以下文章轉(zhuǎn)載自:
American Journal of Neuroradiology
Presurgical Mapping with fMRI and DTI: Soon the Standard of Care?
The technique of fMRI has been around for over 30 years, and DTI for about 15 years. The first application of fMRI was by Ogawa et al, in 1990. In a rat model, this team was able to manipulate the blood oxygen level–dependent (BOLD) signal by inducing changes in deoxyhemoglobin concentrations with insulin-induced hypoglycemia and anesthetic gases. About a year later, Kwong and Belliveau published the first images of cerebral areas that responded to visual stimulation and vision-related tasks.
DTI was first described by Basser et al, who were experimenting on a voxel-by-voxel characterization of 3D diffusion profiles, which took into account anisotropic effects (instead of eliminating them, as in standard DWI). Tractography (or fiber tracking) was developed by applying statistical models to DTI data to obtain anatomic fiber bundle information.
Although both fMRI and DTI are now currently available in most scanners, well beyond the framework of academic institutions and research protocols, these techniques are not quite considered “standard of care.” Indeed, the processes that govern the translation of new technology into clinical practice are complex. Even more complex are the processes that lead to establishing clinical practice as standard of care, particularly at a time when established patterns of care delivery are being increasingly challenged and economic difficulties affect all aspects of society, certainly including health care.
However, some challenges, especially with fMRI, go back to basic cerebrovascular physiology. The cerebrovascular response to neuronal activation, also referred to as “functional hyperemia,” was first recognized in 1890 by Roy and Sherrington, who initially proposed a metabolic hypothesis to the phenomenon, ie, mediation via release from neurons of vasoactive agents in the extracellular space. The major role of astrocytes as key intermediaries in the neurovascular response — being interposed between blood vessels and neuronal synapses via their foot processes as modeled in the “tripartite synapse model” of the neurovascular unit — has since been recognized. Although complex, astrocyte response to changes in synaptic activity is primarily mediated by glutamate receptors through changes in intracellular Ca2+ concentration.
In fMRI, contrast is based on the BOLD effect, which reflects local shifts of deoxygenated-to-oxygenated hemoglobin ratios due to local increases in blood flow in excess of oxygen utilization following brain activity. As a result, the foundation of the fMRI BOLD signal is based on local changes in cerebral blood flow that are not linearly related to the metabolic changes inducing the flow change.
Therefore, BOLD fMRI rests on 3 major approximations: 1) the technique does not directly reflect neural activity, ie, generation and propagation of action potentials, synaptic transmission, or neurotransmitter release/uptake; 2) the changes in BOLD signal originate from that portion of the vasculature experiencing the greatest change in oxygen concentration, which occurs in the venules in the immediate vicinity of the active neurons; and 3) more importantly, fMRI signal relies on intact “neurovascular coupling,” the phenomenon that links neural activity to metabolic demand and blood flow changes.
The main reason fMRI is clinically useful most of the time is that under most circumstances neurovascular coupling remains fully intact, unaltered by confounding disorders that can interfere with this relationship. However, it has long been known that neuronal activation results in local blood flow increases that exceed local oxygen consumption, so that the oxygen utilized may constitute a small fraction of the amount delivered. Under normal conditions, the oxygen concentration in draining venules increases during neuronal activation. The original researchers who discovered this phenomenon named it “neurovascular uncoupling” or “neurovascular decoupling.” From a medical perspective, “uncoupling” or “decoupling” implies a pathologic condition, suggesting something abnormal about tissue that demonstrates this phenomenon. More recently, researchers have preferred the term “functional hyperemia” to describe the phenomenon. In fact, when there is interference with the mechanism producing functional hyperemia, the term "neurovascular uncoupling" has been re-applied, albeit with a completely opposite meaning from that originally used. Impairment in the flow response leads to neurovascular uncoupling and a reduced BOLD signal in response to neural activity, which can lead to false-negative errors in fMRI maps.
John Ulmer, reporting on a series of 50 patients, found that although accurate cortical activation could be demonstrated most of the time, various cerebral lesions could cause false negatives in fMRI results when compared with other methods of functional localization, suggesting contralateral or homotopic reorganization of function. He further suggested that pathologic mechanisms such as direct tumor infiltration, neovascularity, cerebrovascular inflammation, and hemodynamic effects from high-flow vascular lesions (ie, arteriovenous malformations and fistulas) could trigger “neurovascular uncoupling” in those patients. Neurovascular uncoupling, and other pitfalls of fMRI, are briefly discussed.
