太赫茲醫療診斷、治療、硬體和材料：市場與技術（2026-2046）

太赫茲波段先前在醫學領域尚屬空白。射頻和光學元件在0.1至10太赫茲的 "太赫茲間隙" 表現不佳，其優勢也不明確。然而，如今一場淘金熱正在興起，石墨烯等新型材料憑藉其等離子體激元模式，在該頻率範圍內展現出卓越的性能。其他二維材料、三元3-5化合物和共聚物也正迅速效法。預計在2026年至2046年間，由此產生的感測器、成像儀、光譜儀，甚至放射治療設備將在全球超過20萬家醫院、醫學研究中心和製藥生產線上部署。在此期間，醫療及相關太赫茲設備的收入預計將增加11倍以上，到2046年達到88億美元。如果能夠克服已發現的挑戰，這項預測可能會被超越。

本報告分析了太赫茲醫療診斷、治療、硬體和材料的市場，並概述了太赫茲技術、醫療應用、設備和系統、研發現狀、按細分市場和地區劃分的市場規模趨勢和預測，以及主要公司的趨勢。

目錄

第一章：摘要整理與結論

• 報告目標和範圍
• 太赫茲醫療及相關技術的核心與外圍主題
• 報告內容概覽
• 研究方法與重點
• 本報告重點介紹的具有醫學應用價值的太赫茲特性
• 太赫茲技術的醫療保健應用
• 主要結論：應用、設備與系統，以及11項SWOT分析
• 四項SWOT分析
  • 太赫茲技術
  • 醫療及相關領域：太赫茲在醫療器材的應用
  • 基於太赫茲的疾病診斷與治療
  • 在6G中加入太赫茲、近紅外線和可見光頻率
• 七項SWOT分析醫用太赫茲硬件
  • 太赫茲生物感測器
  • 太赫茲醫學影像
  • 太赫茲醫學光譜學
  • 太赫茲迴旋管
  • 太赫茲電纜波導
  • 太赫茲醫用雷射器
  • 超材料、超表面和超器件
• 關於太赫茲醫用裝置資料的結論（附分析圓餅圖和資訊圖）
  • 五大結論
  • 太赫茲頻段及實用材質及裝置功能：三個資訊圖
  • 20種材料系列（0.1-1 THz）的損耗因子變化
  • 從盒裝組件（分離電路板、天線等）趨勢到整合式太赫茲智慧材料
• 太赫茲醫用硬體路線圖：技術、部署與市場
• 21 市場預測2026 年至 2046 年的市場展望
  • 太赫茲硬體市場：六大板塊，涵蓋醫療領域
  • 醫療及相關太赫茲硬體市場：光譜、影像及其他
  • 太赫茲醫療及相關硬體市場：四大區域
  • 電磁超構裝置市場
  • 電磁超構裝置市場：依應用領域劃分
  • 6G RIS 市場規模：四種主動和半被動類別（按頻率劃分）

第二章 太赫茲背景、材料、裝置及使能技術

• 概述
  • 太赫茲定義、特性、生物效應、醫療及相關應用
  • 待克服的挑戰、太赫茲差距及智慧材料發展趨勢
• 太赫茲材料及組件選擇
  • 太赫茲產生：挑戰、技術與研究進展
  • 太赫茲探測與調諧材料及裝置
  • 低損耗太赫茲介質：20種材料族的介電常數、損耗因子和介電損耗角正切；太赫茲頻率關係
• 太赫茲層狀結構：天線、自旋電子學與等離子激元學
  • 近期實例
  • 太赫茲天線：挑戰、資訊圖表與研究進展
• 太赫茲自旋電子學與等離子激元學
• 使能技術：超材料與超表面
  • 概述
  • 超材料與超表面的SWOT分析
  • 研究進展
• 太赫茲在醫療及相關應用的二維材料
  • 概述
  • 研究進展
• 太赫茲雷射以及其他相干光源
  • 特性、醫療及相關應用、資訊圖
  • 技術
  • 材料機遇
  • 太赫茲雷射研究進展
  • 晶片級電可調諧相干太赫茲源
• 折射式太赫茲透鏡、用於醫學成像、光譜等的準光學元件

