SBIR-STTR Award

Pheresis Treatment of Bioterrorism-Induced Sepsis
Award last edited on: 11/18/05

Sponsored Program
SBIR
Awarding Agency
NIH : NIAID
Total Award Amount
$1,011,543
Award Phase
2
Solicitation Topic Code
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Principal Investigator
Stephen R Ash

Company Information

Hemocleanse Inc

3601 Sagamore Parkway North Suite B
Lafayette, IN 47904
   (765) 742-9392
   inquiries@hemocleanse.com
   www.hemocleanse.com
Location: Single
Congr. District: 04
County: Tippecanoe

Phase I

Contract Number: 1R43AI058528-01
Start Date: 00/00/00    Completed: 00/00/00
Phase I year
2004
Phase I Amount
$504,669
Victims of bacterial bioterrorism agents such as anthrax, plague, and tularemia die very often because of septicemia and subsequent multiple organ dysfunction syndrome (MODS). Viral bioterrorism agents such as smallpox can also induce Systemic Inflammatory Response Syndrome (SIRS) and septic shock because of secondary bacterial infections. An effective therapy for SIRS and MODS would spare many of the victims of bioterrorism from a tragic death. Escalating evidence has implicated cytokines and cytokines mediators, circulating factors produced by the innate immune system, as critical mediators of sepsis-related tissue injury and death. To date, after much research and many clinical trials of drugs targeting individual sepsis mediators, no anti-inflammatory agent has been clinically approved. The goal of this project is to develop a simple extracorporeal sorbent-based pheresis system that can broadly diminish level of pro-inflammatory and anti-inflammatory sepsis mediators from plasma, and halt the downhill course of organ failure after sepsis. A novel treatment for sepsis has already been tested in Phase I clinical trials in patients with sepsis and multiple organ failure. This system, the Biologic-DTPF, consisted of a dialysis system (DT) and a pheresis system (PF) in series. In vitro studies indicated clearance of inflammatory sepsis mediators like TNF-alpha at 20- 25 ml/min for up to 6 hours, due entirely to adsorption by sorbent in the PF system. The Phase I trial indicated that one treatment of 2-6 hours with the DTPF system resulted in physiologic improvement in seven of eight patients with sepsis and multiple organ failure. Based on this Phase I trial, it appears that sorbent-based pheresis with powdered sorbent has the potential to alter cytokine concentrations in blood during therapy and improve the outcome of patients with sepsis and multiple organ failure. This therapy offers new promise in the field of immuno-modulation because it is both broad-spectrum (removing both pro and anti inflammatory compounds) and self-regulating by removing substances in relation to their circulating concentrations. This project will modify the PF extracorporeal pheresis system treatment by making it a stand-alone system. A new sorbent mixture will be developed and tested in the laboratory with a broad assortment of sepsis initiators and mediators. The means of contacting plasma and sorbent will be changed to improve the efficacy of the system. The anticoagulation method will be changed to regional citrate anticoagulation. The safety systems of the existing PF system will be modified to meet the needs of the stand-alone system. Finally, an animal model of sepsis will be used to check efficacy and safety of the entire system.

Thesaurus Terms:
bioterrorism /chemical warfare, blood disorder chemotherapy, blood treatment, plasmapheresis, septic shock, therapy design /development anticoagulant, bacterial disease, blood /lymphatic pharmacology, blood filtration, blood toxicology, cytokine, hemodialysis, hemodynamics, lipopolysaccharide, multiple organ failure, nonhuman therapy evaluation, secondary infection dog

Phase II

Contract Number: 5R43AI058528-02
Start Date: 00/00/00    Completed: 00/00/00
Phase II year
2005
Phase II Amount
$506,874
Victims of bacterial bioterrorism agents such as anthrax, plague, and tularemia die very often because of septicemia and subsequent multiple organ dysfunction syndrome (MODS). Viral bioterrorism agents such as smallpox can also induce Systemic Inflammatory Response Syndrome (SIRS) and septic shock because of secondary bacterial infections. An effective therapy for SIRS and MODS would spare many of the victims of bioterrorism from a tragic death. Escalating evidence has implicated cytokines and cytokines mediators, circulating factors produced by the innate immune system, as critical mediators of sepsis-related tissue injury and death. To date, after much research and many clinical trials of drugs targeting individual sepsis mediators, no anti-inflammatory agent has been clinically approved. The goal of this project is to develop a simple extracorporeal sorbent-based pheresis system that can broadly diminish level of pro-inflammatory and anti-inflammatory sepsis mediators from plasma, and halt the downhill course of organ failure after sepsis. A novel treatment for sepsis has already been tested in Phase I clinical trials in patients with sepsis and multiple organ failure. This system, the Biologic-DTPF, consisted of a dialysis system (DT) and a pheresis system (PF) in series. In vitro studies indicated clearance of inflammatory sepsis mediators like TNF-alpha at 20- 25 ml/min for up to 6 hours, due entirely to adsorption by sorbent in the PF system. The Phase I trial indicated that one treatment of 2-6 hours with the DTPF system resulted in physiologic improvement in seven of eight patients with sepsis and multiple organ failure. Based on this Phase I trial, it appears that sorbent-based pheresis with powdered sorbent has the potential to alter cytokine concentrations in blood during therapy and improve the outcome of patients with sepsis and multiple organ failure. This therapy offers new promise in the field of immuno-modulation because it is both broad-spectrum (removing both pro and anti inflammatory compounds) and self-regulating by removing substances in relation to their circulating concentrations. This project will modify the PF extracorporeal pheresis system treatment by making it a stand-alone system. A new sorbent mixture will be developed and tested in the laboratory with a broad assortment of sepsis initiators and mediators. The means of contacting plasma and sorbent will be changed to improve the efficacy of the system. The anticoagulation method will be changed to regional citrate anticoagulation. The safety systems of the existing PF system will be modified to meet the needs of the stand-alone system. Finally, an animal model of sepsis will be used to check efficacy and safety of the entire system.

Thesaurus Terms:
bioterrorism /chemical warfare, blood disorder chemotherapy, blood treatment, plasmapheresis, septic shock, therapy design /development anticoagulant, bacterial disease, blood /lymphatic pharmacology, blood filtration, blood toxicology, cytokine, hemodialysis, hemodynamics, lipopolysaccharide, multiple organ failure, nonhuman therapy evaluation, secondary infection dog