Stockpiling Of Drugs Research Articles

Selfish Drug Allocation for Containing an International Influenza Pandemic at the Onset

Recent epidemiologic studies have suggested that the prophylactic use of antiviral drugs could slow down the spread of an influenza epidemic. Because drug stockpiles are presently scattered in different countries, the outbreak of an epidemic gives rise to a game in which each country must make decisions about how best to allocate its own stockpile in order to protect its population. We develop a two-period multivariate Reed-Frost model to represent the spread of the epidemic within and across countries at its onset. We consider the first two periods only to mimic the exponential growth of an epidemic in its early stage, while keeping the model tractable. Preliminary numerical studies suggest that insights from the two-period model hold in general when considering the entire time horizon. Our model captures three critical sources of uncertainty: the number of initial infections, the spread of the disease, and drug efficacy. We show that for small probabilities of between-country infections, the underlying game is supermodular, Nash equilibrium exists, and there is a unique one that is Pareto optimal among all existing equilibria. Further, we identify sufficient conditions under which the optimal solution of a central planner (such as the World Health Organization) constitutes a Pareto improvement over the decentralized equilibrium, suggesting that countries should agree on an allocation scheme that would benefit everyone. By contrast, when the central planner's solution does not constitute a Pareto improvement, minimizing the total number of infected persons globally requires some countries to sacrifice part of their own population, which raises intriguing ethical issues.

Investment in antiviral drugs: a real options approach

Real options analysis is a promising approach to model investment under uncertainty. We employ this approach to value stockpiling of antiviral drugs as a precautionary measure against a possible influenza pandemic. Modifications of the real options approach to include risk attitude and deviations from expected utility are presented. We show that risk aversion counteracts the tendency to delay investment for this case of precautionary investment, which is in contrast to earlier applications of risk aversion to real options analysis. Moreover, we provide a numerical example using real world data and discuss the implications of real options analysis for health policy. Suggestions for further extensions of the model and a comparison with the expected value of information analysis are put forward.

Maximizing the Value of Drug Stockpiles for Pandemic Influenza

To the Editor: Tamiflu (oseltamivir; Roche, Indianapolis, IN, USA) is destined to be one of the few branded drugs to develop instant street recognition because of its status as 1 of only 2 licensed drugs shown to be active against the influenza A pandemic (H1N1) 2009 virus. Tamiflu is the major drug stockpiled by governments around the world in preparedness against an influenza pandemic. More than 70 governments have placed orders for Tamiflu, and at least 220 million treatment courses have been stockpiled since 2003 at a cost of $6.9 billion (1). Roche is producing 110 million courses for the 5 months from May to fall 2009 and will produce up to 36 million courses per month by year’s end if necessary. Given the estimated world population of 6.8 billion, it is clear that, on a global basis, stockpiles are woefully inadequate. For the United Kingdom, official estimates indicate sufficient stocks currently exist for half of the population (2). Given the high cost of these stockpiles, every effort should be made to maximize usage of the drug. Most of us are aware of shelf-life assignment to foods, a concept first applied to drugs well before its adoption by food manufacturers. Shelf-life extension could potentially yield significant cost savings in the event stockpiled drugs are not required for use within the typical 5-year shelf life. We use Tamiflu as a case example to suggest how this could be done through careful evidence-based risk assessment. The chemical integrity of any medicine, including Tamiflu, is important because decomposition may lead to loss of activity or formation of toxic products. For formulated products, decomposition may lead to impaired bioavailability. As it became obvious that there were inadequate drug stockpiles even in affluent countries, one of our authors (A.L.W.P., who had served as a member of the UK Committee on Safety of Medicines [3,4]) wrote to his local member of parliament (coauthor N.P.) to suggest that the government institute a program to extend the shelf life of drug stockpiles. A.L.W.P. argued that the relatively minor development work necessary to implement a shelf-life extension program would be highly cost-effective. The UK Department of Health then initiated a collaboration with Roche to extend the shelf life of Tamiflu. On May 8, 2009, the European Medicines Agency independently advised that new batches of Tamiflu would have a shelf life of 7 years instead of only 5 years (5). Oseltamivir is a prodrug that needs metabolic activation (Figure) (6). Prodrugs are used typically to reduce toxicity caused by functional groups such as the carboxylate ion, to alter release properties (e.g., prolonging action of antipsychotic agents), or to improve absorption (bioavailability) by making the drug more lipophilic. Figure Metabolic activation of oseltamivir to carboxylic acid. Oseltamivir carboxylic acid has poor bioavailability; <5% orally compared to 80% for oseltamivir, the parent drug (7). The carboxylate is the only major metabolite and the principal degradation product (7,8). Therefore, with poor storage the major risk is reduced activity through reduced absorption rather than formation of toxic by-products. Health agencies also stockpile other drugs (9), most notably antimicrobial drugs and vaccines. Shelf-life extension would need to be assessed on a product-by-product basis. For example, antimicrobial drugs are often quite unstable and the toxicologic implications are less clear; some evidence suggests that allergenic polymers could be formed while the drugs are in storage. On the positive side, antimicrobial drugs are considerably less expensive than neuramidase inhibitors such as Tamiflu, making antimicrobial stockpiles less costly to replenish. Products with more complicated delivery systems, such as zanamivir in inhalers, would require more validation. For biological products in complex formulations such as vaccines, stability validation may not be cost-effective. Given the high costs involved in maintaining adequate drug stockpiles, attempts should be made to optimize the value of drugs; shelf-life extension is one of the easiest and most cost-effective ways of doing this. We suggest that governments undertake a systematic program for iterative shelf-life extension, ideally cooperatively. The considerable financial savings could mitigate drug shortages of expensive antiviral drugs. The chemical profile of oseltamivir and its degradation pathway suggest that extending the shelf life of Tamiflu to >20 years should be feasible. Storage in dry airtight containers should be able to maintain the integrity of the product for >7 years. During a pandemic, when supplies are unavailable, the balance of benefit to harm would favor using the expired product. The 1918 influenza pandemic is estimated to have killed 50 million persons worldwide (10), many in developing countries. By better safeguarding available drug stockpiles, more drugs could be made available to poorer countries that have few drugs stockpiled.