David Mikulis discusses “neurovascular uncoupling syndrome,” where lack of functional hyperemia during neuronal activation can have long-term consequences on the integrity of the tissue in the absence of acute ischemia.
Jay Pillai discusses the successful clinical application of a technique to improve the consistency of BOLD fMRI by using a breath-holding technique.
Aaron Field discusses the technique, clinical use, and some limitations of DTI and tractography, and describes patterns of alteration of white matter fiber tracts by neoplasms and other lesions.
Lastly, Wade Mueller shows that a neurosurgeon may obtain significant improvements in clinical outcomes and a drastic reduction in complication rates when working with a team that provides presurgical mapping of cerebral lesions by using fMRI and DTI (wisely, fully acknowledging their limitations) and when various team members clearly communicate using a common language.
Functional MRI and DTI are extremely useful techniques that have become increasingly available to neuroradiologists in recent years. As with any technique, these work best as parts of a whole. A good understanding of physiologic mechanisms is necessary to make us good “functional” specialists, and a good understanding of the limitations of any technique is necessary to make us better physicians.
Image modified from: Jellison BJ, Field AS, Medow J, et al. Diffusion tensor imaging of cerebral white matter: a pictorial review of physics, fiber tract anatomy, and tumor imaging patterns.
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為滿足廣大用戶對(duì)功能磁共振成像技術(shù)(fMRI)的應(yīng)用需求,幫助磁共振腦成像領(lǐng)域臨床醫(yī)生、科研工作者、研究生群體快速掌握腦功能課題的實(shí)驗(yàn)任務(wù)設(shè)計(jì)、影像數(shù)據(jù)處理和分析的基本原理和實(shí)操方法。4月12日至14日,由美德醫(yī)療主辦的第13屆Task-fMRI基礎(chǔ)培訓(xùn)班在深圳總部成功舉辦!特邀深圳大學(xué)心理學(xué)院成曉君教授、王超教授、林正龍教授等一線青年學(xué)者進(jìn)行授課,講解fMRI的基礎(chǔ)知識(shí),介紹常用數(shù)據(jù)處理工具,帶教實(shí)驗(yàn)設(shè)計(jì)、任務(wù)編寫(xiě)和數(shù)據(jù)處理全流程操作,采用了實(shí)踐操作與理論講解相結(jié)合的教學(xué)方式,注重培養(yǎng)學(xué)員的自主操作能力,幫助學(xué)員們深入理解Task-fMRI技術(shù)的原理和應(yīng)用。培訓(xùn)班濟(jì)濟(jì)一堂,廣大學(xué)員皆對(duì)腦科學(xué)有著高度的學(xué)習(xí)熱情和探究精神,為T(mén)ask-fMRI相關(guān)知識(shí)和技能的掌握及應(yīng)用,奠定了堅(jiān)實(shí)的基礎(chǔ)。為期三天緊湊而豐富的教學(xué)及實(shí)操課程,讓一眾學(xué)員們表示受益匪淺,更是積極與講師深入交流解己所惑。未來(lái),美德醫(yī)療將繼續(xù)開(kāi)展影像技術(shù)培訓(xùn),促進(jìn)相關(guān)知識(shí)和技能的普及和應(yīng)用,并持續(xù)將客戶需求轉(zhuǎn)化到產(chǎn)品優(yōu)化與技術(shù)服務(wù)!
重大喜訊,2024年04月07日,美德醫(yī)療自主研發(fā)的“磁共振病人監(jiān)護(hù)儀”成功獲批廣東省藥品監(jiān)督管理局頒發(fā)的《醫(yī)療器械注冊(cè)證》。該產(chǎn)品的上市,標(biāo)志著美德醫(yī)療成為國(guó)產(chǎn)無(wú)磁監(jiān)護(hù)領(lǐng)域首家注冊(cè)上市的企業(yè),不僅彰顯了我司對(duì)磁兼容醫(yī)療設(shè)備研發(fā)的專業(yè)技術(shù)實(shí)力,也意味著美德醫(yī)療邁入了一個(gè)更高標(biāo)準(zhǔn)、更高起點(diǎn)、更高層次的新平臺(tái),為更多的患者和醫(yī)療機(jī)構(gòu)提供磁共振環(huán)境下安全、高效、先進(jìn)的整體解決方案!未來(lái),我們將不斷提升產(chǎn)品質(zhì)量和服務(wù)水平,繼續(xù)加大研發(fā)投入,推動(dòng)技術(shù)創(chuàng)新和產(chǎn)品升級(jí),為醫(yī)療影像事業(yè)的發(fā)展貢獻(xiàn)更多的智慧和力量!
