重磅!复旦大学附庸肿瘤医院/复旦大学邵志敏/江一舟团队颁布要紧综述:癌症代谢的新兴疗法
<img src="https://mmbiz.qpic.cn/mmbiz_jpg/pHzHVM2oJO3VyPAmeSv9AYAeQkCYHiaRiaA5Qz5hHqJa7f9ibpMLwwNZFtk8uUwgyPf5SDKcib3NUX4icFOlTtmdGNA/640?wx_fmt=jpeg&tp=webp&wxfrom=5&wx_lazy=1&wx_co=1" style="width: 50%; margin-bottom: 20px;"><img src="https://mmbiz.qpic.cn/mmbiz_png/pHzHVM2oJO0j4nwztvicmUVecx5m7j7hHdGicuFLncEGhMjDbMvSRdVUyhGSdE84IMSkPGOUXMVYvkSLKtVd9p8w/640?wx_fmt=png&tp=webp&wxfrom=5&wx_lazy=1&wx_co=1" style="width: 50%; margin-bottom: 20px;"><p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">本文为转化医学网原创,转载请注明出处 </p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">作者:Jerry</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">导读:</span><span style="color: black;">癌症中的代谢重编程不仅是一个生物学标志,<span style="color: black;">况且</span>揭示了治疗的弱点。在临床前<span style="color: black;">科研</span>中,许多代谢分子已<span style="color: black;">表示</span>出阻止肿瘤<span style="color: black;">发展</span>的治疗靶点,其中<span style="color: black;">有些</span>已进入临床<span style="color: black;">实验</span>。然而,代谢网络的<span style="color: black;">繁杂</span>性和适应性阻碍了代谢治疗的有效性。</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">近期</span>,复旦大学<span style="color: black;">附庸</span>肿瘤医院/复旦大学邵志敏/江一舟团队受邀在国际权威期刊《Cell Metabolism》上<span style="color: black;">发布</span>了题为“Emerging Therapies in Cancer Metabolism”的长文综述,<strong style="color: blue;">概述了肿瘤的代谢治疗靶点,全面总结了代谢疗法<span style="color: black;">日前</span>的临床<span style="color: black;">实验</span><span style="color: black;">状况</span>。<span style="color: black;">经过</span>分析<span style="color: black;">日前</span>制约肿瘤代谢疗法疗效的<span style="color: black;">原因</span>,从临床<span style="color: black;">方向</span>提出了<span style="color: black;">将来</span>靶向肿瘤代谢的探索方向。</strong></p><img src="https://mmbiz.qpic.cn/mmbiz_jpg/pHzHVM2oJO3VyPAmeSv9AYAeQkCYHiaRia0dDFb7H6SUxUWrCtXh6riaBRfITtwibWD0d02Y0eUwW7smMQtticmm2XA/640?wx_fmt=jpeg&tp=webp&wxfrom=5&wx_lazy=1&wx_co=1" style="width: 50%; margin-bottom: 20px;">
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">https://www.cell.com/cell-metabolism/fulltext/S1550-4131(23)00265-6#%20</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">综述背景</strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"> 01 </span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">代谢重编程是癌症的<span style="color: black;">要紧</span>标志之一。</strong>为了维持<span style="color: black;">连续</span>的增殖和转移,肿瘤细胞经历了几种代谢适应来应对营养缺乏的微环境。癌症代谢的<span style="color: black;">科研</span>始于一个世纪前Otto Warburg的开创性工作,他观察到肿瘤细胞在体外表现出利用有氧糖酵解和产生乳酸的偏好。这种现象后来被<span style="color: black;">叫作</span>为“华宝效应”。从那时起,肿瘤细胞中<span style="color: black;">已然</span><span style="color: black;">发掘</span>了多种代谢重编程事件,<span style="color: black;">包含</span>对电子受体的需求<span style="color: black;">增多</span>,对氧化应激<span style="color: black;">守护</span>的依赖<span style="color: black;">增多</span>以及对氮的需求<span style="color: black;">增多</span>。<span style="color: black;">近期</span>的技术进步进一步证明了癌症代谢在时间和空间上的异质性。肿瘤细胞的代谢表型在不同的癌症中是个体化的,而不是统一的,并且在肿瘤<span style="color: black;">发展</span>过程中<span style="color: black;">持续</span>进化。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;"><span style="color: black;">日前</span>针对癌症<span style="color: black;">病人</span>的代谢治疗存在局限性,提示探索新的靶点和优化治疗策略的价值。</strong>本文概述了新兴的癌症代谢治疗<span style="color: black;">办法</span>,并总结了<span style="color: black;">关联</span>的临床<span style="color: black;">实验</span>。