第三章：太赫茲的生理效應及暴露評估

• 概述
• 太赫茲的生理效應（熱效應與非熱效應）
• 太赫茲輻射對囓齒動物神經元放電特性和行為的影響
• 太赫茲暴露評估

第四章：太赫茲醫學診斷及治療

• 概述
• 太赫茲放射治療：2025年至2026年研究進展
  • 以中風患者為例的概述
  • 焦慮症與神經退化性疾病的治療
  • 太赫茲在頭頸部疾病診斷與治療的應用
  • 用於介入或治療神經退化性疾病的神經調控技術
  • 芬太尼過量解毒
• 菌血症的檢測與現場清除
• 太赫茲內視鏡技術的進展
• 在2025年實現視網膜、耳蝸和心臟植入物的精確刺激和無線控制
• 相關太赫茲設備製造商的最新動態
  • TeraSense （美國）
  • Teraview（英國）

第五章 太赫茲影像在醫學上的應用

• 太赫茲成像基礎、醫學化學顯微鏡和超解析度成像
• 太赫茲成像的SWOT分析
• 太赫茲成像的其他進展
  • 奈米顯微鏡
  • 全像成像
  • 太赫茲掃描近場光學顯微鏡
  • 太赫茲影像在皮膚診斷的應用
  • 膠質母細胞瘤的超表面增強太赫茲成像
  • 藥物片劑優化
  • 其他目前非醫學相關的研究進展
• 十大太赫茲成像系統製造商

第六章 太赫茲光譜在醫學上的應用

• 太赫茲光譜學和光譜分析儀
  • 光譜分析儀
  • 範例：利用太赫茲光譜檢測吸菸者呼氣中微量氣體的特徵
  • 範例：太赫茲光譜在蛋白質動力學的應用
  • 例：胺基酸、生物聚合物、血清素等的太赫茲光譜
• 太赫茲醫學光譜的SWOT分析
• 太赫茲超解析度光譜的功能與工具包
  • 功能
  • 工具包
• 2025年至2026年太赫茲超解析度光譜的發展
• 六家太赫茲光譜儀製造商

第七章：用於醫學的太赫茲感測器

• 基礎知識
  • 仿生、輸入、輸出、解剖學和智慧感測器
  • 太赫茲在紅外線感測器的應用（遠紅外線）
  • 太赫茲生物感測器的SWOT分析
• 太赫茲醫學及相關感測領域的幾項重大進展
  • 癌症檢測：乳癌、腦腫瘤
  • 血糖檢測
  • 非法藥物和有害氣體檢測
  • 食品中農藥檢測
  • 苯丙胺酸和其他胺基酸在藥物和診斷的應用
  • 微量蛋白的超靈敏檢測：血清澱粉樣蛋白AA澱粉樣變性
  • 尿膽紅素檢測
• 其他用於醫學及相關應用的太赫茲感測器：多項重大進展2025 至 2026 年

第八章 太赫茲迴旋管在醫學光譜學和新型醫用同位素生產的應用

• 概述
  • 應用與優勢
  • 太赫茲迴旋管的 SWOT 分析
• 太赫茲迴旋管在光譜學的應用：2025 至 2026 年的進展
• 2025 至 2026 年的其他研究
• SHINE Technologies（美國）
• 京都聚變工程（日本）

第九章 太赫茲波導在醫學診斷、感測、樣本檢測和光譜學的應用

• 概述
• 太赫茲電纜波導的 SWOT 分析
• 挑戰、創新與其他進展，2025-2026 年
• 聚合物太赫茲波導（包括長卷電纜）的製造和 3D 列印技術進展，2025-2026 年
• 醫用波導或其組件的製造商和供應商