Investment decisions in influenza pandemic contingency planning: cost-effectiveness of stockpiling antiviral drugs

Background: The threat of an influenza pandemic has led to stockpiling of antiviral drugs in order to mitigate a plausible outbreak. If the stockpile would be used in relation to the recent pandemic alert, an investment decision about renewing the stock for a possible subsequent pandemic is essential. The decision should include cost-effectiveness considerations. Methods: We constructed a cost-effectiveness analysis in the Dutch context, explicitly including risk of an outbreak. Outcomes from a dynamic transmission model, comparing an intervention with a non-intervention scenario, were input in our health economic calculations. Results: Stockpiling was cost-effective from the health-care perspective if the actual risk is 37% for 30 years. If less than 60% of the population would take the antiviral drugs or the attack rate is about 50%, the investment would not be cost-effective from this perspective. Conclusion: Risk perception, realistic coverage among population and size of a pandemic are crucial parameters and highly decisive for the investment decision.

Understanding Australia's influenza pandemic policy on the strategic use of the antiviral drug stockpile

Targeted post-exposure prophylaxis represents a more efficient use of the stockpile than treatment alone.

Effective use of a Limited Antiviral Stockpile for Pandemic Influenza

Just allocation of resources for control of infectious diseases can be profoundly influenced by the dynamics of those diseases. In this paper we discuss the use of antiviral drugs for treatment of pandemic influenza. While the primary effect of such drugs is to alleviate and shorten the duration of symptoms for treated individuals, they can have a secondary effect of reducing transmission in the community. However, existing stockpiles may be insufficient for all clinical cases. Here we use simple mathematical models to present scenarios where the optimum policies to minimise morbidity and mortality, with a limited drug stockpile, are not always the most intuitively obvious and may conflict with theories of justice. We discuss ethical implications of these findings.

