kg compared to 31 to 39 mL/h/kg in adults, resulting in a slightly shorter terminal half-life of about 2.6 hours; limited data exist for younger patients with other products. No significant pharmacokinetic alterations are observed in patients with renal impairment, and no dose adjustments are required.

Medical uses

Approved indications

Recombinant factor VIIa (rFVIIa) is approved by the U.S. Food and Drug Administration (FDA) for the treatment and management of bleeding in specific congenital and acquired coagulation disorders, primarily through its bypassing activity on the extrinsic coagulation pathway. The primary formulations, NovoSeven RT and Sevenfact, share indications for hemophilia but differ in age restrictions and additional uses. For patients with hemophilia A or B who have developed inhibitors to factor VIII or IX, NovoSeven RT is indicated for the treatment of bleeding episodes, perioperative management to prevent bleeding during surgery or invasive procedures, and routine prophylaxis to reduce the frequency of bleeding events; recommended dosing is 90 mcg/kg administered intravenously every 2 hours until hemostasis is achieved, followed by dosing every 3 to 6 hours for severe cases. Sevenfact is similarly approved for the treatment and control of bleeding episodes and perioperative management to prevent or control bleeding during surgery or invasive procedures in adolescents and adults aged 12 years and older with hemophilia A or B with inhibitors, with dosing starting at 75 mcg/kg every 3 hours for mild or moderate bleeds or 225 mcg/kg initially followed by 75 mcg/kg every 2 hours for severe bleeds, adjusted based on response. In congenital factor VII deficiency, NovoSeven RT is approved for the treatment of bleeding episodes and prevention of bleeding during perioperative settings, including routine prophylaxis; dosing typically ranges from 15 to 30 mcg/kg every 4 to 6 hours until hemostasis. NovoSeven RT is suitable for patients of all ages in this indication. For Glanzmann's thrombasthenia, a rare platelet disorder, NovoSeven RT is indicated for the treatment of bleeding episodes and perioperative bleeding prevention in patients refractory to platelet transfusions, with or without antiplatelet antibodies; dosing is 90 mcg/kg every 2 hours until hemostasis, extendable to every 2 to 6 hours. This approval applies to patients across all age groups. NovoSeven RT is also approved for the treatment of bleeding episodes and perioperative management in adults with acquired hemophilia due to autoantibodies against factor VIII; dosing follows a regimen of 70 to 90 mcg/kg every 2 to 3 hours until hemostasis. Sevenfact is not approved for congenital factor VII deficiency, Glanzmann's thrombasthenia, or acquired hemophilia.

Off-label uses

Recombinant factor VIIa (rFVIIa) has been employed off-label in the management of trauma-induced coagulopathy, particularly in cases of massive hemorrhage unresponsive to conventional therapies. Observational studies indicate that administration of rFVIIa at doses of 90 to 120 mcg/kg intravenously, often as a single dose after significant blood product transfusion (e.g., post-20 units of red blood cells), can reduce transfusion requirements and blood loss. For instance, in blunt trauma patients, low-dose rFVIIa (approximately 200 mcg/kg cumulatively) was associated with a significant decrease in red blood cell transfusions (by about 2.6 units) compared to placebo, without altering mortality rates. However, randomized trials such as the CONTROL study have shown mixed results, with reduced need for massive transfusions but no improvement in survival, alongside an elevated risk of thromboembolic events. In intracerebral hemorrhage, early off-label use of rFVIIa aims to limit hematoma expansion. The FAST trial demonstrated that a single intravenous dose of 80 mcg/kg administered within 4 hours of symptom onset significantly reduced hematoma volume growth (by 3.8 ml compared to placebo) at 24 hours, though it did not enhance 90-day survival or functional outcomes. Mortality remained around 20% across groups, and poor functional outcomes (severe disability or death) occurred in 24% to 29% of patients. Arterial thromboembolic events, such as myocardial infarction or cerebral infarction, were more frequent with the 80 mcg/kg dose (9% versus 4% in placebo). Despite these findings, rFVIIa is not routinely recommended due to the lack of clinical benefit outweighing thrombotic risks. For surgical bleeding, rFVIIa serves as an adjunct in refractory cases during cardiac or liver procedures. In cardiac surgery, doses of 60 to 90 mcg/kg intravenously, given intraoperatively or postoperatively, have been reported to control intractable hemorrhage and decrease blood product utilization in observational series, with mean doses around 56 mcg/kg leading to hemostasis in most patients. Similarly, in liver surgery or transplantation, rFVIIa at 90 to 120 mcg/kg has shown efficacy in reducing intraoperative blood loss and transfusion needs in small studies, particularly for patients with coagulopathy from cirrhosis. Evidence from systematic reviews supports its role in major surgical bleeding, though randomized data are limited and inconsistent regarding overall morbidity reduction. Off-label application of rFVIIa in postpartum and obstetric bleeding is reserved for refractory cases after standard measures fail. Case series and reviews report success rates of approximately 85% to 90% in arresting severe postpartum hemorrhage with doses of 60 to 90 mcg/kg intravenously, often as a single or repeated administration, reducing the need for invasive interventions like hysterectomy. A systematic review of over 200 cases found median dosing at 71.6 mcg/kg effectively stopped or reduced bleeding in nearly 90% of instances, with limited randomized evidence but supportive observational data. However, thromboembolic complications, including deep vein thrombosis, have been noted in up to 4% of treated patients. Despite these applications, rFVIIa is not recommended as a first-line therapy for off-label indications due to the substantial risk of thrombosis. Guidelines emphasize cautious use only in life-threatening hemorrhage refractory to other hemostatic agents, with the National Advisory Committee on Blood and Blood Products (2024) highlighting that off-label administration carries a significant thrombotic risk that may negate benefits, particularly in patients with predisposing factors. Recent consensus statements underscore the need for individualized risk assessment, as arterial and venous events occur at rates of 1% to 9% in off-label settings, outweighing unproven survival advantages in most scenarios.