<span style="color: black;">咱们</span>还阐明了影响基于代谢的癌症治疗效果的<span style="color: black;">原因</span>,并从临床<span style="color: black;">方向</span>提出了优化策略。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;"> 综述内容</strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">01 靶向代谢<span style="color: black;">做为</span>一种新兴的肿瘤治疗<span style="color: black;">办法</span></strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"> 02 </span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;"><span style="color: black;">日前</span>肿瘤代谢靶点<span style="color: black;">重点</span>可分为三个方面:靶向肿瘤细胞、靶向肿瘤微环境(TME)以及调节全身代谢。</strong>鉴于癌细胞的高增殖率和活跃的核苷酸合成,干扰核苷酸代谢被认为是一种<span style="color: black;">特别有</span>前途的抗肿瘤治疗策略。新<span style="color: black;">研发</span>的DHODH(嘧啶合成的<span style="color: black;">重要</span>酶)<span style="color: black;">控制</span>剂在临床前模型中<span style="color: black;">亦</span><span style="color: black;">表示</span>出抗肿瘤<span style="color: black;">功效</span>。总的<span style="color: black;">来讲</span>,靶向核苷酸合成在<span style="color: black;">药品</span><span style="color: black;">研发</span>中有着悠久的历史,有几种临床<span style="color: black;">准许</span>的<span style="color: black;">药品</span>和正在进行的新的小分子<span style="color: black;">控制</span>剂的<span style="color: black;">科研</span>。<span style="color: black;">咱们</span>对这些<span style="color: black;">控制</span>剂<span style="color: black;">怎样</span>影响治疗效果的理解正在<span style="color: black;">持续</span>扩大。</p><img src="https://mmbiz.qpic.cn/mmbiz_jpg/pHzHVM2oJO3VyPAmeSv9AYAeQkCYHiaRiaeFgoGp5YGbhFEPfvrRshws91aTeicOiaEA6aC4TXDXfskVgAEiaJKrKgg/640?wx_fmt=jpeg&tp=webp&wxfrom=5&wx_lazy=1&wx_co=1" style="width: 50%; margin-bottom: 20px;">
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">癌症治疗的代谢靶点</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">除了传统理论认为肿瘤细胞<span style="color: black;">必须</span><span style="color: black;">增多</span>养分摄取和分解代谢<span style="color: black;">才可</span>产生三磷酸腺苷(ATP)外,<span style="color: black;">近期</span>的<span style="color: black;">科研</span>强调了能量代谢在细胞分化、侵袭、转移和种植中的<span style="color: black;">要紧</span>性。<span style="color: black;">因此呢</span>,<span style="color: black;">包含</span>糖酵解、脂肪酸代谢、谷氨酰胺代谢、三羧酸(TCA)循环和氧化磷酸化(OXPHOS)在内的能量代谢通路<span style="color: black;">作为</span>有前景的代谢靶点。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">以下是能量代谢靶点的简要总结:在糖酵解方面,在几个体外和<span style="color: black;">身体</span>临床前模型中,葡萄糖转运蛋白(GLUT)、己糖激酶、乳酸脱氢酶和乳酸-质子协同转运蛋白的<span style="color: black;">控制</span>剂被证明<span style="color: black;">能够</span><span style="color: black;">控制</span>肿瘤生长。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">在脂肪酸代谢方面,虽然<span style="color: black;">日前</span>尚<span style="color: black;">没</span>高度特异性的脂肪酸氧化<span style="color: black;">控制</span>剂(FAO),但参与脂肪酰基肉碱生成的<span style="color: black;">要紧</span>酶是可靶向的,并且正在积极<span style="color: black;">科研</span>中。<span style="color: black;">另外</span>,谷氨酰胺转运蛋白和谷氨酰胺酶的<span style="color: black;">控制</span>剂已在临床前和临床模型中进行了深入<span style="color: black;">科研</span>。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">NAD+<span style="color: black;">做为</span>电子受体的<span style="color: black;">重要</span>作用使其<span style="color: black;">作为</span>一个有前景的靶点。在临床前模型中,NAD+<span style="color: black;">弥补</span>联合抗pd - l1治疗有效<span style="color: black;">控制</span>了肿瘤生长。