泌尿外科展望: 20年后
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<h2 style="color: black; text-align: left; margin-bottom: 10px;"> <span style="color: black;">自史前<span style="color: black;">败兴</span>,<span style="color: black;">咱们</span>对泌尿学的认识越来越深入。从最初泌尿外科<span style="color: black;">大夫</span><span style="color: black;">运用</span>尿液<span style="color: black;">做为</span>治疗的<span style="color: black;">药品</span>,到<span style="color: black;">此刻</span><span style="color: black;">大夫</span>利用多<span style="color: black;">方向</span>活动的机械臂远程切除肾脏,并且<span style="color: black;">能够</span><span style="color: black;">同期</span><span style="color: black;">运用</span>图像叠加技术以<span style="color: black;">加强</span>图像效果。本文对20年后泌尿外科技术的可能<span style="color: black;">状况</span>进行综述,对影像学、诊断、<span style="color: black;">设备</span>人技术和其他可能的新技术的发展进行分析<span style="color: black;">评定</span>。<span style="color: black;">尤其</span>强调了微创技术、纳米技术和组织工程学等有前景的<span style="color: black;">行业</span>,这些很可能是泌尿外科新时代的<span style="color: black;">重要</span>所在。</span></h2>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"><strong style="color: blue;"><span style="color: black;">前言</span></strong></span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">从史前时代起,泌尿学就吸引了人类,从观察尿液及其潜在的治疗特性到利用芦苇减轻膀胱梗阻症状。几千年后,随着对解剖学和医学认识的<span style="color: black;">持续</span>深入,泌尿外科实践正<span style="color: black;">处在</span>一个特殊的<span style="color: black;">周期</span>,在这个<span style="color: black;">周期</span>中,人们<span style="color: black;">重点</span>致力于<span style="color: black;">供给</span>微创、个性化和靶向治疗等技术在<span style="color: black;">疾患</span>治疗中的<span style="color: black;">科研</span>。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">在这个快速革新的时代,本文探讨到2038年泌尿外科技术的发展方向。影像学、诊断、<span style="color: black;">设备</span>人技术和<span style="color: black;">将来</span>新技术将会进行分析。<span style="color: black;">然则</span>泌尿外科是一个<span style="color: black;">处在</span><span style="color: black;">科研</span>和创新前沿的科学,<span style="color: black;">因此呢</span>本文只能<span style="color: black;">供给</span>对当前发展的一瞥。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"><strong style="color: blue;"><span style="color: black;">影像技术与诊断</span></strong></span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">20年的时间,影像技术和诊断方面将会<span style="color: black;">出现</span>很大的变化,<span style="color: black;">包含</span>现有技术的改进和新技术的应用。窄带光<span style="color: black;">影像</span>(NBI)只是其中一项新技术,它是在内窥镜中<span style="color: black;">运用</span>特定的蓝色和绿色波长的光来<span style="color: black;">加强</span>粘膜细节的<span style="color: black;">表示</span>。与<span style="color: black;">日前</span>广泛应用的白光膀胱镜相比,NBI<span style="color: black;">拥有</span>更强的检测癌组织的能力,<span style="color: black;">科研</span><span style="color: black;">发掘</span>NBI用于经尿道膀胱肿瘤电切术减少了肿瘤的复发。这种<span style="color: black;">影像</span>技术可能<span style="color: black;">亦</span>有益于<span style="color: black;">哪些</span>非肌层浸润性膀胱癌<span style="color: black;">病人</span>,<span style="color: black;">同期</span>它可能对其他泌尿系统癌症<span style="color: black;">亦</span>有<span style="color: black;">帮忙</span>。