Safety and tolerability

Adverse effects

Recombinant factor VIIa (rFVIIa) is generally well-tolerated in approved indications, with common adverse effects occurring at rates exceeding 1% primarily consisting of headache, nausea or vomiting, injection site reactions such as pain or hematoma, fever, and dizziness. These effects are typically mild and transient, observed in clinical trials for hemophilia patients with inhibitors, where fever affected approximately 4% of treatment episodes and headache was reported in isolated cases. Serious adverse effects include thrombotic events, which are more frequent with off-label use compared to approved indications. In randomized clinical trials across various indications involving over 4,400 participants, thromboembolic events occurred in 10.2% of rFVIIa-treated patients, with arterial events (such as stroke or myocardial infarction) at 5.5% versus 3.2% in placebo groups, particularly elevated in elderly patients (≥65 years) at 9% versus 3.8%. Venous thrombotic events, including deep vein thrombosis and pulmonary embolism, showed no significant increase (5.3% versus 5.7% in placebo). However, in patients with pulmonary embolism experiencing bleeding (e.g., due to anticoagulation), the use of rFVIIa carries significant thrombosis risks, including potential worsening of the pulmonary embolism or formation of new venous or arterial clots; it should be reserved for desperate situations following multidisciplinary discussion with hematology and critical care specialists. Risk factors for these events encompass high doses (>120 μg/kg), advanced age, and underlying comorbidities; in approved hemophilia A or B uses with inhibitors, the incidence is lower at approximately 0.11% as of 2023 data from clinical trials and post-marketing surveillance. A 2023 review reported an overall thrombotic event incidence of 0.17% across all approved indications. Post-marketing surveillance from 1999 to 2004 identified 185 thrombotic events in 168 patients, with 54% arterial and 40% venous, predominantly in off-label settings like trauma or ; more recent advisories as of 2024 emphasize significant risk outside labeled uses. Hypersensitivity reactions are rare, with anaphylaxis reported in isolated post-marketing cases (estimated <0.1%), more likely with repeated exposure; symptoms may include rash, hypotension, flushing, or urticaria. Other effects include hypertension and arthralgia, noted infrequently in clinical use without specific incidence data exceeding 1%. Unlike factor VIII products, there is no evidence of inhibitor development against rFVIIa in hemophilia A or B patients with inhibitors, though rare inhibitor development has been reported in congenital factor VII deficiency patients.