NAD+代谢的争议<span style="color: black;">功效</span>反映了肿瘤治疗中调节氧化还原代谢的<span style="color: black;">繁杂</span>性。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">肿瘤细胞的<span style="color: black;">各样</span>代谢靶点在前几节中<span style="color: black;">无</span><span style="color: black;">触及</span>。靶向PHGDH的<span style="color: black;">控制</span>剂<span style="color: black;">经过</span><span style="color: black;">控制</span>肿瘤中的一碳代谢而<span style="color: black;">表示</span>出抗肿瘤疗效。<span style="color: black;">另外</span>,靶向色氨酸和多胺代谢可<span style="color: black;">经过</span><span style="color: black;">加强</span>抗肿瘤免疫来<span style="color: black;">控制</span>肿瘤生长。<span style="color: black;">另外</span>,<span style="color: black;">近期</span>的一项<span style="color: black;">科研</span><span style="color: black;">显示</span>,靶向肌酸代谢<span style="color: black;">经过</span>失活Smad2/3<span style="color: black;">控制</span>结直肠癌和乳腺癌的转移。三阴性乳腺癌(TNBC)是恶性程度最高且治疗<span style="color: black;">方法</span>有限的乳腺癌亚型,实验室对其代谢靶点进行了深入<span style="color: black;">科研</span>。随着对肿瘤代谢<span style="color: black;">科研</span>的<span style="color: black;">持续</span>深入,新的代谢脆弱性有望被系统识别。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">鉴于T细胞在抗肿瘤免疫中起着<span style="color: black;">重要</span><span style="color: black;">功效</span>,重塑T细胞代谢在肿瘤治疗中<span style="color: black;">拥有</span>巨大的前景。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">既往<span style="color: black;">科研</span><span style="color: black;">发掘</span>,糖酵解在T细胞活化中发挥<span style="color: black;">要紧</span><span style="color: black;">功效</span>。<span style="color: black;">另外</span>,<span style="color: black;">控制</span>胆固醇代谢或用亚油酸处理CD8+T细胞可<span style="color: black;">加强</span>其细胞毒性和<span style="color: black;">加强</span>免疫治疗。<span style="color: black;">另外</span>,<span style="color: black;">咱们</span><span style="color: black;">发掘</span>调节性T细胞(Tregs)<span style="color: black;">能够</span>利用单羧酸转运蛋白1 (MCT1)摄取乳酸并上调PD-1的表达,表明MCT1是免疫治疗的潜在靶点。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">尽管靶向TME代谢的证据<span style="color: black;">重点</span>是临床前证据,但此类策略<span style="color: black;">特别有</span>前景,<span style="color: black;">必须</span>进一步<span style="color: black;">科研</span>。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">除了肿瘤部位的代谢重编程,全身的代谢<span style="color: black;">亦</span>呈现出潜在的治疗靶点。<span style="color: black;">膳食</span><span style="color: black;">干涉</span>和体育<span style="color: black;">熬炼</span>是靶向机体代谢的两大途径。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"> <strong style="color: blue;">综述内容</strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">02 靶向代谢,使其他癌症疗法更<span style="color: black;">敏锐</span></strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"> 03 </span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">代谢重编程不仅<span style="color: black;">寓意</span>着一种新兴的治疗策略,<span style="color: black;">况且</span>影响其他抗肿瘤疗法的疗效。</strong>在<span style="color: black;">这儿</span>,<span style="color: black;">咱们</span>总结了临床前和临床证据,阐明了靶向代谢<span style="color: black;">怎样</span><span style="color: black;">加强</span>癌症对标准治疗的易感性,<span style="color: black;">包含</span>化疗、放疗、基因组改变靶向治疗和免疫治疗。