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">磁共振<span style="color: black;">影像</span>(MRI)在诊断中的应用<span style="color: black;">亦</span>将<span style="color: black;">经过</span>纳米技术的开创而得到改进,<span style="color: black;">包含</span>将磁性纳米颗粒附着到特定的<span style="color: black;">目的</span>上,例如淋巴结转移,<span style="color: black;">而后</span><span style="color: black;">能够</span>在MRI上<span style="color: black;">表示</span>。<span style="color: black;">另外</span>,人们<span style="color: black;">已然</span><span style="color: black;">发掘</span>在前列腺癌局部治疗后<span style="color: black;">病人</span>的随访中的应用, MRI<span style="color: black;">显著</span>优于前列腺特异性抗原(PSA)。<span style="color: black;">况且</span>,<span style="color: black;">经过</span>多参数<span style="color: black;">影像</span>,MRI-超声融合前列腺穿刺活检获取前列腺组织<span style="color: black;">能够</span>改进Gleason评分,<span style="color: black;">拥有</span>巨大前景。将来,<span style="color: black;">倘若</span>MRI<span style="color: black;">检测</span>成本<span style="color: black;">能够</span>降低,这些技术将会得到更广泛的应用。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">MRI技术的最新<span style="color: black;">发展</span><span style="color: black;">包含</span>7T MRI,与<span style="color: black;">日前</span>的1.5T和3T相比,该MRI在诊断技术方面有了重大改进。<span style="color: black;">经过</span><span style="color: black;">加强</span>的空间分辨率和<span style="color: black;">加强</span>的血管信号,该技术<span style="color: black;">供给</span>更好的诊断质量,<span style="color: black;">供给</span>更准确的腹部病理学诊断,如在前列腺中的应用。<span style="color: black;">经过</span>识别几乎所有前列腺癌都表达的前列腺特异性膜抗原(PSMA),还<span style="color: black;">能够</span>加强对前列腺癌复发的检测。<span style="color: black;">经过</span>68Ga-PSMA-11PET/CT,这种抗原有望取代<span style="color: black;">日前</span><span style="color: black;">运用</span>的18F-胆碱PET CT,前者在鉴别前列腺癌复发和前列腺外转移方面<span style="color: black;">拥有</span><span style="color: black;">优良</span>。<span style="color: black;">另外</span>,<span style="color: black;">近期</span>的<span style="color: black;">科研</span><span style="color: black;">显示</span>,<span style="color: black;">因为</span>其高<span style="color: black;">敏锐</span>性和特异性,68Ga-PSMA-11 PET/CT在前列腺癌转移的分期中的应用可能还有额外用处。将来<span style="color: black;">经过</span>开展多中心前瞻性临床<span style="color: black;">实验</span>,68Ga-PSMA-11 PET/CT<span style="color: black;">能够</span>直接与传统扫描进行比较,以便更好地认识该<span style="color: black;">办法</span><span style="color: black;">是不是</span><span style="color: black;">加强</span>了初次分期的诊断能力,并对患者随后的管理产生积极影响。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">除了PET/CT,<span style="color: black;">日前</span><span style="color: black;">科研</span><span style="color: black;">显示</span>PSMA PET/MRI在识别CT上可能遗漏的转移淋巴结方面<span style="color: black;">拥有</span><span style="color: black;">显著</span>的<span style="color: black;">优良</span>。PSMA PET/MRI诊断技术在PSA水平较低时有独到之处,它<span style="color: black;">拥有</span>局部复发的高检出率。<span style="color: black;">另外</span>,PSMA在局部挽救疗法中还<span style="color: black;">拥有</span><span style="color: black;">必定</span><span style="color: black;">功效</span>,例如<span style="color: black;">运用</span>镥-177标记PSMA(177-Lu-PSMA),其直接治疗前列腺癌,并可减少副<span style="color: black;">功效</span>。除了局部治疗之外,还<span style="color: black;">发掘</span>177-Lu-PSMA治疗对去势抵抗嗜PSMA转移性前列腺癌<span style="color: black;">病人</span><span style="color: black;">拥有</span>较高的应答率。