European survey on decontamination in mass casualty incidents

The goal of this study is to assess the European status in the case of mass casualties regarding legislation, responsibilities of ministries and organizations, education and training, material and equipment, and bottlenecks. A questionnaire answered by 22 of 27 European Union member states and Croatia, Norway, and Switzerland. Results and recommendations of a European expert's workshop on decontamination of victims of mass casualties. Ministries and responsible organizations of 22 European Union member states Croatia, Norway, and Switzerland. Hazardous chemical agents are a global realistic risk. Therefore it is an important obligation to direct education, service activities and research towards priority concerns of prevention and response in case of an accidental or criminal liberation of toxic chemicals. The most effective procedures to save the life and health of contaminated persons are: (1) The decontamination of chemically contaminated casualties as soon as possible reduces both morbidity and mortality. (2) The removal of clothing as the first stage of the decontamination process reduces the amount of contamination by 75-85 percent. The decontamination in case of a mass casualty incident needs a high number of personnel, personal protection equipment (PPE), a decontamination unit, education and permanent training, and a management of command, communication, and coordination; all these in the shortest time of preparedness, reaction, and cross border nationally and internationally. During the German EU Council Presidency in the first 6 months of 2007 the Federal Ministry of the Interior held a 3 days seminar (Ahrweiler, February 22-24, 2007) on the "Decontamination of Casualties Involved in Incidents with Hazardous Chemical Materials--European Inventory and Perspectives." The aim was to arrange an exchange of information and experience on the various systems in place in Europe which would be beneficial to all parties concerned. The seminar was organized by the Federal Office of Civil Protection and Disaster Assistance. (1) Results of a nine question enquiry, (2) results of four workgroups with the focus on medicine, organization, equipment, and education. In most countries, the medical sector is the weakest part of the integrated approach. Decontamination has two goals: to decontaminate the casualties and to avoid secondary contamination of personnel, equipment, and institutions (hospitals). The most effective method for decontamination is to undress patients as soon as possible. The procedures for undressing, triage, basic life support, etc have to be evidence based by research. Cooperation between MS should be developed including transborder cooperation, designing modules in the framework of the EU Mechanism, and considering reinforcement between MS as precautionary measures, for example, for major international events. Interoperability of equipment is recommended and achievable. Need for European inventory of decontamination units. Need for national stockpiles of antidotes and drugs as well as logistics. The following recommendations were given to the EU Commission: Organize focused experts meetings on the above mentioned subjects. Promote common exercises. Collect and promote best practices by supporting research for evidence-based results. Promote crossborder cooperation and possibly preplanned reinforcements.

The Risk of Seasonal and Pandemic Influenza: Prospects for Control

Seasonal influenza is an underappreciated cause of morbidity and mortality in the United States. Seasonal vaccination of individuals in groups at high risk of complications has long been recommended. However, there has been a gradual expansion of the recommended groups for annual influenza immunization in order to reduce the incidence of uncomplicated infection, to alleviate the impact of seasonal influenza on health care, and to simplify the application of recommendations. The threat of an influenza pandemic, heightened by recent cases of highly pathogenic avian influenza in humans, requires continued efforts in preparedness. Strategies for the control of pandemic influenza must include vaccines, antiviral drugs, and nonpharmaceutical interventions like school closure and voluntary quarantine around cases. The prophylactic efficacy of neuraminidase inhibitors, previously observed in household studies, suggests that they will be a useful adjunct to voluntary quarantine. Stockpiles of antiviral drugs are being established for therapeutic and perhaps preventive use for pandemic influenza.

Recommendations for the prevention and treatment of influenza using antiviral drugs based on cost–effectiveness

Influenza is an acute respiratory disease that causes epidemics and pandemics in the human population of temperate regions. Influenza epidemics occur every year during the winter months, affecting approximately 10% of the population. The primary strategy for reducing the effect of influenza in the community is to vaccinate persons who are at risk or caring for high-risk individuals each year before seasonal increases in influenza virus circulation occur. Antiviral drugs can be used for the treatment of influenza and the prevention of seasonal and post-exposure influenza. Four antiviral drugs are available for the prevention and treatment of influenza infections: oseltamivir, zanamivir, rimantadine and amantadine. Antiviral drugs can be used for the treatment of influenza and for post-exposure and seasonal influenza prevention. The cost–effectiveness of antiviral therapies ranged from cost savings to more than US$130,000 per quality-adjusted life-year (QALY) for influenza treatment, from GB£9000 to more than £1 million per QALY for seasonal prevention and from cost savings to £100,000 per QALY for post-exposure prevention. Based on the cost–effectiveness threshold of £30,000 or $40,000 per QALY, antiviral therapies can be recommended for influenza treatment and post-exposure prevention in healthy and high-risk individuals and for seasonal prevention in high-risk individuals. Zanamivir, oseltamivir and amantadine have favorable cost–effectiveness ratios for these interventions, but amantadine should only be used in countries with a low prevalence of resistant virus. The stockpile of antiviral drugs should be maintained in developed countries because they are cost effective for the prevention and treatment of a possible influenza pandemic.

