Two Consecutive Invasive Surgeries Utilizing Zymogen Protein C (ZPC) That Enhanced Patient Safety and Reduced Costs.

This case report describes a major surgical procedure for a protein C-deficient, hypercoagulable patient who underwent two back-to-back invasive surgeries, hip replacement, and spinal stenosis correction. The patient, an 84-year-old male with a history of deep vein thromboses (DVT) and pulmonary emboli (PE), was treated pre-, peri-, and postoperatively with zymogen protein C (ZPC-Baxter, International) and recovered without clotting or increased bleeding. During the procedure, the patient was not administered any other anticoagulants. There have now been several case reports on different patients with unrelated teams in various locations worldwide using zymogen protein C during surgical procedures. Thus, this procedure is becoming a viable choice for patients with a high probability of clotting during and after invasive surgery. This case focuses on accomplishing safer surgery and reducing costs, by using less ZPC while accomplishing two surgeries in one procedure. As a result, this procedure might be useful for many medical situations where acquired protein C deficiency could be a problem (e.g., sepsis, pregnancy, etc.). This approach may have greater application to medical conditions other than protein C deficiency, where clotting and inflammation can become issues.

A Compelling Case for the Use of Perioperative Zymogen Protein C for Increased Patient Safety.

It is imperative to maintain normal blood flow to provide adequate oxygen supply to specific organs and cells, as well as for the removal of metabolic byproducts. Therefore, any situation that results in blood clotting can injure or kill living tissues. In this paper, we describe a case where a protein C deficient subject who would, by all medical indicators, be at 100 % risk of experiencing thrombophlebitis, deep vein thrombosis, and or lung emboli, is able to escape all pathologies by using perioperative zymogen protein C (ZPC). This protein C deficient patient has a long history of blood clotting, particularly from surgical procedures. The patient is 81 years old and first experienced clotting due to hernia surgery in 1964, when he was hospitalized for 16 days post-surgery with life threatening complications. It was later determined in 1980, after many episodes, that the patient had hereditary protein C deficiency at the 38 % level. In his hernia surgery, perioperative ZPC was used along with accepted anticoagulation procedures with no blood clots or other related side effects occurring. This procedure can greatly benefit protein C deficient patients, and could potentially find use for non-PC deficient patients in surgeries and a variety of other medical treatments. This particular case helps to validate the importance of ZPC in effecting safer surgery in high-risk patients. It also supports the mechanism of ZPC acting as an anticoagulant without causing bleeding. Most importantly, each clinical case study represents a unique combination of surgeon, hematologist, medical staff, and patient functioning as a coordinated team. In this case, smaller amounts of very expensive ZPC achieved safe and efficacious results, which is hugely important for future clinical applications when considering the production cost of ZPC. More studies must be done to establish minimum dosing while achieving safe and efficacious outcomes.

Pancreaticoduodenectomy using perioperative zymogen protein C to help prevent blood clotting: a trilogy on increased patient safety.

The blood clotting mechanism is a very important and complex physiologic process. Blood flow must be continuous through the blood vessels to provide essential oxygen and nutrients to the cells of the body. Dr. Melvin H. Knisely (Honorary First President of ISOTT, 1973) named and pioneered research in blood sludging and clotting which led to his nomination for the Nobel Prize by Dr. August Krogh in 1948. Abnormal clotting is a pathological state that can inhibit and prevent normal blood flow, leading to reduced oxygen transport to tissue from the microcirculation. It can result in the death of cells and tissues, including entire organs as well as the patient. Blood clotting and sludging are common occurrences during and after invasive surgery; thus, it is imperative to find safe procedures to reduce or prevent these deadly phenomena. All anticoagulants used today, for clot prevention and dissolution, can cause excessive bleeding that can lead to enormous medical expense to provide control, otherwise causing patient death. Protein C is a natural protein and is the pivotal anticoagulant in the blood. Due to the mechanism of converting the zymogen protein C (ZPC) to active protein C (APC), only when and where it is needed, and their respective half-lives in the body, the natural anticoagulant, antithrombotic characteristics of APC can be utilized without causing bleeds.

Zymogen Protein C to prevent clotting without bleeding during invasive medical procedures.