Contraindications and precautions

Recombinant factor VIIa (rFVIIa) is contraindicated in patients with known to the active substance, excipients, or proteins derived from the production process, such as mouse, hamster, bovine, or proteins depending on the formulation. For example, Sevenfact is specifically contraindicated in individuals with severe to proteins. Although not formally listed as an absolute contraindication in all prescribing information, rFVIIa should generally be avoided in cases of (DIC) without associated , as it may exacerbate thrombotic complications. Relative precautions are advised in patients with a history of thrombotic events, such as recent or , due to the potential for serious arterial or venous . Caution is also recommended for elderly patients, who may face heightened risk, and in those with advanced atherosclerotic disease, , or septicemia, where extensive expression could amplify procoagulant effects. Concurrent use with anticoagulants requires careful evaluation, as it may complicate hemostatic balance. During pregnancy, rFVIIa is classified as FDA C, with limited data available; animal studies indicate potential fetal mortality at high doses but no teratogenicity, and use should only occur if the potential benefit justifies the risk to the . For , there is no information on in , so a decision to continue or therapy should weigh the benefits against potential risks to the . Monitoring strategies include regular assessment of and clinical signs of , such as or dyspnea, particularly in at-risk patients. Coagulation parameters like (PT) and activated (aPTT) should be evaluated, though they may not fully predict efficacy; in factor VII-deficient patients, monitoring for factor VII activity and formation is essential. Drug interactions that increase thrombosis risk include concomitant administration with activated prothrombin complex concentrates (aPCCs), prothrombin complex concentrates (PCCs), or recombinant factor XIII (rFXIII), which should be avoided. Limited data exist on interactions with , but caution is warranted. Thrombotic adverse events, as noted in safety profiles, underscore the need for vigilant monitoring in these scenarios.

Formulations

NovoSeven

NovoSeven is the proprietary brand name for the original recombinant activated factor VIIa (rFVIIa), also known as eptacog alfa (activated), developed and manufactured by . It was introduced as the first rFVIIa therapy, receiving approval in the on February 23, 1996, and in the United States on March 25, 1999, initially for treating bleeding episodes in patients with hemophilia A or B who have inhibitors to factors VIII or IX. Over its history, NovoSeven has expanded indications to include perioperative management in hemophilia patients with inhibitors, treatment of bleeding in congenital factor VII deficiency, control of bleeding in refractory to platelet transfusions, and acquired hemophilia, with approvals encompassing all age groups, including pediatrics from birth (0 years). The product is produced through recombinant DNA technology, where the human coagulation factor VII gene is cloned and expressed in baby hamster kidney (BHK) cells, followed by activation to rFVIIa and purification to yield a sterile, lyophilized powder. NovoSeven is supplied in single-dose vials containing 1 mg (50,000 IU), 2 mg (100,000 IU), 5 mg (250,000 IU), or 8 mg (400,000 IU) of rFVIIa, accompanied by a of sterile water for injections with histidine; the formulation includes excipients such as , dihydrate, glycylglycine, , , , and , but contains no preservatives. After reconstitution with the provided , it forms a clear, colorless solution at approximately 1 mg/mL, suitable for immediate intravenous bolus administration without infusion sets. For bleeding episodes in approved indications, the standard dosing regimen is 90 mcg/kg administered as an intravenous bolus every 2 hours until is achieved, then adjusted to every 3-6 hours based on severity; in hemophilia with inhibitors, a single 270 mcg/kg dose may be used for mild bleeds. This dosing applies across all ages, including neonates and infants, with no differences in safety or effectiveness observed from 0 to 16 years. NovoSeven's advantages include a extensive clinical track record spanning over 25 years, with millions of doses administered worldwide, supporting its established safety and efficacy profile in diverse scenarios. However, as of 2025, intermittent shortages and limited availability have occurred in some countries due to issues. The NovoSeven RT () formulation, approved by the FDA in 2008, enhances by allowing storage at up to 25°C (77°F) without prior to reconstitution, while post-reconstitution stability permits use within 3 hours at or 24 hours refrigerated. In the , formulation updates focused on ease of use, including the 2010 FDA approval of an 8 mg vial size to reduce injection frequency for higher-dose needs and a compact mix-and-inject kit that simplifies reconstitution and administration in under 2 minutes, improving patient compliance during on-demand treatment.