第十章：醫療領域太赫茲頻率的 6G 通訊計畫

• SWOT 分析：概述
• 6G 演進（2030-2046 年）和太赫茲定位
• 6G 有潛力實現真正的物聯網，造福醫療保健
  • 改善醫院環境、遠距醫療和災害應變
  • 6G 架構及其對醫療保健的益處，包括智慧醫院
  • 改進的行動醫療多媒體應用
  • 6G 人工智慧有潛力實現真正的物聯網，造福醫療保健醫療保健
  • 6G 即時融合生活方式與環境，實現超個人化醫療
• 材料機會：245 篇近期太赫茲及其他 6G 相關光學研究分析
• 以工作頻率劃分的 6G 硬體印刷方案
• 2025 年至 2026 年 6G 通訊太赫茲研究進展
• 中興通訊（中國）

Summary

Terahertz was the medical Wild West. The Terahertz Gap at 0.1-10THz was where neither radio frequency nor optical components worked well and the benefits were unclear. Now it is more like a gold rush, with new materials such as graphene in plasmonic mode working best at those frequencies. Other 2D materials, tertiary 3-5 compounds, co-polymers and more are in hot pursuit. Resulting sensors, imagers, spectrometers and even radiation therapy equipment are being deployed into over 200,000 hospitals and medical research centers and pharmaceutical production lines worldwide 2026-2046. Medical and allied THz equipment sales will grow over eleven-fold over that timeframe to $8.8 billion in 2046. There is upside potential on this forecast if the identified challenges are overcome.

A new Zhar Research report details your opportunities. This 374-page, commercially-oriented, "Terahertz Medical Diagnosis, Therapy, Hardware, Materials: Markets, Technology 2026-2046".

Leading author Dr Peter Harrop, CEO of Zhar Research says, "Most importantly, using THz facilitates increasingly improves detection and treatment of cancers but there is much more in the pipeline, including the equipment becoming portable, its use in design and production of new pharmaceuticals and medical radioisotopes, dentistry and veterinary uses and previously-impossible diagnosis and therapy. To reveal all your opportunities, the report includes these closely allied topics."

Old news is misleading in this now fast-moving topic so the report is intensely focussed on the flood of research advances 2025-6 and gaps in the market given the rather limited number of THz equipment suppliers for what will be needed.

The Executive Summary and Conclusions (55 pages) is self-sufficient for those with limited time. See 11 SWOT appraisals 16 key conclusions, 21 forecast lines 2026-2046 with graphs and explanation plus the main infograms.

Report Statistics:

• Chapters: 10
• SWOT appraisals: 11
• Key conclusions: 16
• Forecast lines to 2046: 21
• New Infograms: 27
• Companies: : 64
• Pages: 374

Table of Contents

1. Executive summary and conclusions

• 1.1 Purpose and scope of this report
• 1.2 Core and peripheral topics involving THz medical and allied technology
• 1.3 Report coverage infogram
• 1.4 Methodology and focus of this analysis
• 1.5 Medically-useful THz characteristics appearing in this report
• 1.6 Healthcare applications of THz technology
• 1.7 Key general conclusions: applications, devices, systems with 11 SWOT appraisals
• 1.8 Four general SWOT appraisals
  • 1.8.1 SWOT appraisal of THz technology
  • 1.8.2 SWOT appraisal of THz use in the medical and allied sectors
  • 1.8.3 SWOT appraisal of THz disease diagnosis and treatment
  • 1.8.4 SWOT appraisal of 6G adding THz, near infrared and visible frequencies
• 1.9 Seven SWOT appraisals of medically-useful THz hardware
  • 1.9.1 SWOT appraisal of THz biosensors
  • 1.9.2 SWOT appraisal of THz medical imaging
  • 1.9.3 SWOT appraisal of THz medical spectroscopy
  • 1.9.4 SWOT appraisal of THz gyrotrons
  • 1.9.5 SWOT appraisal of THz cable waveguides
  • 1.9.6 SWOT appraisal of THz medical lasers
  • 1.9.7 SWOT appraisal for metamaterials, metasurfaces, metadevices
• 1.10 Conclusions concerning THz medical device materials with analysis pie chart, infogram
  • 1.10.1 Five conclusions
  • 1.10.2 Terahertz Gap with useful materials and device capabilities: 3 infograms
  • 1.10.3 Dissipation factor variation for 20 material families 0.1-1THz
  • 1.10.4 Components-in-a-box (discrete boards, antennas etc.) trends to THz smart material integration
• 1.11 THz medical hardware roadmaps: technology, deployment, markets 2026-2046
• 1.12 Market forecasts in 21 lines with tables, graphs and explanation 2026-2046
  • 1.12.1 THz hardware market including medical in six lines $ billion 2026-2046
  • 1.12.2 Medical and allied THz hardware market: spectrometry, imaging, other $ billion 2026-2046
  • 1.12.3 THz Medical and allied hardware value market by four regions 2026-2046
  • 1.12.4 Electromagnetic meta-device market $ billion 2025-2045
  • 1.12.5 Electromagnetic meta-device market $ billion 2025-2046 by application segment
  • 1.12.6 6G RIS value market $ billion: active vs four semi-passive categories by frequency 2026-2046 with explanation

