Click here to get a transcript of John's conversation.
NOSOCOMIAL INFECTIONSIn this episode we examine hospital-acquired, or nosocomial, infections. AirInSpace, a leading supplier of mobile medical devices that captureand inactivate harmful and resistant biological particles from the air, allowed us to observe its symposium: Strategies for Airborne Infection Control Under Challenging Environments and Patient Conditions. This symposium was held at the 2008 annual conference of the Association for Professionals in Infection Control & Epidemiology, or APIC.What youll hear are three presentations. The first, by Wayne R. Thomann, Ph.D., Director of the Occupational and Environmental Safety Office at Duke University Medical Center, takes a look at the ongoing and evolving challenges of protecting patient environments.The second presentation, by Michael S. Phillips, M.D., an assistant clinical professor in the Division of Infectious Diseases and Immunology at New York University School of Medicine, reviews the epidemiology of invasive Aspergillosis (IA), a particularly lethal airborne infection.And the final presentation, from Ludwig Aho-Glélé, M.D., who is head of the Epidemiology and Hospital Hygiene unit at Dijon University Hospital, discusses results of using AirInSpace technology at his hospital to protect immunocompromised patients.First up is Dukes Dr. Wayne Thomann. Click here to view the Symposium presentations. PLEASE NOTE: This is a 1-hour DIVX movie file, and it may take some time to download. You will need the latest versions of Quicktime or Windows Media Player to view it.
Dr. Denis Caillot
HOSPITAL-ACQUIRED INFECTIONSIn the United States, attempts to control hospital-acquired (nosocomial) infections are proving ineffective, according to the Government Accountability Office (GAO).In fact, hospital-acquired infections are estimated to be one of the top-ten causes of death in the U.S., claiming 90,000 lives every year.In this episode, we look at how Dijon Hospital in Dijon, France, is protecting its most vulnerable patients with a new mobile infection control technology from AirInSpace.The companys device, called PlasmairT2006, was recently cleared by the FDA to be used in U.S. hospitals.At Dijon Hospital, there are 40 mobile Plasmair units being used in the pediatric and adult haematology wards, where immunocompromised cancer patients are at high risk from deadly airborne pathogens such as aspergillosis.We speak with two doctors at Dijon Hospital: Dr. Denis Caillot, head of Clinical Haematology, and his colleague, Dr. Ludwig Aho, head of Hospital Hygiene and Epidemiology. .
Dr. Ludwig Aho
NANOMEDICINE AND TARGETED CANCER THERAPY SERIES
Paras Prasad, PhD, Executive Director of the Institute for Lasers, Photonics and Biophotonics at SUNY (Buffalo)
NANOMEDICINE AND TARGETED CANCER THERAPY SERIES - One in four deaths in the U.S. is from cancer, making it the second-leading cause of death after heart attack. Radiation therapyalso called radiotherapy, x-ray, or irradiationis typically used to kill cancer cells and shrink tumors. Radiation therapy injures or destroys cells in the area being treated by damaging their genetic material, making it impossible for these cells to continue to grow and divide. The goal of radiation therapy is to damage as many cancer cells as possible, while limiting harm to nearby healthy tissue. About half of all cancer patients receive some type of radiation therapy, which may be used alone or in combination with other cancer treatments, such as chemotherapy or surgery. Radiation therapy may be used to treat almost every type of solid tumor. Radiation dose to each site depends on a number of factors, including the type of cancer and whether there are tissues and organs nearby that may be damaged by radiation. In these episodes, well speak with leading radiation-oncologists and other experts about how a Paris-based company, Nanobiotix, is using technology that it calls nanoXray to resolve radiation therapys biggest drawback: destruction of healthy tissue and its subsequent deleterious side effects when a high dose of x-ray is necessary. The Company believes that nanoXray offers the potential for a dramatic innovation in cancer therapy, based on a technology that is designed to allow destruction of cancer cells onlya new treatment weapon that could be used alone, or in concert with existing anticancer protocols: chemotherapy, surgery, and immunotherapy. Because nanoXray does not interact with healthy cells, it is expected to prevent the toxic side effects associated with chemotherapy.