Sevenfact (coagulation factor VIIa (recombinant)-jncw)

Sevenfact (coagulation factor VIIa (recombinant)-jncw), also known as eptacog beta, is a recombinant bypassing agent developed by LFB S.A., a French biopharmaceutical company, and commercialized in the United States by HEMA Biologics, LLC. It received U.S. (FDA) approval on April 1, 2020, marking the first new bypassing agent for hemophilia patients with inhibitors in over two decades. The product is manufactured using technology in genetically engineered rabbits, where the human factor VII gene is expressed in the mammary glands and secreted into milk, followed by enzymatic conversion to activated factor VIIa during purification. This rabbit-derived production method differs from cell-line-based approaches used in earlier recombinant factor VIIa products. Sevenfact is supplied as a lyophilized in single-use vials containing 1 mg, 2 mg, or 5 mg of the , with a co-packaged 3 mL sterile pre-filled glass syringe (added in 2024); excipients include arginine hydrochloride, , , lysine hydrochloride, , dihydrate, and for stabilization and reconstitution. The supports room-temperature storage (2°C to 30°C) for up to 36 months, enhancing practical compared to some predecessors requiring . It is indicated for the treatment and control of bleeding episodes in adults and adolescents aged 12 years and older with hemophilia A or B who have developed inhibitors to or IX. Dosing is typically 75 mcg/kg intravenously every 3 hours for mild or moderate bleeds, or an initial 225 mcg/kg followed by 75 mcg/kg every 2-3 hours for severe bleeds, adjusted based on clinical response and bleed severity. Clinical trials, including the phase 3 PERSEPT 1 and PERSEPT 2 studies, demonstrated hemostatic rates of 88.7% at 12 hours and 97.8% at 24 hours for treated bleeds, with a profile showing no thrombotic events or new inhibitor development in most participants, though one case of was noted. These results indicate comparable and to earlier recombinant factor VIIa products like NovoSeven, with potentially lower due to the novel production process, though variations in responses remain a monitored . As a non-interchangeable biologic, Sevenfact offers potential savings through competitive , estimated at 46-72% lower per treatment episode in some analyses. Its , including a of approximately 3-4 hours, are broadly similar to reference products. Initially launched in the United States, Sevenfact (marketed as Cevenfacta in ) gained approval in 2022 and has expanded to and , with ongoing efforts for broader global availability projected through 2025 to address unmet needs in hemophilia care.

Society and culture

Recombinant factor VIIa, marketed primarily as NovoSeven, received initial approval from the (EMA) in 1996 for treating and preventing in hemophilia A or B patients with inhibitors to factors VIII or IX. The U.S. () approved it on March 25, 1999, for treatment of episodes in patients with hemophilia A or B with inhibitors. It was later approved for episodes in congenital factor VII deficiency on July 11, 2005, and for acquired hemophilia on October 13, 2006. In 2023, the added recombinant factor VIIa to its Model List of (23rd list), underscoring its role in managing severe disorders globally. The product is available in over 90 countries, including major markets in , , , and the . Key patents for NovoSeven expired in the in November 2010 and in December 2014, facilitating the development and approval of . This patent landscape shift enabled the FDA approval of Sevenfact ( factor VIIa [recombinant]-jncw) on April 1, 2020, as the first new bypassing agent for hemophilia with inhibitors in over two decades. In , the AryoSeven was approved for marketing around 2014, providing a lower-cost alternative for local patients with hemophilia and inhibitors. Access to recombinant factor VIIa remains challenged by its high cost, typically ranging from $1 to $3 per depending on formulation and market, which can exceed $10,000 for a single treatment dose in adults. Patient assistance programs, such as Novo Nordisk's NovoCare offerings, provide financial support and free medication to eligible uninsured or underinsured individuals to improve affordability. Shortages have occurred intermittently in the , including a manufacturing-related supply disruption for NovoSeven affecting multiple countries in 2024 and limited availability in several member states persisting into 2025 due to increased demand. No major regulatory withdrawals have been issued for approved recombinant factor VIIa products as of 2025.

Military use

Recombinant factor VIIa (rFVIIa) was initially adopted by the military in the early 2000s for managing combat-related hemorrhage during Operations Iraqi Freedom and Enduring Freedom. Military physicians began using it off-label to control life-threatening bleeding in trauma patients, with early reports from 2004 documenting its administration in settings. By 2005, rFVIIa was incorporated into the (TCCC) guidelines as an option for in massively transfused casualties, reflecting its perceived potential to enhance in austere environments. Clinical data from military registries indicated that rFVIIa, typically administered at doses of 200 mcg/kg, reduced transfusion requirements in trauma. For instance, early administration was associated with a 20% decrease in use among patients needing massive transfusions and a reduction in 30-day mortality for severely injured casualties. These findings supported its role in decreasing blood loss by 30-50% in select cases of hemorrhage, though results were inconsistent across studies. In the 2010s, controversies arose over rFVIIa's off-label use in military trauma due to emerging evidence of thromboembolic risks. The FDA added a black-box warning to the NovoSeven label in 2011, highlighting serious arterial thrombotic events associated with high-dose off-label applications, particularly in older patients or those with comorbidities. Additionally, its high cost—approximately $30,000–$40,000 for a trauma dose in an adult—and logistical challenges, such as the need for reconstitution and cold storage in field conditions, limited its practicality in combat zones. As of 2025, US Department of Defense (DoD) protocols under updated TCCC guidelines restrict rFVIIa to refractory cases of unresponsive to standard measures, with now preferred as first-line therapy for hemorrhagic shock due to its proven efficacy and lower risk profile. Internationally, forces have explored rFVIIa for pre-hospital hemorrhage control, but its adoption remains selective amid ethical concerns over resource allocation in resource-limited deployments, where high costs may divert funds from broader casualty care needs.