2. Terahertz in context, materials, devices and enabling technologies

• 2.1 Overview
  • 2.1.1 THz definition, characteristics, biological impact, medical, and allied applications
  • 2.1.2 Challenges being overcome, THz gap,, trend to smart materials
• 2.2 Choices of THz material and component
  • 2.2.1 THz generation: challenges, techniques, research advances 2025-6
  • 2.2.2 THz detection and tuning materials and devices
  • 2.2.3 Low-loss THz dielectrics: permittivity and dissipation factor vs THz frequency for 20 material families
• 2.3 Terahertz laminar constructs: antennas, spintronics, plasmonics
  • 2.3.1 Overview with recent examples
  • 2.3.2 Terahertz antennas: challenges, infogram, research advances 2025-6
• 2.4 THz spintronics and plasmonics
• 2.5 Enabling technologies: metamaterials and metasurfaces
  • 2.5.1 Overview
  • 2.5.2 SWOT appraisal for metamaterials and metasurfaces
  • 2.5.3 Research advances 2025-6
• 2.6 THz 2D materials for medical and allied applications
  • 2.6.1 Overview
  • 2.6.2 Research advances 2025-6
• 2.7 THz lasers and other coherent sources
  • 2.7.1 Uniques, medical and allied applications, infogram
  • 2.7.2 Technologies
  • 2.7.3 Materials opportunities
  • 2.7.4 THz laser research advances 2025-6
  • 2.7.5 Chip-scale, electrically-tunable coherent THz source
• 2.8 Refractive THz lenses, quasi-optics for medical imaging, spectroscopy, other

3. THz physiological effects and exposure assessment

• 3.1 Overview
• 3.2 THz physiological effects thermal and non-thermal
• 3.3 Effects of terahertz radiation on neuronal firing characteristics and rodent behavior
• 3.4 THz exposure assessment

4. THz medical diagnosis and treatment

• 4.1 Overview
  • 4.1.1 General
  • 4.1.2 SWOT appraisal of THz disease treatment
• 4.2 THz radiation therapy: rapid research advances 2025-6
  • 4.2.1 General with example of stroke patients
  • 4.2.2 Treating anxiety and neuronal degenerative diseases
  • 4.2.3 THz diagnosis and treatment of head and neck diseases
  • 4.2.4 Neuromodulation technique for intervening or treating neuronal degenerative diseases
  • 4.2.5 Fentanyl overdose reversal
• 4.3 Detection of Bacteremia and In Situ Elimination
• 4.4 Terahertz endoscopy advances through 2025-6
• 4.5 Precise stimulation and wireless control in retinal, cochlear, cardiac implants in 2025
• 4.6 Latest activities of some manufacturers of appropriate THz equipment
  • 4.6.1 TeraSense USA
  • 4.6.2 Teraview UK