A large-scale simulation model of pandemic influenza outbreaks for development of dynamic mitigation strategies

Limited stockpiles of vaccine and antiviral drugs and other resources pose a formidable healthcare delivery challenge for an impending human-to-human transmittable influenza pandemic. The existing preparedness plans by the Center for Disease Control and Health and Human Services strongly underscore the need for efficient mitigation strategies. Such a strategy entails decisions for early response, vaccination, prophylaxis, hospitalization and quarantine enforcement. This paper presents a large-scale simulation model that mimics stochastic propagation of an influenza pandemic controlled by mitigation strategies. The impact of a pandemic is assessed via measures including total numbers of infected, dead, denied hospital admission and denied vaccine/antiviral drugs, and also through an aggregate cost measure incorporating healthcare cost and lost wages. The model considers numerous demographic and community features, daily human activities, vaccination, prophylaxis, hospitalization, social distancing, and hourly accounting of infection spread. The simulation model can serve as the foundation for developing dynamic mitigation strategies. The simulation model is tested on a hypothetical community with over 1100 000 people. A designed experiment is conducted to examine the statistical significance of a number of model parameters. The experimental outcomes can be used in developing guidelines for strategic use of limited resources by healthcare decision makers. Finally, a Markov decision process model and its simulation-based reinforcement learning framework for developing mitigation strategies are presented. The simulation-based framework is quite comprehensive and general, and can be particularized to other types of infectious disease outbreaks.

Crystal structures of oseltamivir-resistant influenza virus neuraminidase mutants

The potential impact of pandemic influenza makes effective measures to limit the spread and morbidity of virus infection a public health priority. Antiviral drugs are seen as essential requirements for control of initial influenza outbreaks caused by a new virus, and in pre-pandemic plans there is a heavy reliance on drug stockpiles. The principal target for these drugs is a virus surface glycoprotein, neuraminidase, which facilitates the release of nascent virus and thus the spread of infection. Oseltamivir (Tamiflu) and zanamivir (Relenza) are two currently used neuraminidase inhibitors that were developed using knowledge of the enzyme structure. It has been proposed that the closer such inhibitors resemble the natural substrate, the less likely they are to select drug-resistant mutant viruses that retain viability. However, there have been reports of drug-resistant mutant selection in vitro and from infected humans. We report here the enzymatic properties and crystal structures of neuraminidase mutants from H5N1-infected patients that explain the molecular basis of resistance. Our results show that these mutants are resistant to oseltamivir but still strongly inhibited by zanamivir owing to an altered hydrophobic pocket in the active site of the enzyme required for oseltamivir binding. Together with recent reports of the viability and pathogenesis of H5N1 (ref. 7) and H1N1 (ref. 8) viruses with neuraminidases carrying these mutations, our results indicate that it would be prudent for pandemic stockpiles of oseltamivir to be augmented by additional antiviral drugs, including zanamivir.