Research

Ongoing clinical trials

As of 2025, several phase III clinical trials have investigated recombinant factor VIIa (rFVIIa) for prophylaxis in with hemophilia A or B and inhibitors, focusing on preventing excessive during elective major procedures. The SCOPE-HIM trial (NCT05695391), an international, multicenter, single-arm study, evaluated the safety and of rFVIIa at doses of 200–300 mcg/kg for hemostatic coverage in adolescents and adults undergoing surgery, with primary outcomes including hemostatic rated by surgeons and adverse events; the trial began enrollment in June 2024 but was terminated due to feasibility considerations with extended recruitment timelines. This builds on prior completed phase III prophylaxis studies, such as NCT02020369, which demonstrated reduced bleed rates with weekly dosing regimens of 75–225 mcg/kg in similar populations, though that trial concluded in 2023. In the area of intracerebral hemorrhage (ICH), the FASTEST trial (NCT03496883), a global phase III, randomized, double-blind, placebo-controlled study, is actively assessing rFVIIa administered at 80 mcg/kg within 8 hours of symptom onset compared to standard care plus placebo in adults aged 18–80 with acute spontaneous ICH. Primary endpoints include hematoma expansion at 24 hours and functional outcomes at 180 days, with interim analyses showing feasibility for rapid administration; recruitment continues across multiple sites in 2025. This trial addresses limitations from earlier phase IIb studies by targeting earlier intervention to potentially limit hematoma growth and improve neurological recovery. Pediatric expansions for rFVIIa formulations, particularly Sevenfact (coagulation factor VIIa [recombinant]-jncw), are under evaluation in ongoing trials for children under 12 years with hemophilia and inhibitors. A phase IV study (NCT04647227) is recruiting to assess the safety and tolerability of Sevenfact for treating events in pediatric and patients, including those as young as 0–17 years, with dosing at 75–225 mcg/kg and monitoring for thrombotic events; enrollment is ongoing as of November 2025. Combination therapies involving rFVIIa with for hemophilia patients with inhibitors are being explored in safety and efficacy studies, though dedicated phase II trials remain limited. Ongoing phase III and IV investigations, such as the Sevenfact bleeding events trial, indirectly include patients on prophylaxis, evaluating rFVIIa for breakthrough bleeds at standard doses; the Medical and Scientific Advisory Council recommends rFVIIa as the preferred bypassing agent in this setting due to lower thrombotic risk compared to activated prothrombin complex concentrates. These efforts span 2023–2027, with emphasis on real-world hemostatic response rates exceeding 90% in combined regimens. Post-marketing safety registries provide long-term surveillance data on rFVIIa use. The Hemophilia and Research Society (HTRS) Registry, ongoing since the early 2000s, collects prospective data on all NovoSeven administrations for episodes and prophylaxis in hemophilia patients, reporting low rates of adverse events like (less than 1%) across thousands of exposures as of 2025. An international (NCT01312636), completed in patients with congenital FVII deficiency, monitored and , with data confirming consistent tolerability profiles.