2024年3月29日-31日,由電子科技大學(xué)生命科學(xué)與技術(shù)學(xué)院、四川省醫(yī)學(xué)科學(xué)院?四川省人民醫(yī)院聯(lián)合主辦的“首屆天府孤獨(dú)癥腦科學(xué)國(guó)際論壇”在電子科技大學(xué)清水河校區(qū)成功舉辦。本次會(huì)議邀請(qǐng)了從事孤獨(dú)癥研究的神經(jīng)科學(xué)、遺傳學(xué)、心理認(rèn)知學(xué)和臨床、康復(fù)領(lǐng)域的國(guó)內(nèi)外知名專家,面向廣大關(guān)注孤獨(dú)癥的科研人員、臨床醫(yī)生和相關(guān)家庭,從行為、分子、環(huán)路、腦影像及醫(yī)學(xué)干預(yù)與行為矯正等多層面解析孤獨(dú)癥的機(jī)制及精確診斷與治療的前沿方法。大會(huì)還組織家長(zhǎng)-專家圓桌討論,為孤獨(dú)癥家庭與孤獨(dú)癥研究領(lǐng)域?qū)<覀兲峁┟鎸?duì)面探討的機(jī)會(huì),以及舉辦“星星集市”、“湖畔音樂(lè)會(huì)”等公益活動(dòng),展示“來(lái)自星星的孩子”的獨(dú)特藝術(shù)天賦。美德醫(yī)療特別贊助本次會(huì)議,并攜腦科學(xué)相關(guān)產(chǎn)品亮相現(xiàn)場(chǎng),吸引了諸多學(xué)者同仁前來(lái)交流,不少在場(chǎng)的老師和醫(yī)生對(duì)美德醫(yī)療腦功能視聽(tīng)覺(jué)刺激儀在科研及臨床上的貢獻(xiàn)給出了高度評(píng)價(jià)。未來(lái),美德醫(yī)療將堅(jiān)持科學(xué)探索,不斷優(yōu)化產(chǎn)品,為推進(jìn)國(guó)內(nèi)孤獨(dú)癥研究領(lǐng)域多學(xué)科協(xié)同發(fā)展,促進(jìn)孤獨(dú)癥腦影像技術(shù)產(chǎn)學(xué)研用成果轉(zhuǎn)化貢獻(xiàn)力量!
隨著社會(huì)就業(yè)形勢(shì)日漸嚴(yán)峻,國(guó)家大力加強(qiáng)關(guān)于促進(jìn)高校畢業(yè)生就業(yè)的工作部署,為積極響應(yīng)國(guó)家政策,貫徹產(chǎn)教融合與高校共謀發(fā)展,我司也迎來(lái)了深圳技術(shù)大學(xué)健康與環(huán)境工程學(xué)院副院長(zhǎng)康雁教授等一眾老師及學(xué)生的訪企拓崗促就業(yè)專項(xiàng)行動(dòng)。美德醫(yī)療創(chuàng)始人湯潔女士對(duì)康教授一行人的到訪表示熱烈歡迎,通過(guò)共同參觀我司的文化展廳、研發(fā)中心、生產(chǎn)倉(cāng)儲(chǔ)等實(shí)體產(chǎn)業(yè)規(guī)模,向大家詳細(xì)介紹了美德的成長(zhǎng)歷程、企業(yè)文化、專研領(lǐng)域、公司榮譽(yù)、發(fā)展方向等等。在充分了解美德目前的發(fā)展現(xiàn)狀之后,雙方就我司的人才需求結(jié)合學(xué)校的人才培養(yǎng)展開(kāi)了深入的交流,作為深圳專精特新的技術(shù)企業(yè),我司由磁共振第三方部件源頭制作供應(yīng),對(duì)產(chǎn)業(yè)鏈前端-硬件的研發(fā)極其看重。美德大家庭的每一位成員,對(duì)公司有著極高的認(rèn)同和歸屬感,鉆研與熱愛(ài)并行,技能與素養(yǎng)同在。借此交流機(jī)會(huì),希望能與深圳技術(shù)大學(xué)加強(qiáng)合作共同培養(yǎng)專項(xiàng)人才,貼近技術(shù)發(fā)展契合市場(chǎng)需求,為學(xué)生的實(shí)習(xí)實(shí)訓(xùn)就業(yè)提供更多機(jī)會(huì),實(shí)現(xiàn)校企緊密聯(lián)系、資源共享、合作共贏!