然而,在正式<span style="color: black;">运用</span>这种治疗<span style="color: black;">办法</span>之前,还<span style="color: black;">必须</span><span style="color: black;">更加多</span>的<span style="color: black;">科研</span>,<span style="color: black;">况且</span>很可能在<span style="color: black;">将来</span>二十年中会<span style="color: black;">发掘</span><span style="color: black;">更加多</span>的特异性配体能够为所有人<span style="color: black;">供给</span>更加个性化的治疗<span style="color: black;">办法</span>,可能会<span style="color: black;">作为</span>泌尿外科诊疗<span style="color: black;">发展</span>的<span style="color: black;">重要</span>部分。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">除了影像技术,肿瘤标志物可能会变得更加精细。<span style="color: black;">近期</span><span style="color: black;">发掘</span>的两种监测肿瘤负荷的标志物是血清microRNA和循环肿瘤细胞(CTC)。最新<span style="color: black;">科研</span>揭示,由Ashworth<span style="color: black;">首要</span><span style="color: black;">发掘</span>的CTCs能够最好地预测转移性去势抵抗前列腺癌<span style="color: black;">病人</span>的存活率,其低水平<span style="color: black;">显示</span>预后良好。<span style="color: black;">另外</span>,<span style="color: black;">经过</span>对细胞的基因组分析,CTCs可应用于识别肿瘤的特异性治疗靶点。<span style="color: black;">况且</span>,特异性microRNA和miR-371a-3p是最新<span style="color: black;">发掘</span>的对睾丸生殖细胞肿瘤既<span style="color: black;">敏锐</span>又特异的新的生物标志物,比<span style="color: black;">日前</span>用于诊断的血液检测<span style="color: black;">办法</span>更为<span style="color: black;">敏锐</span>。这些肿瘤标志物,以及<span style="color: black;">近期</span><span style="color: black;">发掘</span>的<span style="color: black;">经过</span>狗嗅病人尿液来识别前列腺癌的能力,<span style="color: black;">明显</span>了将来筛选和监测病人以及<span style="color: black;">帮忙</span>基于基因组学的“个性化医学”蓬勃发展的潜在<span style="color: black;">功效</span>。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"><strong style="color: blue;"><span style="color: black;"><span style="color: black;">设备</span>人技术</span></strong></span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">泌尿外科先驱们在<span style="color: black;">设备</span>人<span style="color: black;">行业</span>取得了巨大<span style="color: black;">发展</span>。<span style="color: black;">设备</span>人技术已被采用,<span style="color: black;">由于</span>它<span style="color: black;">拥有</span>微创性,<span style="color: black;">能够</span><span style="color: black;">供给</span>3D视觉和放大视野以及<span style="color: black;">供给</span>更高的精度和灵活性。然而,现有的<span style="color: black;">设备</span>人技术存在<span style="color: black;">非常多</span>问题,<span style="color: black;">包含</span>器械的<span style="color: black;">外边</span>碰撞,缺乏触觉反馈,以及难以在手术区域<span style="color: black;">周边</span>维持三角形划分。<span style="color: black;">因此呢</span>,新的单孔平台<span style="color: black;">已然</span>应用于<span style="color: black;">设备</span>人技术,仅有一个进入<span style="color: black;">病人</span><span style="color: black;">身体</span>的入口。这个单孔通道<span style="color: black;">能够</span>容纳一个摄像机和多个<span style="color: black;">设备</span>人仪器,<span style="color: black;">同期</span>只<span style="color: black;">必须</span>达芬奇<span style="color: black;">设备</span>人系统的一个手臂。<span style="color: black;">另外</span>,通道内的器械<span style="color: black;">拥有</span>活动关节,为使器械更加灵巧,其<span style="color: black;">增多</span>了<span style="color: black;">身体</span>三角形划分。在<span style="color: black;">包括</span>19名<span style="color: black;">病人</span>的临床<span style="color: black;">实验</span>中,这种单孔技术被证明是成功的。