Resource Allocation during an Influenza Pandemic

To the Editor: Planning for pandemic influenza is accepted as an essential healthcare service and has included creation of national and international antiviral drug stockpiles and novel approaches to emergency vaccine development (1). The effectiveness of these strategies in a pandemic may be substantial but is unknown. More certain is that effective management of severe and complicated influenza will reduce deaths and that demand will exceed available treatment resources (2). Appropriate allocation of treatment resources is therefore essential, perhaps more important than any specific treatment such as administering antiviral medication to symptomatic patients. Resource allocation requires the following: 1) making clear societal decisions on the goals for healthcare resources; 2) conducting operational research to develop an evidence base to support the achievement of these goals; and 3) developing systems to capture and learn from new information in a pandemic to facilitate modification of the response as the characteristics of the pandemic emerge. Most societies have not yet addressed the first issue fully. In the United Kingdom, a Department of Health consultation on planning critical care during emergencies cites “the underpinning principle of providing the greatest good for the greatest number of people during the course of an emergency” and thus appears to support a capacity-to-benefit approach (3). Similarly, triage criteria developed in Canada, based on the Sequential Organ Failure Assessment (SOFA) score, exclude those persons believed to be too ill or otherwise unlikely to benefit from critical care (4). Even more important for most severely ill patients, however, will be deciding whether to admit them to the hospital at all. The UK pandemic-planning criteria currently recommend a scoring system for hospital admission based on an assessment of poor outcome rather than on capacity to benefit (2). Indeed, age >85 years and severe underlying cognitive impairment, which would rule out admission to critical care in Canada, would strongly favor admission to hospital care in the United Kingdom, the opposite of the situation for a younger cognitively intact person with similar disease severity. If tools are to be developed to support triage at all stages of the patient pathway in a pandemic, societies must consider the ethical issues raised (4,5), debate them, and take a position on the values that should underpin decision making in a pandemic. Even when clear societal goals are established, much work remains to ensure that the healthcare community is equipped to steer healthcare resources to deliver these effectively (6). Community-acquired pneumonia has been used as a surrogate for influenza to test predictive scoring systems for assessing severity and assisting triage decisions (7). Seasonal influenza epidemics would provide the most realistic setting available, in particular, if protocols were in place to test criteria when a relatively severe influenza season occurs. In addition to identifying criteria for setting priorities within influenza management, such testing will need to consider the balance of resources between influenza treatment and treatment of other usual noninfluenza conditions that will require emergency care during the pandemic. Decisions that must be made during a pandemic are complex, varying from when to stop major elective surgery so critical care capacity can be opened up, to how to triage those who have experienced major trauma and those with influenza. These decisions could differ from those same decisions made outside a pandemic, and an adequate evidence base is needed if they are to be of good quality. The third component of our preparation for optimally deploying standard care in a pandemic is being able to change our approach quickly as new knowledge emerges. In the so-called Spanish influenza pandemic of 1918–19, the unfamiliar clinical course meant that influenza was not even considered when the first cases appeared (8), and expectations had to be revised concerning who was most vulnerable and at what stage in their clinical course they were most at risk. Therefore, healthcare professionals must develop and test the public health infrastructure to capture patient factors associated with outcome and treatment response during a pandemic and feed this information back into clinical practice rapidly and reliably, as occurred during the epidemic of severe acute respiratory syndrome (9). International collaboration will be important for sharing this work (10) and developing useful tools early in a pandemic. Having recognized the risk for pandemic influenza, we must now complement the research into novel influenza treatments by addressing our knowledge gap on how best to use our resources to deliver optimal clinical care in the management of influenza guided by effective clinical surveillance.

Pandemic preparedness

Pandemic influenza remains a threat to world health and will probably result in an overwhelming number of critically ill patients. Preparations should be made now to meet this threat. Limited data are available on which to base preparations. Adequate staffing is crucial to the functioning of an ICU and therefore occupational safety is of central concern. In the absence of knowledge of the method of spread of a pandemic disease, it would seem appropriate to take airborne and contact precautions, and the literature related to this area is reviewed. Methods of recruiting and training additional staff and the issues of bed capacity, stockpiling, triage and ethics are discussed. Extensive preparation is needed in advance of an epidemic. This should include occupational safety measures, stockpiling of equipment and drugs, staff training, development of triage policies, and discussion of the limits of duty of care to patients. These preparations take considerable time and therefore these issues should be tackled urgently.

Antiviral treatment for the control of pandemic influenza: some logistical constraints.

Disease control programmes for an influenza pandemic will rely initially on the deployment of antiviral drugs such as Tamiflu, until a vaccine becomes available. However, such control programmes may be severely hampered by logistical constraints such as a finite stockpile of drugs and a limit on the distribution rate. We study the effects of such constraints using a compartmental modelling approach. We find that the most aggressive possible antiviral programme minimizes the final epidemic size, even if this should lead to premature stockpile run-out. Moreover, if the basic reproductive number R(0) is not too high, such a policy can avoid run-out altogether. However, where run-out would occur, such benefits must be weighed against the possibility of a higher epidemic peak than if a more conservative policy were followed. Where there is a maximum number of treatment courses that can be dispensed per day, reflecting a manpower limit on antiviral distribution, our results suggest that such a constraint is unlikely to have a significant impact (i.e. increasing the final epidemic size by more than 10%), as long as drug courses sufficient to treat at least 6% of the population can be dispensed per day.