</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;">综述内容</strong></span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">03 针对癌症代谢的临床<span style="color: black;">实验</span></strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"> 04 </span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;"><span style="color: black;">咱们</span>对已<span style="color: black;">发布</span>的<span style="color: black;">科研</span>进行了全面的回顾,总结了进入临床<span style="color: black;">实验</span><span style="color: black;">周期</span>的代谢<span style="color: black;">药品</span>和<span style="color: black;">膳食</span><span style="color: black;">干涉</span><span style="color: black;">办法</span>。</strong>随后,<span style="color: black;">咱们</span>对clinicaltrials .govas进行了调查,以深入<span style="color: black;">认识</span>代谢疗法的<span style="color: black;">状况</span>。</p><img src="https://mmbiz.qpic.cn/mmbiz_jpg/pHzHVM2oJO3VyPAmeSv9AYAeQkCYHiaRia0CcpibgicCaJxH6LApDdDMib9AicAxicXxGicrzp9X8wK7TNQlwszWP0l3GQ/640?wx_fmt=jpeg&tp=webp&wxfrom=5&wx_lazy=1&wx_co=1" style="width: 50%; margin-bottom: 20px;">
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">针对癌症代谢的临床<span style="color: black;">实验</span>趋势</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;"><span style="color: black;">综述内容</span></strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"> <strong style="color: blue;">04</strong> <strong style="color: blue;">限制肿瘤代谢治疗效果的<span style="color: black;">原因</span></strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"> 05 </span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">将癌症代谢<span style="color: black;">做为</span>靶向治疗的一个<span style="color: black;">重要</span><span style="color: black;">阻碍</span>是难以在达到抗肿瘤效果的<span style="color: black;">同期</span>将对正常细胞的毒性降至最低。</strong>鉴于正常细胞共享许多对肿瘤细胞<span style="color: black;">存活</span>至关<span style="color: black;">要紧</span>的代谢通路,<span style="color: black;">因此呢</span>代谢药物的治疗窗口<span style="color: black;">一般</span>较窄,可能<span style="color: black;">引起</span><span style="color: black;">明显</span>毒性。总体而言,靶向癌症代谢的治疗不同于靶向基因组改变的治疗,克服与对正常细胞产生影响<span style="color: black;">关联</span>的不良事件仍然是一个重大挑战。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">肿瘤细胞与TME之间<span style="color: black;">繁杂</span>的相互<span style="color: black;">功效</span><span style="color: black;">亦</span>是代谢治疗的一个<span style="color: black;">要紧</span>问题。</strong>肿瘤间和肿瘤内的代谢异质性<span style="color: black;">亦</span>降低了代谢治疗的效果。<span style="color: black;">另一</span>,肿瘤<span style="color: black;">发展</span>和治疗过程中的代谢适应性是另一个巨大的挑战。</p><img src="https://mmbiz.qpic.cn/mmbiz_jpg/pHzHVM2oJO3VyPAmeSv9AYAeQkCYHiaRiaIP5ApkwibUsO3nrbxfGhtYTgsPXFXOZlqiaauxHvGuJ2nNI10ZvNiaAYw/640?wx_fmt=jpeg&tp=webp&wxfrom=5&wx_lazy=1&wx_co=1" style="width: 50%; margin-bottom: 20px;">
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">限制肿瘤代谢治疗效果的<span style="color: black;">原因</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;"><span style="color: black;">综述内容</span></strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">05 肿瘤代谢靶向<span style="color: black;">精细</span>治疗的<span style="color: black;">将来</span>方向</strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"> 06 </span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">代谢治疗面临与免疫治疗<span style="color: black;">类似</span>的挑战。<span style="color: black;">因此呢</span>,<span style="color: black;">咱们</span><span style="color: black;">能够</span>从历史案例中吸取教训,克服现有靶向肿瘤代谢的缺陷。</strong><span style="color: black;">近期</span>,多组学<span style="color: black;">工具</span>在<span style="color: black;">发掘</span>新的代谢靶点方面<span style="color: black;">表示</span>出巨大的<span style="color: black;">潜能</span>。