当前<span style="color: black;">设备</span>人的进一步改进<span style="color: black;">包含</span>安装带有内置传感器的液压<span style="color: black;">操作</span>器以<span style="color: black;">加强</span>器械<span style="color: black;">精细</span>度,以及利用萤火虫技术以更好地进行肾肿瘤肾部分切除术。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">新的<span style="color: black;">设备</span>人程序<span style="color: black;">亦</span>可能在<span style="color: black;">将来</span>实施。为了在<span style="color: black;">无</span>切口和散射的<span style="color: black;">状况</span>下实现肿瘤的完全切除,新的程序<span style="color: black;">能够</span><span style="color: black;">包含</span>对非肌层浸润性移行细胞癌进行<span style="color: black;">设备</span>人整块切除,以及采用会阴入路的<span style="color: black;">设备</span>人根治性前列腺切除术。<span style="color: black;">另外</span>,<span style="color: black;">将来</span><span style="color: black;">设备</span>人技术(如Telelap ALF-X)的进步,<span style="color: black;">经过</span><span style="color: black;">运用</span>3D眼镜来<span style="color: black;">增多</span>外科<span style="color: black;">大夫</span>的情境感知,从而改善达芬奇<span style="color: black;">设备</span>人的手术环境,而不是包住外科<span style="color: black;">大夫</span>的脸,<span style="color: black;">同期</span><span style="color: black;">供给</span>触觉反馈技术。<span style="color: black;">设备</span>人将来可能对所有<span style="color: black;">病人</span>群体都可用,部分<span style="color: black;">原由</span>是许多知识产权专利到期,从而降低了成本。正如<span style="color: black;">近期</span>对65名儿童的回顾所强调的那样,<span style="color: black;">设备</span>人技术正在儿童泌尿学<span style="color: black;">行业</span>得到越来越多的认可。尽管<span style="color: black;">因为</span>更小和更<span style="color: black;">繁杂</span>的解剖结构而面临<span style="color: black;">显著</span>的挑战,<span style="color: black;">然则</span><span style="color: black;">能够</span>学习技术手段,例如膀胱减压,以克服这些<span style="color: black;">阻碍</span>。<span style="color: black;">设备</span>人泌尿外科的<span style="color: black;">将来</span>是令人兴奋的,并将改善术后结果和病人满意度。然而,它会在结构、人员和技术方面变得更加<span style="color: black;">繁杂</span>,<span style="color: black;">因此呢</span><span style="color: black;">必要</span><span style="color: black;">持续</span>加以<span style="color: black;">仔细</span>审查。<span style="color: black;">另一</span>,在许多手术如根治性肾切除术中,并<span style="color: black;">无</span>证明<span style="color: black;">设备</span>人手术优于腹腔镜手术,这<span style="color: black;">显示</span>仍然<span style="color: black;">必须</span>做出<span style="color: black;">更加多</span>的改进,<span style="color: black;">尤其</span>是在资源有限的医疗保健系统中。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"><strong style="color: blue;"><span style="color: black;">微创技术</span></strong></span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">这个时代,技术正在<span style="color: black;">持续</span>改进以降低感染率和缩短住院时间,微创治疗在<span style="color: black;">将来</span>20年的应用肯定会越来越<span style="color: black;">广泛</span>。例如,<span style="color: black;">日前</span><span style="color: black;">运用</span>精确定位和活检的前列腺癌冷冻消融治疗是非常有前景的,尽管其还<span style="color: black;">必须</span><span style="color: black;">更加多</span>的临床<span style="color: black;">实验</span>来验证。很可能计算机和<span style="color: black;">设备</span>人辅助的<span style="color: black;">办法</span>将有助于冷冻疗法的革命,并将其推向新的高度。<span style="color: black;">另外</span>,射频消融(RFA)治疗肾癌已被证明是安全有效的,<span style="color: black;">尤其</span>是<span style="color: black;">针对</span><span style="color: black;">哪些</span><span style="color: black;">不可</span>耐受手术的<span style="color: black;">病人</span>。