Thrombophilic disorders that predispose patients to develop blood clots can be life-threatening and result in a large economic burden on healthcare expenditures. Venous Thromboembolism(VTE) (deep vein thrombosis and pulmonary embolism) are the third leading cause of death in the United States. Protein C deficiency is a common thrombophilic condition that affects an estimated 1 in 400 Americans. Zymogen Protein C (ZPC) is the precursor to Activated Protein C (APC), a pivotal endogenous anticoagulant in human blood. Patients with protein C deficiency who have roughly half the normal level of protein C are estimated to be at 10-fold increased risk of VTE. We describe the use of protein C concentrate (Ceprotin®, Baxter, Deerfield, IL) in a patient with protein C deficiency and with a previous pulmonary embolism who developed a life-threatening gastrointestinal bleed after polypectomy. The patient is a 75-year-old male at very high risk for deep vein thrombosis and possible lung emboli. He has heterozygous Protein C deficiency (50%) and heterozygosity for the prothrombin gene G20210A mutation. During a routine colonoscopy, a large 3 cm cecal polyp was identified and resected. Eight days post-procedure while performing abdominal exercise he developed a life-threatening GI bleed originating from the polypectomy site as his warfarin was becoming therapeutic on a Low Molecular Weight Heparin (LMWH) periprocedural bridge. The patient's warfarin was reversed with vitamin K, and LMWH and warfarin were discontinued. To prevent thrombosis, he was started on ZPC until anticoagulation could be safely restarted. During endoscopy, the bleeding site was treated with an injection of 1:10,000 dilution of epinephrine, followed by cauterization and placement of endoclips (4 metal staples). Three days after endoscopic repair LMWH was restarted with warfarin. Sixteen months post-bleed, the patient remains on life-long warfarin without further episodes of bleeding or thrombosis. Zymogen Protein C concentrate (Ceprotin®, Baxter Deerfield, IL) should be strongly considered for peri-procedural management of any patient with protein C deficiency and previous thromboembolism.

Safer surgery using zymogen protein C concentrate.

This is the first case (November 12, 2007) of peri-operative use of zymogen protein C (ZPC) for a heterozygote Protein C deficient (50%) patient with heterozygosity for the prothrombin gene mutation. The surgery involved total left hip replacement. The patient was 74 years of age and at very high-risk for Deep Vein Thrombosis (DVT) thus possible lung emboli. He was a survivor of Venous thrombo-embolism (VTE) in 1999.For this case the need for increased heparin to prevent a reoccurrence of thrombosis led to a further concern of internal bleeding and possible infection. As proposed by the authors in previous publications the use of a ZPC concentrate would decrease the chance of a thrombosis, with minimum or no internal bleeding. ZPC is activated at the endothelium cell surface and on the surface of the platelets where and when it is needed, therefore providing a safer procedure.This protocol was implemented by administering ZPC concentrate 1 day prior to surgery and continuing for 10 days after. Slightly higher than normal blood loss occurred, however, a safe procedure was achieved without dangerous side effects while several additional benefits were experienced (level of PC activity as high as 235% above normal were measured during the procedure.). It is felt that positive effects were the result of increased blood flow and oxygen transport to the tissues by reducing blood sludging in the microcirculation. Further studies on Protein C dose levels will be necessary to provide economical, safe and efficacious use of Protein C products.It is suggested that ZPC should be considered for patients with high probability of VTE which could cause thrombotic occlusion of the pulmonary and peripheral vasculature. These phenomena can result in hypoxia and hypo perfusion causing organ failure and death.Our research includes a focused effort to optimize upstream and downstream bio-processing to produce both zymogen and activated Protein C at a lower cost and to examine the medical indications that could benefit from a more available and affordable Protein C product.

Protein C production: metal ion/protein interfacial interaction in immobilized metal affinity chromatography.

Protein C (PC) is an essential blood factor in the human blood coagulation cascade. PC can help achieve blood hemostasis in many deadly disease conditions such as sepsis, cancer, HIV, etc.; reduced oxygen transport due to blood agglutination within the body can cause tissue death and organ failure as a result of low oxygen transport. Our goal is to produce large quantities of low cost zymogen PC for the treatment and prevention of blood clotting resulting from many disease states, as well as provide an effective therapy for PC deficiency. Current studies show that Immobilized Metal Affinity Chromatography (IMAC) has high specificity and can be used for difficult separations among homologous proteins at relatively low cost compared to current methods, such as Immunoaffinity Chromatography. Thus, we are investigating the optimization of IMAC for the separation and purification of PC from Cohn fraction IV-I. Molecular interactions within the chromatography column involve many parameters that include: the use and type of chromatographic gel and buffer solution, the pH, temperature, metal ion, chelator, and the sequence and structure of the protein itself. These parameters all influence the protein's interaction with the column. Experimental equilibrium isotherms show that PC has primary and secondary binding characteristics, demonstrating that the interaction is not just a simple process of one protein binding to one metal ion. Understanding the thermodynamics of interfacial interaction between proteins and surface-bound Cu2+ is essential to optimizing IMAC for PC purification, as well as for separation of other proteins in general. Hence we are undertaking theoretical and experimental studies of IDA-Cu/PC adsorption. The differences in structures of PC and other critical homologous blood factors are examined using the protein visualization program Cn3D. A better understanding of the interfacial phenomena will help determine the most effective conditions to achieve our goal.

Polyphosphates and other phosphorus-containing polymers for drug delivery applications.

Poly(phosphate ester)s, polyphosphonates, and polyphosphazenes are three classes of phosphorus-containing polymers that have received wide attention over the past decade for their utility in biomedicine and tissue engineering. These three families of polymers can lead to a number of subclasses of polymers with varied properties. Significant research in this area has led to niche polymers with morphologies ranging from viscous gels to amorphous microparticles for utility in drug delivery. Furthermore, the pentavalency of phosphorus offers the potential for covalent linking of the drug. The classes of polymers discussed in this review are being explored in human clinical trials for vaccine delivery as well as delivery of oncolytic and CNS therapeutics. More applications in the areas of DNA delivery and tissue engineering are also being explored.