Future developments

Research into modified variants of recombinant factor VIIa (rFVIIa) focuses on extending its to improve prophylactic efficacy in hemophilia patients with inhibitors. One promising approach involves fusion proteins, such as rFVIIa fused with (rFVIIa-FP), which demonstrates an extended of approximately 10-12 hours compared to the standard 2-3 hours for unmodified rFVIIa, while maintaining hemostatic activity in preclinical models. CSL Behring's rFVIIa-FP (CSL689) completed early clinical phases (phase I/II) starting in 2015, showing pharmacokinetic benefits in patients with congenital factor VII deficiency, though no recent phase II or III advancements have been confirmed as of 2025. Similarly, Fc-fusion variants like rFVIIa-Fc have shown prolonged circulation in , supporting ongoing development for reduced dosing frequency. Synergies between rFVIIa and represent an emerging strategy for treating congenital factor VII deficiency, a rare bleeding disorder. Preclinical studies have demonstrated that (AAV) vectors encoding the FVII gene can achieve sustained expression of functional factor VII, potentially complementing rFVIIa administration to bridge gaps in acute bleeding management until effects stabilize. For instance, AAV8-mediated delivery in FVII deficiency models resulted in high-level, long-term FVII expression without issues, suggesting potential for combined regimens in clinical translation. These approaches aim to address limitations in current replacement therapies by providing durable endogenous production. Exploration of rFVIIa for new indications includes sepsis-induced and cancer-associated , where early-phase data indicate hemostatic potential. These developments build on ongoing clinical trials evaluating rFVIIa in expanded settings. expansions are anticipated to enhance access to rFVIIa, particularly in Asian markets by 2027. In , Sino Biopharm's recombinant human factor VIIa (N01), approved in July 2025, reported significant sales growth in the first half of 2025, offering a cost-effective alternative to branded products like NovoSeven. Projections indicate that additional biosimilars from regional manufacturers will enter markets in and , potentially lowering treatment costs by 30-50% and improving availability for hemophilia care in resource-limited settings. Addressing thrombosis risks remains a key challenge in rFVIIa advancement, with targeted delivery systems under laboratory investigation to enhance specificity. Preclinical innovations aim to mitigate the <1% incidence of thrombotic events observed in rFVIIa use.