与部分肾切除相比,RFA在<span style="color: black;">保存</span><span style="color: black;">更加多</span>肾组织的<span style="color: black;">同期</span>,<span style="color: black;">拥有</span>更好的预后。<span style="color: black;">然则</span>,RFA并不适用于所有肿瘤,肿瘤大于5cm<span style="color: black;">拥有</span>较高的失败率;<span style="color: black;">将来</span>的<span style="color: black;">发展</span>很可能会改善这一点。最后介绍的消融治疗是高频超声(HIFU),它<span style="color: black;">能够</span>用于前列腺癌放疗后复发的挽救治疗。这种<span style="color: black;">办法</span>减少了挽救性前列腺切除术<span style="color: black;">关联</span>的并发症,<span style="color: black;">同期</span><span style="color: black;">拥有</span>良好的临床效果。在今后20年中,<span style="color: black;">经过</span>实时<span style="color: black;">影像</span>技术(例如超声)的<span style="color: black;">运用</span>,该技术可能会受益,它<span style="color: black;">能够</span><span style="color: black;">供给</span>关于HIFU操作过程中的实时质量反馈。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">显然,微创技术在治疗尿路结石方面<span style="color: black;">拥有</span>广阔的前景,在过去几年中输尿管镜和经皮肾取石术(PCNL)的<span style="color: black;">运用</span><span style="color: black;">明显</span><span style="color: black;">增多</span>,开放性手术减少。Uro Dyna-CT技术<span style="color: black;">能够</span><span style="color: black;">经过</span><span style="color: black;">创立</span>实时立体横断面图像以改进PCNL过程,<span style="color: black;">经过</span>诸如此类<span style="color: black;">办法</span>的应用<span style="color: black;">能够</span>使<span style="color: black;">此刻</span>的技术进一步<span style="color: black;">加强</span>,<span style="color: black;">同期</span>还<span style="color: black;">能够</span><span style="color: black;">增多</span>清石率。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">此外,PCNL概念自1976年提出<span style="color: black;">败兴</span><span style="color: black;">已然</span>得到<span style="color: black;">快速</span>发展。除了<span style="color: black;">以上</span>新颖<span style="color: black;">影像</span>技术的应用,许多器械<span style="color: black;">机构</span><span style="color: black;">已然</span>着手将设备微型化,这有助于降低并发症,<span style="color: black;">同期</span><span style="color: black;">增多</span>了治疗所有人群中困难结石的能力。<span style="color: black;">因此呢</span>,在接下来的20年里,这些微型PCNL技术将很可能<span style="color: black;">作为</span>结石治疗的<span style="color: black;">要紧</span><span style="color: black;">办法</span>。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"><strong style="color: blue;"><span style="color: black;">新时代</span></strong></span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">随着良性前列腺增生和梗阻在<span style="color: black;">咱们</span>日益老龄化的人口中越来越<span style="color: black;">广泛</span>,寻找改进的治疗技术变得越来越<span style="color: black;">要紧</span>。有可能取代经尿道前列腺切除术(TURP)和开放性前列腺切除术(OP)的新的治疗技术是钬激光前列腺剜除术(HoLEP)和铥激光前列腺剜除术。两种<span style="color: black;">办法</span>治疗良性前列腺增生<span style="color: black;">拥有</span>同等的临床疗效和安全性。<span style="color: black;">另外</span>,最新<span style="color: black;">科研</span><span style="color: black;">显示</span>,<span style="color: black;">保存</span>尿道粘膜的改良HoLEP<span style="color: black;">能够</span>使病人在一天之内出院,从而进一步<span style="color: black;">加强</span>病人的治疗标准。然而,值得<span style="color: black;">重视</span>的是,虽然与TURP相比,<span style="color: black;">日前</span>铥激光前列腺剜除术的手术时间更长,<span style="color: black;">然则</span>随着时间推移技术会<span style="color: black;">持续</span>改进。