An analysis of the current status of hospital emergency preparedness for infectious disease outbreaks in Beijing, China

BackgroundIn the event of a large-scale infectious disease outbreak, hospitals will play a critical role. The objective of our study is to understand the current status of hospitals preparedness for infectious disease outbreaks in Beijing and to provide basic information for infectious disease prevention and control in hospitals.MethodsOne hundred fifty-two secondary and tertiary care hospitals in Beijing were surveyed by a standardized questionnaire. Data related to hospital demographic information and their emergency plans, laboratory diagnosis capacity, medical treatment procedures for infectious diseases, stockpiles of drugs and personal protective equipment, and staff training were collected.ResultsResponses were received from 134 (88.2%) of the 152 hospitals surveyed. Overall, hospitals reported that the number of physicians and nurses in infectious disease accounted for only 1.8% of the total physicians and 2.5% of the total nurses, and surgery beds accounted for 8.5% of all the fixed beds. Approximately 93.3% of the hospitals surveyed reported that they had an emergency plan, and none of those reported that their laboratories were able to isolate and identify all 8 kinds of common pathogens of infectious diseases: 22.4% of the hospitals had medical treatment procedures for all these infectious diseases, 23.1% had stored specific drugs for treatment, 2.2% had all personal protective equipment, and 30.6% reported that their health care staff had been trained in hospital emergency preparedness for infectious diseases. In general, emergency preparedness for infectious diseases in tertiary care hospitals was better than that in secondary care hospitals; the preparedness at general hospitals was better than that at specialized hospitals; and that at teaching hospitals was better than that at nonteaching hospitals.ConclusionEmergency preparedness for infectious disease at hospitals in Beijing was in an early stage of development during this survey. Comprehensive measures should be developed and implemented to enhance their capacity for infectious disease emergency.

Refill non-adherence to repeat prescriptions leads to treatment gaps or to high extra costs

To determine the nature and extent of undersupply and the economic consequences of oversupply of medication among non-adherent patients. This study used copies of repeat prescriptions (= multiple dispensations), collected during 1 week in 2002 at 16 Swedish community pharmacies. For patients with a refill adherence below 80%, treatment gaps were defined as the number of days they had no drug available. The cost of drug oversupply (i.e., refill adherence > 120%) was calculated from the prices of the drug packages dispensed. The number of collected repeat prescriptions was 3,636. The median of treatment gaps among patients with a refill adherence below 80% was 53 days per 90-100 days treatment period and the corresponding median for oversupply was 40 days. The cost of oversupply for exempt patients (i.e., patients who have paid 1,800 SEK (Euro 196; US$ 243) per year for medicines) was 32,000 SEK (Euro 3,500; US$ 4,300) higher than for non-exempt patients. An extrapolation to all Sweden indicates that exemption from charges leads to an additional oversupply of about 142 million SEK (Euro 15 million; US$ 19 million) per year above that of non-exempt patients. Both undersupply and oversupply of prescribed medicines are common in Sweden. Patients with a refill adherence below 80% seem to have less than half of the prescribed treatment available. Oversupply or drug stockpiling occurs more frequently among exempt than among non-exempt patients, and this oversupply leads to high unnecessary costs.

Will the Post 9/11 World Be a Post-Tort World?

This essay looks at the impact of 9/11 on provisions for civil recourse by victims of harm. The short answer to the title question is: NO. But tort law will continue to be eroded by attrition, by lopping off remedies - especially by limiting damages and expanding immunities - unless we are able to grab hold of the public's conscience and consciousness to bring home the point that liability in tort is not some form of punishment, erratically inflicted. We discuss and analyze the legislative responses that followed: * the September 11 Victims Compensation Fund * establishment of the World Trade Center Captive Insurance Company to provide defense and excess liability insurance of $1 billion to the City of New York and its contractors. * the smallpox vaccination campaign and the liability limitations and modest compensation scheme of the Smallpox Emergency Personnel Protection Act of 2003. * the adoption of the government contractor defense for suppliers of qualified anti-terrorism technology to the newly created Department of Homeland Security in the SAFETY Act of 2004. * the BioShield Act of 2004 which established a strategic national stockpile of drugs, vaccines and other biological products, medical devices, and other supplies for use in the event of bioterrorist attack or public health emergency. * The Public Readiness and Emergency Preparedness Act of 2005,(PREPA) which declares targeted liability protections for pandemic and epidemic products and security countermeasures. * S. 2291, a bill introduced in 2006 by the Democratic leadership, would repeal the PREPA and create a defense in a narrow class of medical products for which use is permitted without completing the usual regulatory vetting, due to their importance in a threatened emergency. We discuss the ATSSSA, reviewing the strengths and weaknesses of the tort claims of those who were injured and died on 9/11. Next reviewed are the WTC respiratory injury occupational disease tort claims, their necessity and justice, examining their vulnerability in light of the immunity and lack of duty defenses raised. The claims affirm the importance and vigor of the tort remedy. The other post 9/11 liability-limiting legislative measures are discussed. They provide broad protection for many classes of actors and sellers, including administrators and producers of vaccines. A survey of the historic experience with the Swine Flu vaccine campaign of 1976 shows the centrality of familiar tort liability principles of responsibility. In the Swine Flu vaccination the government stood in the shoes of vaccine manufacturers. The United States admitted strict liability in tort for some vaccine complications (such as confirmed paralytic Guillain Barre Syndrome), and fought others. And under the Federal Tort Claims Act the United States defended its own hard sell of the Swine Flu vaccine. Liability was imposed on the United States itself for the Centers for Disease Control's failure to adequately inform citizens of vaccine risks. The British Hepatitis C-contaminated blood cases are discussed as another important instance of government agency liability. There the National Blood Authority was held accountable as collector and distributor of blood products for its tardy implementation of an effective test for viral contamination. First presented as the 2006 Raynes McCarty Distinguished Health Law Lecture, Widener Law School, October 11, 2006