Paras Prasad, PhD, Executive Director of the Institute for Lasers, Photonicsand Biophotonics at SUNY (Buffalo) and one of the world's leading authorities on nanotechnology. Dr. Prasad is a co-founder of Nanobiotix and a Science Adviser to the Company. .
Elsa Borghi, MD
NANOMEDICINE AND TARGETED CANCER THERAPY SERIES - One in four deaths in the U.S. is from cancer, making it the second-leading cause of death after heart attack. Radiation therapyalso called radiotherapy, x-ray, or irradiationis typically used to kill cancer cells and shrink tumors. Radiation therapy injures or destroys cells in the area being treated by damaging their genetic material, making it impossible for these cells to continue to grow and divide. The goal of radiation therapy is to damage as many cancer cells as possible, while limiting harm to nearby healthy tissue. About half of all cancer patients receive some type of radiation therapy, which may be used alone or in combination with other cancer treatments, such as chemotherapy or surgery. Radiation therapy may be used to treat almost every type of solid tumor. Radiation dose to each site depends on a number of factors, including the type of cancer and whether there are tissues and organs nearby that may be damaged by radiation. In these episodes, well speak with leading radiation-oncologists and other experts about how a Paris-based company, Nanobiotix, is using technology that it calls nanoXray to resolve radiation therapys biggest drawback: destruction of healthy tissue and its subsequent deleterious side effects when a high dose of x-ray is necessary. The Company believes that nanoXray offers the potential for a dramatic innovation in cancer therapy, based on a technology that is designed to allow destruction of cancer cells onlya new treatment weapon that could be used alone, or in concert with existing anticancer protocols: chemotherapy, surgery, and immunotherapy. Because nanoXray does not interact with healthy cells, it is expected to prevent the toxic side effects associated with chemotherapy.
Elsa Borghi, MD, Medical Director, Nanobiotix. Previously, Dr. Borghi worked in the R&D oncology department for Sanofi-Aventis, one of the five largest pharmaceutical companies in the world, until the onset of 2008, when she joined Nanobiotix. .
Christophe Douat
NANOMEDICINE AND TARGETED CANCER THERAPY SERIES - More than half of all cancer patients worldwide receive radiation therapyalso called radiotherapy, x-ray, or irradiationto treat their disease. According to the American Cancer Society (ACS), there were 12 million new cases of cancer worldwide in 2007. By 2050, ACS estimates there will be 27 million new cases worldwide on an annual basis. Radiation therapy is typically used to kill cancer cells and shrink tumors. Radiation therapy injures or destroys cells in the area being treated by damaging their genetic material, making it impossible for these cells to continue to grow and divide. The goal of radiation therapy is to damage as many cancer cells as possible, while limiting harm to nearby healthy tissue. Radiation therapy may be used alone or in combination with other cancer treatments, such as chemotherapy or surgery. Radiation therapy may be used to treat almost every type of solid tumor. In these episodes, well speak with leading industry experts and Nanobiotix executives about how the Company is using technology that it calls nanoXray to resolve radiation therapys biggest drawback: destruction of healthy tissue and its subsequent deleterious side effects when a high dose of x-ray is necessary. The Company believes that nanoXray offers the potential for a dramatic innovation in cancer therapy, based on a technology that is designed to allow destruction of cancer cells onlya new treatment weapon that could be used alone, or in concert with existing anticancer protocols: chemotherapy, surgery, and immunotherapy. Because nanoXray does not interact with healthy cells, it is expected to prevent the toxic side effects associated with chemotherapy.
Christophe Douat, a former strategy consultant with the Boston Consulting Group and now a Partner with Paris-based VC firm Matignon Technologies, is an investor in Nanobiotix. .