前列腺动脉栓塞术是良性前列腺增生症的<span style="color: black;">另一</span>一种治疗技术。这种<span style="color: black;">办法</span>对供应前列腺的动脉进行治疗性闭塞,是一种比HoLEP等微创<span style="color: black;">办法</span>更安全的替代<span style="color: black;">方法</span>,并且<span style="color: black;">能够</span>在门诊开展。然而,在该<span style="color: black;">办法</span><span style="color: black;">能够</span><span style="color: black;">做为</span>标准化治疗之前,还<span style="color: black;">必须</span>进行深入<span style="color: black;">科研</span>以便更好地分析其并发症及临床效果。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"><span style="color: black;">另一</span>,随着慢性肾脏<span style="color: black;">疾患</span>越来越<span style="color: black;">广泛</span>,组织再生似乎是<span style="color: black;">将来</span>的<span style="color: black;">要紧</span>技术。在不久的将来,组织工程和再生医学的结合可能会<span style="color: black;">科研</span>出人造肾脏。随着3D打印技术越来越成熟,人造生物材料<span style="color: black;">特别有</span>可能<span style="color: black;">显现</span>,尽管<span style="color: black;">因为</span>器官的异质性可能会<span style="color: black;">引起</span><span style="color: black;">有些</span>困难的<span style="color: black;">显现</span>。在组织再生<span style="color: black;">行业</span>,<span style="color: black;">日前</span><span style="color: black;">科研</span>的热点是膀胱脱细胞基质(BAM)。该技术有可能会改进手术过程,以扩大或替代膀胱,以往该手术曾<span style="color: black;">引起</span><span style="color: black;">各样</span>并发症的<span style="color: black;">显现</span>,<span style="color: black;">例如</span>结石、恶性肿瘤和菌尿。当接种干细胞时,BAM<span style="color: black;">做为</span>组织再生工程的支架发挥<span style="color: black;">功效</span>,可能会为创建新膀胱和治疗肌层浸润性膀胱癌带来革命性的改变。干细胞治疗在泌尿外科有望取得重大<span style="color: black;">发展</span>,但还有表观遗传学改变、免疫反应和感染等<span style="color: black;">阻碍</span><span style="color: black;">必须</span>克服。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"><span style="color: black;">一样</span>,纳米技术将会辅助靶向治疗,走在最前沿。纳米粒子,<span style="color: black;">少于</span>等于1000纳米,已有<span style="color: black;">科研</span>利用其搭载化疗<span style="color: black;">药品</span>(如阿霉素),<span style="color: black;">发掘</span>其<span style="color: black;">拥有</span>较<span style="color: black;">有效</span>率,并且<span style="color: black;">能够</span>在<span style="color: black;">身体</span>维持持久的化疗效果。<span style="color: black;">另外</span>,<span style="color: black;">已然</span>证明纳米颗粒是基因治疗的有效<span style="color: black;">器具</span>,<span style="color: black;">由于</span>它们在将遗传物质携带到细胞中方面比病毒载体更安全有效。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"><span style="color: black;">咱们</span>还<span style="color: black;">重视</span>到纳米粒子介导的激光治疗在超声和MRI技术的辅助下<span style="color: black;">拥有</span>前列腺肿瘤特异性的定向消融<span style="color: black;">功效</span>。虽然<span style="color: black;">日前</span>的<span style="color: black;">科研</span>规模有限,但激光的<span style="color: black;">运用</span>在临床上是安全有效的。然而,在接下来的几年里该技术普及之前,<span style="color: black;">咱们</span><span style="color: black;">必须</span><span style="color: black;">更加多</span>的<span style="color: black;">科研</span>数据。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">在靶向<span style="color: black;">药品</span>和治疗方面,纳米技术将是<span style="color: black;">将来</span>泌尿外科设备和<span style="color: black;">影像</span>技术的<span style="color: black;">重要</span>。