References

  1. https://www.fda.gov/media/70435/download
  2. https://www.accessdata.fda.gov/scripts/opdlisting/oopd/detailedIndex.cfm?cfgridkey=26588
  3. https://www.drugs.com/history/sevenfact.html
  4. https://www.fda.gov/vaccines-blood-biologics/sevenfact
  5. https://pmc.ncbi.nlm.nih.gov/articles/PMC4921516/
  6. https://pubmed.ncbi.nlm.nih.gov/37391649/
  7. https://pubmed.ncbi.nlm.nih.gov/20188400/
  8. https://www.jci.org/articles/view/110939
  9. https://www.sciencedirect.com/science/article/pii/S0268960X15300023
  10. https://www.hematology.org/about/history/50-years/hemophilia
  11. https://pubmed.ncbi.nlm.nih.gov/20609014/
  12. https://www.ema.europa.eu/en/medicines/human/EPAR/novoseven
  13. https://www.accessdata.fda.gov/scripts/opdlisting/oopd/detailedIndex.cfm?cfgridkey=185904
  14. https://www.fda.gov/media/70442/download
  15. https://pmc.ncbi.nlm.nih.gov/articles/PMC11283401/
  16. https://www.researchgate.net/publication/371966165_Current_status_and_future_prospects_of_activated_recombinant_coagulation_factor_VIIa_NovoSevenR_in_the_treatment_of_haemophilia_and_rare_bleeding_disorders
  17. https://journals.sagepub.com/doi/10.1177/1076029614555902
  18. https://www.frontiersin.org/journals/bioengineering-and-biotechnology/articles/10.3389/fbioe.2022.832059/full
  19. https://www.ema.europa.eu/en/news/meeting-highlights-committee-medicinal-products-human-use-chmp-16-19-may-2022
  20. https://pubmed.ncbi.nlm.nih.gov/10544046/
  21. https://pmc.ncbi.nlm.nih.gov/articles/PMC11847032/
  22. https://sevenfact.com/Sevenfact_PI.pdf
  23. https://pubmed.ncbi.nlm.nih.gov/26382581/
  24. https://pubmed.ncbi.nlm.nih.gov/10850558/
  25. https://pubmed.ncbi.nlm.nih.gov/12358603/
  26. https://ashpublications.org/blood/article/104/13/3858/18972/The-use-of-recombinant-factor-VIIa-in-the
  27. https://www.sciencedirect.com/science/article/pii/S1538783622158228
  28. https://onlinelibrary.wiley.com/doi/full/10.1046/j.1538-7836.2003.00225.x
  29. https://pmc.ncbi.nlm.nih.gov/articles/PMC2291262/
  30. https://pubmed.ncbi.nlm.nih.gov/27614059/
  31. https://www.fda.gov/media/163683/download
  32. https://www.novosevenrt.com/
  33. https://www.nejm.org/doi/full/10.1056/NEJMoa0707534
  34. https://jamanetwork.com/journals/jamasurgery/fullarticle/401634
  35. https://pubmed.ncbi.nlm.nih.gov/18393147/
  36. https://www.nejm.org/doi/full/10.1056/NEJMoa1006221
  37. https://cdn.mdedge.com/files/s3fs-public/Document/September-2017/037110572.pdf
  38. https://pmc.ncbi.nlm.nih.gov/articles/PMC10140848/
  39. https://jamanetwork.com/journals/jama/fullarticle/202213
  40. https://nacblood.ca/sites/default/files/2024-08/2024-07-17%2520NAC%2520Statement%2520on%2520Recombinant%2520Factor%2520VIIa.pdf
  41. https://www.rxlist.com/factor_viia_recombinant/generic-drug.htm
  42. https://www.ema.europa.eu/en/documents/product-information/novoseven-epar-product-information_en.pdf
  43. https://www.novo-pi.com/novosevenrt.pdf
  44. https://purplebooksearch.fda.gov/productdetails?query=103665
  45. https://www.ema.europa.eu/en/medicines/human/shortages/novoseven-eptacog-alfa
  46. https://www.ncbi.nlm.nih.gov/books/NBK98693/
  47. https://www.prnewswire.com/news-releases/fda-approves-8-mg-vial-of-novoseven-rt-for-the-treatment-of-hemophilia-a-or-b-with-inhibitors-and-enhanced-shelf-life-for-all-vial-sizes-100369339.html
  48. https://pubmed.ncbi.nlm.nih.gov/20586800/
  49. https://www.fda.gov/media/137275/download
  50. https://dailymed.nlm.nih.gov/dailymed/drugInfo.cfm?setid=b23ad666-8ce0-4e0b-9eff-c6983ac5f7e6
  51. https://www.fda.gov/media/189551/download
  52. https://hemophilianewstoday.com/news/hemophilia-bypassing-agent-sevenfact-lowers-bleeds-patients-inhibitors/
  53. https://www.groupe-lfb.com/lfb-content/uploads/2022/07/pr_approval_cevenfacta_europe_mexico_final-lfb.pdf
  54. https://synapse.patsnap.com/article/in-which-countries-is-sevenfact-approved
  55. https://academic.oup.com/milmed/article/173/11/1057/4265783
  56. https://pubmed.ncbi.nlm.nih.gov/18301188/
  57. https://ohsu.elsevierpure.com/en/publications/early-versus-late-recombinant-factor-viia-in-combat-trauma-patien-2
  58. https://www.nature.com/articles/nm0611-633
  59. https://ccforum.biomedcentral.com/articles/10.1186/cc3784
  60. https://tccc.org.ua/en/guide/damage-control-resuscitation-cpg
  61. https://jts.health.mil/assets/docs/cpgs/Damage_Control_Resuscitation_12_Jul_2019_ID18.pdf
  62. https://clinicaltrials.gov/study/NCT05695391
  63. https://clinicaltrials.gov/study/NCT02020369
  64. https://clinicaltrials.gov/study/NCT03496883
  65. https://clinicaltrials.gov/study/NCT04647227
  66. https://www.novomedlink.com/rare-bleeding-disorders/products/treatments/novosevenrt/efficacy-safety/breakthrough-bleeds.html
  67. https://globalrph.com/rx-list/novoseven-drug/
  68. https://clinicaltrials.gov/study/NCT01312636
  69. https://synapse.patsnap.com/article/what-clinical-trials-have-been-conducted-for-csl-689
  70. https://www.sciencedirect.com/science/article/pii/S153878362205156X
  71. https://link.springer.com/article/10.1007/s40259-015-0133-6
  72. https://pmc.ncbi.nlm.nih.gov/articles/PMC12282199/
  73. https://pubmed.ncbi.nlm.nih.gov/39990097/
  74. https://www.sciencedirect.com/science/article/pii/S2475037924003650
  75. https://firstwordpharma.com/story/5990238
  76. https://www.linkedin.com/pulse/china-recombinant-human-coagulation-viia-market-9hmye/
  77. https://biomarkerres.biomedcentral.com/articles/10.1186/s40364-023-00504-6
Add your contribution
Related Hubs
User Avatar
No comments yet.