Patrick Langlois
NANOMEDICINE AND TARGETED CANCER THERAPY - More than half of all cancer patients worldwide receive radiation therapyalso called radiotherapy, x-ray, or irradiationto treat their disease. According to the American Cancer Society (ACS), there were 12 million new cases of cancer worldwide in 2007. By 2050, ACS estimates there will be 27 million new cases worldwide on an annual basis. Radiation therapy is typically used to kill cancer cells and shrink tumors. Radiation therapy injures or destroys cells in the area being treated by damaging their genetic material, making it impossible for these cells to continue to grow and divide. The goal of radiation therapy is to damage as many cancer cells as possible, while limiting harm to nearby healthy tissue. Radiation therapy may be used alone or in combination with other cancer treatments, such as chemotherapy or surgery. Radiation therapy may be used to treat almost every type of solid tumor. In these episodes, well speak with leading industry experts and Nanobiotix executives about how the Company is using technology that it calls nanoXray to resolve radiation therapys biggest drawback: destruction of healthy tissue and its subsequent deleterious side effects when a high dose of x-ray is necessary. The Company believes that nanoXray offers the potential for a dramatic innovation in cancer therapy, based on a technology that is designed to allow destruction of cancer cells onlya new treatment weapon that could be used alone, or in concert with existing anticancer protocols: chemotherapy, surgery, and immunotherapy. Because nanoXray does not interact with healthy cells, it is expected to prevent the toxic side effects associated with chemotherapy.
Patrick Langlois, former Aventis Vice Chairman and CFO and now a General Partner with consulting firm PJL CONSEILS, and recently elected Chairman of Nanobiotix. .
NANOMEDICINE AND TARGETED CANCER THERAPY One in four deaths in the U.S. is from cancer, making it the second-leading cause of death after heart attack.Radiation therapyalso called radiotherapy, x-ray, or irradiationis typically used to kill cancer cells and shrink tumors.Radiation therapy injures or destroys cells in the area being treated by damaging their genetic material, making it impossible for these cells to continue to grow and divide. The goal of radiation therapy is to damage as many cancer cells as possible, while limiting harm to nearby healthy tissue. About half of all cancer patients receive some type of radiation therapy, which may be used alone or in combination with other cancer treatments, such as chemotherapy or surgery. Radiation therapy may be used to treat almost every type of solid tumor. Radiation to each site depends on a number of factors, including the type of cancer and whether there are tissues and organs nearby that may be damaged by radiation. In this episode, well take a look at how a Paris-based company, Nanobiotix, is using technology that it calls nanoXray to resolve radiation therapys biggest drawback: destruction of healthy tissue and its subsequent deleterious side effects when a high dose of x-ray is necessary.The Company believes that nanoXray offers a dramatic innovation in cancer therapy, based on a technology that is designed to allow destruction of cancer cells onlya new treatment weapon that could be used alone, or in concert with existing anticancer protocols: chemotherapy, surgery, and immunotherapy.Because nanoXray does not interact with healthy cells, it is expected to prevent the toxic side effects associated with chemotherapy.
Dr. Jean Bourhis (MD, PhD), a radiation-oncologist and researcher with the Institut Gustave Roussy, one of Europes leading cancer research and treatment centers, discusses radiation therapy and his experience with the emerging nanoXray technology. .
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Don Rohrbaugh, CEO, Sunshine Heart Inc.
Heart Failure Intervention - Sunshine Heart is a medical device company focused on commercializing C-Pulsean implantable, non-blood-contacting heart assist therapy for treating people with moderate heart failure: a condition in which the heart progressively loses its ability to efficiently pump blood throughout the body.C-Pulse reduces the symptoms of heart failure through the use of counterpulsation technology, which enables an increase in cardiac output and coronary blood flow and a reduction in the hearts pumping workload.Sunshine Heart currently has an IDE application under consideration by the FDA seeking approval to conduct a US clinical trial with C-Pulse.In this episode, Sunshine Hearts CEO Don Rohrbaugh discusses early heart-failure intervention.
Bob Ward, CEO, The Polymer Technology Group
Professor Joachim Schofer
UNCLOGGING THE FORKS: A bifurcation is an area where one main blood vessel branches out into two smaller vessels, like a fork in the road: one being the continuation of the main vessel, the other one often referred to as the side branch. Narrowings at a bifurcation are very commonmore than 500,000 bifurcation coronary lesions are treated each year. But even using drug-eluting stents (DES), the restenosis rate in bifurcations is a startling 23-26 percent. The difficulty in treating bifurcated lesions with conventional interventional approaches i.e., angioplasty with stenting lies in the troublesome anatomical terrain in which the lesions occur. Having to work at the Y-shaped intersection of two vessels, interventionalists have to maneuver multiple guidewires and stents, which often present challenges that increase the procedures complexity. Equally important, current stents, since they are not designed to fit bifurcated vessels, do not properly scaffold the areaand specifically the side branch entrance. Thus, having a device specifically designed for bifurcationswhich is a significant unmet clinical needshould help avoid many of these clinical problems. In this episode, Professor Joachim Schofer of the Center for Cardiology and Vascular Interventions, Hamburg, Germany, gives his perspective on bifurcated stents, in general, and the Stentys birfurcated stent, in particular. . CLICK HERE TO DOWNLOAD THE PODCAST TRANSCRIPT.