例如,与典型的聚氨酯支架相比,<span style="color: black;">运用</span>可降解纳米纤维材料的输尿管支架将有助于降低炎症和感染<span style="color: black;">出现</span>率。<span style="color: black;">另一</span>,EnSealTM纳米技术<span style="color: black;">经过</span>在较低温度下产生止血效果,起到减少对邻近组织的<span style="color: black;">损害</span><span style="color: black;">功效</span>,来减少腹腔镜手术中热<span style="color: black;">损害</span>的缺点。最后,纳米颗粒能够渗入肿瘤间质<span style="color: black;">从而</span><span style="color: black;">加强</span>MRI扫描效果,随后可在后续<span style="color: black;">影像</span>中进行强化,从而<span style="color: black;">加强</span>癌症识别的<span style="color: black;">敏锐</span>性和特异性。<span style="color: black;">期盼</span>这些<span style="color: black;">发展</span>在<span style="color: black;">将来</span>能够普及。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">随着<span style="color: black;">海量</span>新技术的<span style="color: black;">显现</span>,<span style="color: black;">将来</span>泌尿科<span style="color: black;">大夫</span>的培训比以往任何时候都更加<span style="color: black;">要紧</span>。尽管<span style="color: black;">日前</span>模拟器是培训的核心部分,<span style="color: black;">然则</span><span style="color: black;">因为</span>计算能力和交互性的<span style="color: black;">加强</span>,<span style="color: black;">将来</span>的模拟器将实现<span style="color: black;">加强</span>现实和虚拟现实。这项技术将在许多方面被<span style="color: black;">运用</span>,例如利用医学<span style="color: black;">影像</span>来创建用于直肠指检的3D模拟器,<span style="color: black;">帮忙</span>外科<span style="color: black;">大夫</span>更好地理解<span style="color: black;">检测</span>过程。<span style="color: black;">另外</span>,新技术将有助于“远程外科”手术的发展。最后,值得<span style="color: black;">重视</span>的是,<span style="color: black;">日前</span>正在虚拟会诊以及会诊记录方面取得<span style="color: black;">发展</span>,以进一步<span style="color: black;">加强</span>泌尿外科专业的效率。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"><strong style="color: blue;"><span style="color: black;">结论</span></strong></span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">显然,泌尿外科技术将在<span style="color: black;">将来</span>二十年以<span style="color: black;">各样</span>各样的形式发展,以创建个体化疗法,从而使<span style="color: black;">每一个</span><span style="color: black;">病人</span>都接受有针对性和特异性的治疗,且副<span style="color: black;">功效</span>最小。然而,<span style="color: black;">咱们</span><span style="color: black;">不可</span>疏忽遗传学和靶向治疗的<span style="color: black;">发展</span>可能预示着许多泌尿外科手术(例如减瘤性肾切除)的结束,这些手术可能<span style="color: black;">由于</span>靶向治疗而失宠。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">史前泌尿科医师在治疗病人时可能不得不避开剑齿虎,<span style="color: black;">将来</span>泌尿科学者们的挑战将是利用技术的进步来助力泌尿科技的发展,并更好地治疗有<span style="color: black;">必须</span>的病人。</span></p>
<h1 style="color: black; text-align: left; margin-bottom: 10px;"><span style="color: black;">Urological technology: where will we be in 20 years’ time?<strong style="color: blue;">Article</strong> in </span><span style="color: black;">Therapeutic Advances in Urology</span><span style="color: black;">10(6):175628721878266 · June 2018 with 38 Rea</span><span style="color: black;"><span style="color: black;">ds </span>DOI: </span><span style="color: black;">10.1177/1756287218782666</span></h1>
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感谢楼主的分享!我学到了很多。 你的话深深触动了我,仿佛说出了我心里的声音。 回顾历史,我们感慨万千;放眼未来,我们信心百倍。
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