5. THz imaging for healthcare

• 5.1 THz imaging basics, medical chemical microscope, super resolution imaging
• 5.2 SWOT appraisal of THz imaging
• 5.3 Other THz imaging advances 2025-6
  • 5.3.1 Nanoscopy
  • 5.3.2 Holography
  • 5.3.3 Terahertz scanning near-field optical microscopy
  • 5.3.4 THz imaging for skin diagnostics
  • 5.3.5 Metasurface-enhanced THz imaging for glioblastoma
  • 5.3.6 Pharmaceutical tablet optimisation
  • 5.3.7 Other relevant research advances not specifically medical at this stage
• 5.4 Ten leading manufacturers of THz imaging systems

6. THz spectroscopy for healthcare

• 6.1 THz spectroscopy and spectrum analysers
  • 6.1.1 Spectroscopy basics
  • 6.1.2 Spectrum analyzers
  • 6.1.3 Example: Trace gas signatures in exhaled breath of a human smoker detected by THz
  • 6.1.4 Example: Terahertz Spectroscopic Analysis in Protein Dynamics
  • 6.1.5 Example: THz spectra of amino acids, biopolymers, serotonin, others
• 6.2 SWOT appraisal of THz medical spectroscopy
• 6.3 THz super-resolution spectroscopy capability, toolkit
  • 6.3.1 Capability
  • 6.3.2 Toolkit
• 6.4 Other THz super-resolution spectroscopy advances through 2025-6
• 6.5 Six THz spectrometer manufacturers

7. THz sensors for healthcare

• 7.1 Basics
  • 7.1.1 Biomimetics, inputs, outputs, anatomy, smart sensors
  • 7.1.2 THz (far infrared) sensors in context of infrared sensors generally
  • 7.1.3 SWOT appraisal of THz biosensors
• 7.2 Some major advances in THz medical and allied sensing
  • 7.2.1 Cancer detection: breast cancer, brain tumour
  • 7.2.2 Blood sugar detection
  • 7.2.3 Illegal drugs and hazardous gases
  • 7.2.4 Pesticide detection in food
  • 7.2.5 Phenylalanine and other amino acids in pharmaceuticals and diagnostics
  • 7.2.6 Ultrasensitive sensing of trace proteins: Serum amyloid AA amyloidosis
  • 7.2.7 Urine bilrubin detection
• 7.3 Other THz sensors for medical and allied applications: many major advances 2025-6

8. THz gyrotrons for medical spectroscopy and manufacture of new medical isotopes

• 8.1 Overview
  • 8.1.1 Uses and benefits
  • 8.1.2 SWOT appraisal of THz gyrotrons
• 8.2 THz gyrotrons for spectroscopy: advances in 2025-6
• 8.3 Other research through 2025-6
• 8.4 SHINE Technologies USA
• 8.5 Kyoto Fusioneering Japan

9. THz waveguides for medical diagnostics, sensing, sample inspection, spectroscopy

• 9.1 Overview
  • 9.1.1 Definition, purpose
  • 9.1.2 Use in medical spectroscopy and exploring biological samples
  • 9.1.3 Basic types of THz waveguides
  • 9.1.4 Materials opportunities
• 9.2 SWOT appraisal of terahertz cable waveguides
• 9.3 Challenges, innovations and other 2025-6 advances
• 9.4 Manufacturing polymer THz waveguides including cable in long reels and 3D printing and 2025-6 advances
• 9.5 Manufacturers and suppliers of medical waveguides or their parts

10. Planned 6G Communication at THz frequencies for healthcare

• 10.1 Overview with SWOT appraisal
• 10.2 Evolution of 6G 2030-2046 and the place of THz
• 10.3 6G may enable genuine Internet of Things benefitting healthcare
  • 10.3.1 Hospital environment, remote healthcare and disaster response improvement
  • 10.3.2 6G architecture and benefits for healthcare including smart hospitals
  • 10.3.3 Mobile health multimedia applications improvement
  • 10.3.4 AI in 6G may enable genuine Internet of Things benefitting healthcare
  • 10.3.5 6G integration of lifestyle and environment in real-time for hyper-personalized medicine
• 10.4 Materials opportunities: Analysis of 245 latest THz and other optical 6G-related research
• 10.5 Printing options for 6G hardware by frequency of operation
• 10.6 Other 6G Communications THz research advances through 2025-6
• 10.7 ZTE China