<span style="color: black;">首要</span>,对多组学新维度的探索,<span style="color: black;">加强</span>了<span style="color: black;">咱们</span>对肿瘤代谢调控的理解,并使潜在的代谢靶点的识别<span style="color: black;">作为</span>可能。其次,整合基因组学、转录组学和蛋白质组学等多组学分析,系统地揭示肿瘤代谢网络并揭示潜在靶点。<span style="color: black;">另外</span>,新的分析<span style="color: black;">办法</span>的发展促进了新的代谢脆弱性的<span style="color: black;">发掘</span>。综上所述,多组学<span style="color: black;">工具</span>和单细胞和空间检测技术<span style="color: black;">明显</span>加快了代谢靶点的识别。<span style="color: black;">将来</span>的方向<span style="color: black;">包含</span>在临床前验证这些靶点,并将研究结果转化为临床。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;">除了确定理想的代谢靶点外,在治疗过程中克服代谢适应性<span style="color: black;">亦</span>很<span style="color: black;">要紧</span>。</strong><span style="color: black;">因此呢</span>,动态、精确地<span style="color: black;">跟踪</span>肿瘤代谢是迫切<span style="color: black;">必须</span>的。识别和<span style="color: black;">跟踪</span>代谢靶点的<span style="color: black;">最后</span>目的是实现<span style="color: black;">精细</span>医疗。<span style="color: black;">思虑</span>到肿瘤的时空代谢异质性,个体化代谢治疗将是<span style="color: black;">将来</span>的发展方向。</p><img src="https://mmbiz.qpic.cn/mmbiz_jpg/pHzHVM2oJO3VyPAmeSv9AYAeQkCYHiaRiaYoXOl4UScmHCGWc1CWGOibpmu5gbJfWJ7hreYI2pJrg2rJ4dEjiauWwQ/640?wx_fmt=jpeg&tp=webp&wxfrom=5&wx_lazy=1&wx_co=1" style="width: 50%; margin-bottom: 20px;">
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">肿瘤代谢<span style="color: black;">精细</span>治疗的<span style="color: black;">将来</span>方向</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><strong style="color: blue;"> 总结</strong></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;"> 07 </span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">癌症中的代谢重编程<span style="color: black;">表率</span>了生物学现象和潜在临床靶点的融合。尽管<span style="color: black;">发掘</span>了许多潜在的代谢分子,但针对癌症代谢治疗的临床<span style="color: black;">实验</span>有时表现出令人不满意的效果。为了克服这些挑战,<span style="color: black;">必要</span>采取一系列行动。<span style="color: black;">经过</span>整合多组学、单细胞和空间检测技术来确定更理想的代谢靶点将是<span style="color: black;">重要</span>的一步。<span style="color: black;">另外</span>,还<span style="color: black;">必须</span>更精确、更动态地跟踪和可视化代谢重组过程的<span style="color: black;">工具</span>。基于这些<span style="color: black;">发展</span>,临床<span style="color: black;">大夫</span>将进一步推进针对癌症<span style="color: black;">病人</span>的个性化代谢疗法。</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">参考资料:</span></p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;">https://www.cell.com/cell-metabolism/fulltext/S1550-4131(23)00265-6#%20</p>
<p style="font-size: 16px; color: black; line-height: 40px; text-align: left; margin-bottom: 15px;"><span style="color: black;">注:本文旨在介绍医学<span style="color: black;">科研</span><span style="color: black;">发展</span>,<span style="color: black;">不可</span><span style="color: black;">做为</span>治疗<span style="color: black;">方法</span>参考。如需<span style="color: black;">得到</span>健康<span style="color: black;">指点</span>,请至正规医院就诊。</span></p><img src="https://mmbiz.qpic.cn/mmbiz_png/pHzHVM2oJO3VyPAmeSv9AYAeQkCYHiaRiaorvnyEOBCFo6dsSd8iajsicznkVQGKLDSCOVxRVvB5VmK9qww5I6jCzw/640?wx_fmt=png&tp=webp&wxfrom=5&wx_lazy=1&wx_co=1" style="width: 50%; margin-bottom: 20px;">
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