Self-Calibrating Diagnostic Digital Radiometer

自校准诊断数字辐射计

• 批准号: 7212096
• 负责人: FRED STERZER
• 金额: $ 31.23万
• 依托单位: MMTC, INC.
• 依托单位国家: 美国
• 财政年份: 2003
• 资助国家: 美国
• 起止时间: 2003-02-01 至 2009-03-01
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7212096
• 关键词: 3-Dimensional; Amplifiers; Appendicitis; Architecture; Arthritis; Blood Vessels; Calibration; California; Chest wall structure; Clinical; Clinical Trials; Consultations; Depth; Detection; Development; Devices; Diagnosis; Diagnostic; Disease; Evaluation; Fever; Frequencies; Germanium; Grant; Hand; Human body; Infection; Inflammation; Inflammatory; Knowledge; Laboratories; Lesion; Malignant Neoplasms; Manufacturer Name; Measurement; Measures; Medical; Medicine; Modification; Monitor; Noise; Operative Surgical Procedures; Pennsylvania; Performance; Phase; Physicians; Procedures; Process; Radiation; Radiation therapy; Recurrence; Safety; San Francisco; Silicon; Simulate; Small Business Funding Mechanisms; Small Business Innovation Research Grant; Subcutaneous Tissue; Surgical wound; Techniques; Temperature; Testing; Thermometers; Time; Tissues; Transistors; Treatment Effectiveness; Treatment Efficacy; United States Food and Drug Administration; United States National Institutes of Health; Universities; Weight; Wound Infection; base; chemotherapy; commercialization; cost; design; detector; digital; drug efficacy; hyperthermia treatment; implantable device; instrument; interest; malignant breast neoplasm; medical schools; microwave electromagnetic radiation; miniaturize; novel; programs; prototype; research clinical testing; size; subcutaneous; two-dimensional

DESCRIPTION (provided by applicant): The overall aim of the proposed Phase II program is to complete the development and evaluation of a self-calibrating, low-cost Handheld Digital Microwave Radiometer that can non-invasively measure subsurface temperatures by simple contact with the human body in order to detect and locate subsurface inflammations. In addition to its use as a contact thermometer for core temperature measurement, promising applications for the Radiometer include detecting infections around post-surgical wounds or implanted devices, locating malignant tumors that cause local temperature increases in subcutaneous tissues, evaluating vascular insufficiencies and inflammatory diseases such as arthritis, and determining the efficacy of treatments for these diseases. The novel architecture of the Radiometer will be implemented using miniaturized microwave components including recently available silicon-germanium microwave transistors for low-noise amplifiers and a high-gain logarithmic amplifier/detector integrated circuit that drastically reduces the gain required to amplify temperature-generated noise to adequate detection levels. A novel low-loss resonant switch using microwave field-effect transistors has been developed to simplify the digital calibration process without the added noise or excessive loss of other available miniaturized switches. The digital calibration and measurement technique developed and proven in previous cabinet mounted digital radiometers will be adapted and used in the proposed Radiometer which will be tested in a specially developed tissue-equivalent 3-D phantom capable of simulating clinically interesting subsurface temperature profiles, and the results will be used to finalize the design of a prototype instrument suitable for laboratory testing leading to a final design suitable for clinical testing. Contacts with manufacturers will be established with the aim of early commercialization. Unlike conventional thermometers, the Handheld Digital Microwave Radiometer will conveniently, quickly, and non-invasively measure subsurface temperatures. The Radiometer will provide new means of locating infections and lesions because of the ability to estimate a temperature-depth relation. The effectiveness of treatments can be quantified by monitoring changes of internal temperatures with medicines or procedures.

描述（由申请人提供）：拟议第二阶段计划的总体目标是完成自校准、低成本手持式数字微波辐射计的开发和评估，该辐射计可以通过与人体的简单接触来非侵入性地测量地下温度身体以检测和定位皮下炎症。除了用作测量核心温度的接触式温度计外，辐射计的潜在应用还包括检测术后伤口或植入设备周围的感染、定位导致皮下组织局部温度升高的恶性肿瘤、评估血管功能不全和炎症性疾病，例如例如关节炎，并确定这些疾病的治疗效果。辐射计的新颖架构将使用小型化微波组件来实现，包括最近可用的用于低噪声放大器的硅锗微波晶体管和高增益对数放大器/检测器集成电路，该电路大大降低了将温度产生的噪声放大到所需的增益。足够的检测水平。已经开发出一种使用微波场效应晶体管的新型低损耗谐振开关，以简化数字校准过程，而不会增加其他可用小型开关的噪声或过多损耗。先前机柜安装的数字辐射计中开发和验证的数字校准和测量技术将在拟议的辐射计中进行调整和使用，该辐射计将在专门开发的组织等效 3D 模型中进行测试，该模型能够模拟临床上感兴趣的地下温度分布，并且结果将用于最终确定适合实验室测试的原型仪器的设计，从而形成适合临床测试的最终设计。将与制造商建立联系，以实现早期商业化。与传统温度计不同，手持式数字微波辐射计可以方便、快速、非侵入地测量地下温度。由于能够估计温度-深度关系，辐射计将提供定位感染和病变的新方法。治疗的有效性可以通过药物或程序监测内部温度的变化来量化。