Empirical Studies of the Development and Diffusion of Medical Technologies

医疗技术发展和传播的实证研究

• 批准号: 8738582
• 负责人: HEIDI Lie WILLIAMS
• 金额: $ 27.67万
• 依托单位: NATIONAL BUREAU OF ECONOMIC RESEARCH
• 依托单位国家: 美国
• 财政年份: 2013
• 资助国家: 美国
• 起止时间: 2013-09-30 至 2018-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8738582
• 关键词: Affect; Antineoplastic Agents; Award; Basic Science; Cancer Patient; Cause of Death; Classification; Clinical Trials; Code; Cost-Benefit Analysis; Costs and Benefits; Data; Data Set; Development; Diagnosis; Diagnostic; Diffusion; Disease; Economics; Enrollment; Genes; Genotype; Goals; Government; Grant; Healthcare Market; Hereditary Disease; Human; Human Genome; Incentives; Investments; Legal patent; Length; Licensing; Light; Link; Litigation; Malignant Neoplasms; Marketing; MeSH Thesaurus; Measures; Medical; Medical Technology; Methods; National Cancer Institute; Oncogenes; Organ; Paper; Patients; Pharmacologic Substance; Phenotype; Physician Data Query; Policies; Prostate; PubMed; Public Policy; Randomized; Registries; Research; Rights; Scientific Advances and Accomplishments; Shapes; Source; Staging; System; Technology; Text; Theoretical model; Trademark; Work; base; cancer therapy; cost; design; drug development; innovation; new technology; public health relevance; response

DESCRIPTION: Technological change is a central feature of health care markets and over the past few decades has revolutionized the treatment of many medical conditions. Although breakthrough scientific advances are an important driver of the pace of medical innovation, market incentives - such as those provided by the patent system - are often a critical determinant of which potential technologies successfully make the transition 'from the lab to the market.' The key contribution of this project is to develop new data (Aims 1 and 3) and new empirical methods (Aims 2 and 4) to investigate how patents shape the development and diffusion of medical innovations. Specifically, we apply these new data and new methods to estimate two relevant parameters: the extent to which patents provide incentives for the development of new technologies, and the extent to which patents on existing technologies hinder subsequent innovation. The more effective patents are in inducing research investments, the stronger the case for longer or broader patents. On the other hand, the larger the costs of patents in terms of hindering subsequent innovation, the weaker is this case. Evaluating these costs and benefits of patents is a key input into optimal policy design. To estimate the first parameter - how the prospect of stronger patent protection affects research investments - we develop a new empirical method (Aim 2) based on the following idea: because pharmaceutical firms file patents prior to starting clinical trials, shorter clinical trials grant firms longer efective patent terms. Hence, if longer patent terms encourage more research investments, we should see higher levels of research investments on treatments for patient groups that require shorter clinical trials. We apply this method to a newly developed data set measuring research investments on treatments for cancer patients (developed in Aim 1). To estimate the second parameter - how patents on existing technologies affect subsequent research investments - we develop a new empirical method (Aim 4). The key idea behind our approach is to take advantage of two facts: first, patent applications are quasi- randomly assigned to patent examiners at the US Patent and Trademark Office; and second, patent examiners differ in their likelihood of awarding a patent to any given application. We apply this method to a newly- developed data set measuring research investments related to the human genome (developed in Aim 3) and quantify the extent to which patents on human genes have hindered subsequent medical innovation. The new empirical methods (Aims 2 and 4) will be applied to two particular classes of medical technologies - cancer treatments and gene-based diagnostics and treatments - but each method can be applied in other contexts. In addition, the new data construction methods (Aims 1 and 3) - text-based matching with clinical trial enrollment lists, and MeSH-ICD matching of research investments to the relevant groups of patients - can also be applied in other contexts.

技术变革是医疗保健市场的核心特征，在过去的几十年里，技术变革已经彻底改变了许多医疗条件的治疗。尽管突破性的科学进步是推动医疗创新步伐的重要因素，但市场激励——例如专利制度提供的激励——往往是决定哪些潜在技术成功地“从实验室向市场”过渡的关键因素。该项目的主要贡献是开发新的数据（目标1和3）和新的实证方法（目标2和4），以调查专利如何影响医疗创新的发展和传播。具体来说，我们运用这些新数据和新方法来估计两个相关参数：专利对新技术开发的激励程度，以及现有技术专利对后续创新的阻碍程度。专利在吸引研究投资方面越有效，越有必要延长或扩大专利期限。另一方面，在阻碍后续创新方面，专利成本越大，这种情况就越弱。评估专利的这些成本和收益是优化政策设计的关键投入。为了估计第一个参数——更强的专利保护前景如何影响研究投资——我们基于以下想法开发了一种新的实证方法（目标2）：因为制药公司在开始临床试验之前申请专利，较短的临床试验授予公司较长的有效专利期限。因此，如果更长的专利期限鼓励更多的研究投资，我们应该看到对需要更短临床试验的患者群体的治疗的更高水平的研究投资。我们将此方法应用于新开发的测量癌症患者治疗研究投资的数据集（在Aim 1中开发）。为了估计第二个参数——现有技术的专利如何影响后续的研究投资——我们开发了一种新的实证方法（目标4）。我们的方法背后的关键思想是利用两个事实：首先，专利申请是准随机分配给美国专利商标局（US patent and Trademark Office）的专利审查员的；其次，专利审查员对任何给定申请授予专利的可能性不同。我们将这种方法应用于一个新开发的数据集，该数据集测量了与人类基因组相关的研究投资（在Aim 3中开发），并量化了人类基因专利阻碍后续医学创新的程度。新的经验方法（目标2和目标4）将应用于两类特殊的医疗技术——癌症治疗和基于基因的诊断和治疗——但是每种方法都可以应用于其他情况。此外，新的数据构建方法（目标1和目标3）-基于文本的临床试验入组列表匹配，以及研究投资与相关患者组的MeSH-ICD匹配-也可以应用于其他情况。