Antiviral agents active against influenza A viruses.

The recent outbreaks of avian influenza A (H5N1) virus, its expanding geographic distribution and its ability to transfer to humans and cause severe infection have raised serious concerns about the measures available to control an avian or human pandemic of influenza A. In anticipation of such a pandemic, several preventive and therapeutic strategies have been proposed, including the stockpiling of antiviral drugs, in particular the neuraminidase inhibitors oseltamivir (Tamiflu; Roche) and zanamivir (Relenza; GlaxoSmithKline). This article reviews agents that have been shown to have activity against influenza A viruses and discusses their therapeutic potential, and also describes emerging strategies for targeting these viruses.

A 'small-world-like' model for comparing interventions aimed at preventing and controlling influenza pandemics

BackgroundWith an influenza pandemic seemingly imminent, we constructed a model simulating the spread of influenza within the community, in order to test the impact of various interventions.MethodsThe model includes an individual level, in which the risk of influenza virus infection and the dynamics of viral shedding are simulated according to age, treatment, and vaccination status; and a community level, in which meetings between individuals are simulated on randomly generated graphs. We used data on real pandemics to calibrate some parameters of the model. The reference scenario assumes no vaccination, no use of antiviral drugs, and no preexisting herd immunity. We explored the impact of interventions such as vaccination, treatment/prophylaxis with neuraminidase inhibitors, quarantine, and closure of schools or workplaces.ResultsIn the reference scenario, 57% of realizations lead to an explosive outbreak, lasting a mean of 82 days (standard deviation (SD) 12 days) and affecting 46.8% of the population on average. Interventions aimed at reducing the number of meetings, combined with measures reducing individual transmissibility, would be partly effective: coverage of 70% of affected households, with treatment of the index patient, prophylaxis of household contacts, and confinement to home of all household members, would reduce the probability of an outbreak by 52%, and the remaining outbreaks would be limited to 17% of the population (range 0.8%–25%). Reactive vaccination of 70% of the susceptible population would significantly reduce the frequency, size, and mean duration of outbreaks, but the benefit would depend markedly on the interval between identification of the first case and the beginning of mass vaccination. The epidemic would affect 4% of the population if vaccination started immediately, 17% if there was a 14-day delay, and 36% if there was a 28-day delay. Closing schools when the number of infections in the community exceeded 50 would be very effective, limiting the size of outbreaks to 10% of the population (range 0.9%–22%).ConclusionThis flexible tool can help to determine the interventions most likely to contain an influenza pandemic. These results support the stockpiling of antiviral drugs and accelerated vaccine development.

Scientific lessons from the first influenza pandemic of the 20th century

Re-analysis of the influenza pandemic of 1918 has given reassurance about a rather low reproductive number (R o), a prolonged herald wave of virus and that the skewed mortality towards the young adult could be a singularly unique event dependent upon previous infection history, perhaps not to be repeated in a future pandemic. Over 99% of those who contracted the virus survived, in spite of the absence of antivirals, vaccine and antibiotics for the secondary bacteria infections which probably accounted for one-third of the 50 million deaths. Therefore, in spite of a three-fold population increase since 1918 and 100 thousand plane journeys daily, judicious and careful planning together with a stockpile of antiviral drugs, oseltamivir, zanamivir and M2 blockers and a generic H5N1 vaccine, and application of hygiene would be expected to reduce mortality in a new pandemic, to figures significantly less than 1918.