Richard Heller, MD
DNA Vaccines Conventional technology used to create vaccines for a limited number of diseases such as polio and tetanus is not effective against cancer, HIV, hepatitis C, and a legion of other deadly and disabling diseases.But the promise of using a new generation of technologyDNA vaccinesto stimulate the bodys own immune responses has been curtailed by a lack of an effective delivery system.Use of virus carriers poses uncertainties regarding potential mutation and unwanted immune responses against the carrier. Lipids and the gene gun may not achieve sufficient levels of immune response.And none of these methods is inexpensive. Now, there is growing evidence that an electroporation-based delivery system from Inovio Biomedical (AMEX: INO) has the potential to become a preferred delivery method for a wide range of therapeutic and preventive vaccines.In this episode, Dr. Richard Heller of the University of South Floridas College of Medicine and the Moffitt Cancer Center discusses how electroporation works to deliver a DNA vaccine and enhance the potency of that vaccine as well.Dr. Heller is currently the principal investigator in an ongoing Phase I melanoma clinical study to test the safety and tolerability of direct intratumoral delivery of plasmid-based IL-12 using the electroporation system of Inovio Biomedical. .
Rafael Neiman, M.D.
In this episode, Rafael Neiman, M.D., of Orthopedic Trauma Surgeons of Northern California, discusses how he injected a 49-year-old female patients own bone marrow stem cells into the fracture and nonunion sites of both her legs that had not healed since injured in a skiing accident seven months earlier.Dr. Neiman reports that complete fracture closure and union was achieved in both legs.This case is noteworthy because Dr. Neiman treated his patient without open surgery by collecting, processing, and returning the patients own bone marrow stem cells at the patients bedside in the same procedure.It has been widely reported in the scientific literature that percutaneous delivery of a high concentration of adult stem cells can enhance the rate and amount of bone formation.Several studies have documented the effects of injected bone marrow cell concentrates in cardiovascular and orthopedic disease.Until now, it has been difficult to process and concentrate adult stem cells from a patients own bone marrow at the point of care.
Robert G. Johnson, M.D., Neurosugical Assoc., San Antonio, TX
There is significant interest among spine surgeons for a bone graft substitute that could be used during lumbar spine surgery to help facilitate fusion and thereby eliminate the need to harvest a patients own bone. In this episode, Dr. Robert Johnson, a spine surgeon based in San Antonio, Texas, talks about his ongoing study using autologous adult stem cells to facilitate spinal fusion instead of using bone harvested from a patients pelvis, which may create two potential problems: (1) graft site morbidity (complications may include bleeding, infection, and chronic pain at the donor site in the pelvis); and (2) failure to fuse. These are the two primary reasons that there is great interest in creating a bone graft mechanism for use in a spine fusion procedure instead of using a patients own bone.
Dr. Robert Nagel
In this episode, we'll take a look at what's new in treating cellulite, focusing on an emerging, privately funded aesthetics company called SmoothShapes®.The Company's FDA-cleared SmoothShapes® 100 device is a painless, non-invasive laser-based system that works gradually and effectively to improve the appearance of cellulite by reducing its underlying cause: subcutaneous fat.A multi-center clinical study of the SmoothShapes® device concluded that 81 percent of patients experienced significant volumetric reduction in subcutaneous fat. SmoothShapes® 100 is the only system that has validated its claims with rigorous and extensive before-and-after MRI evaluations, in stark contrast to the random and subjective photography that typifies this category. here to listen.
SmoothShapes 100
In this episode, sports medicine physicians discuss how and why they have used autologous adult stem cells in an office-based healthcare setting. They are treating a 55-year-old woman who faces hip replacement surgery if their stem cell therapy is not effective. The stem cell therapy is made possible at the point-of-care by Harvest Technologies and its BMAC® System for concentrating autologous adult stem cells. .
