Stroke-like presentation of acute toxic leukoencephalopathy due to capecitabine treatment with extensive intramyelinic edema

Q1 Medicine
Julia Feige, Fritz Klausner, Johannes A. R. Pfaff, Eugen Trinka, Slaven Pikija, Mahdi Safdarian
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Pfaff,&nbsp;Eugen Trinka,&nbsp;Slaven Pikija,&nbsp;Mahdi Safdarian","doi":"10.1002/cdt3.72","DOIUrl":null,"url":null,"abstract":"<p>Capecitabine is an oral prodrug of 5-fluorouracil (5-FU), which is widely used for adjuvant and neoadjuvant chemotherapy of different solid tumors, particularly breast and colorectal cancers.<span><sup>1</sup></span> Neurotoxicity of capecitabine has been consistently reported as capecitabine-induced toxic leukoencephalopathy, which includes bilateral lesions in the corpus callosum and corticospinal tract presenting as acute or delayed central nervous system toxicity.<span><sup>2</sup></span> This side effect requires discontinuation of chemotherapy<span><sup>3</sup></span>; however, neurological symptoms due to capecitabine are reported to be usually reversible upon drug withdrawal.<span><sup>1</sup></span></p><p>The patients presenting with acute stroke-like symptoms with accompanied restricted diffusion outside typical vessel territory pose a significant diagnostic challenge. In the case of exclusively white matter involvement, the observed low apparent diffusion coefficient (ADC) could be due to the severe intramyelinic edema and not cell death, that is, cytotoxic edema. Multifocal leukoencephalopathy has been associated with capecitabine, but only a few cases have been reported in the literature.<span><sup>4</sup></span></p><p>A 51-year-old woman was admitted due to acute onset of dizziness, dysarthria, and right-sided central facial paresis. The patient had been diagnosed with bilateral breast cancer 5 years ago for which neoadjuvant chemotherapy was done as well as surgical and radiation therapy. The primary tumor was a moderately differentiated invasive breast carcinoma of nonspecific type (right breast: stadium cT1b, human epidermal growth factor receptor 2 [HER2] negative with Ki67 10%–20%, and left breast: Stadium cT1c cN1 cM0. HER2 negative. Ki67 10%). Neoadjuvant chemotherapy regime consisted of four cycles of epirubicin/cyclophosphamide (every 2 weeks [q2w]) afterwards four cycles of paclitaxel (q2w) with granulocyte-colony-stimulating factor (G-CSF) support for 4 months. In the follow-up fluorodeoxyglucose-positron emission tomography (FDG-PET) scan, a solitary osseous metastasis was detected in the sacrum, for which capecitabine and bevacizumab had been initiated.</p><p>At our department, the patient reported a feeling of dizziness and difficulties in swallowing 1 day after starting capecitabine and bevacizumab. The CT at admission showed no infarction or hemorrhage and she was also outside thrombolysis therapeutic window. In the evening that day, there was a sudden onset of motoric aphasia. MR-tomography showed a pronounced hyperintense white matter lesion affecting the splenium of the corpus callosum and the medullary beds with pronounced fiber rarefication in arcuate fasciculus (Figure 1A–C). There was a mild pleocytosis of 15 cells/μL in the CSF, with normal protein and lactate. A JC virus polymerase chain reaction (PCR) from the CSF was negative. Onco-neural and antineuronal antibodies were all negative (Table 1). Clinical symptoms resolved rapidly 1 day after discontinuation of capecitabine. About 2 months later, a control MRI showed only discrete hyperintensity in the splenium with normal fiber-tracking (Figure 1D–F).</p><p>Upon discharge, 3 weeks radiation of solitary metastasis in S1 sacral bone with 15 × 3 Gy (cumulative 45 Gy) was done as an alternative treatment for her metastatic disease.</p><p>Here we presented a case of acute onset of motoric aphasia developed immediately after initiating capecitabine, with prompt resolution of clinical symptoms upon its discontinuation.</p><p>Capecitabine, upon oral ingestion, is activated through the triple enzymatic process (carboxylesterase, cytidine deaminase, and thymidine phosphorylase), resulting in the formation of 5-FU.<span><sup>5</sup></span> 5-FU would be preferentially produced in cancer cells due to higher levels of thymidine phosphorylase,<span><sup>6</sup></span> and undergo catabolism through dihydropyrimidine dehydrogenase (DYPD) in the liver. DYPD deficiency, therefore, leads to severe toxicity due to accumulating 5-FU. However, DYPD deficiency is nowadays a rare cause of 5-FU toxicity due to regular screening. Nevertheless, other polymorphisms of the DYPD gene, which are not regularly screened, and other genes such as thymidylate synthase (TYMS) can be responsible for increased toxicity. For example, patients homozygous for the TS 3RG allele have higher toxicity and less response to treatment compared to the nonhomozygous cohort.<span><sup>7</sup></span> The capecitabine intermediate metabolite 50-deoxy-5-fluorouridine (50-DFUR) crosses the blood-brain barrier, providing the substrate for this final step of capecitabine transformation into 5-FU locally in the brain.<span><sup>8</sup></span></p><p>The lesions seen in patients with capecitabine-induced leukoencephalopathy are mostly localized in the white matter tracts and are mostly reversible. However, the imaging is inconsistent with reports ranging from “no abnormality” to extensive white matter involvement, including infratentorial as well as supratentorial tracts.</p><p>Low ADC, as seen in our patient could point to the presence of intramyelinic edema, as suggested by de Oliveira.<span><sup>9</sup></span> It postulates the existence of nonneurotoxic edema in the virtual space of myelin layers enveloping and insulating the axons. The characteristic pattern is of truly restricted water diffusibility—imitating irreversible cytotoxic edema—however, without lasting consequences on control imaging.</p><p>Posterior reversible leukoencephalopathy syndrome (PRES) could present with similar clinical symptoms. PRES presents in patients with elevated blood pressure, disorders of consciousness, epileptic seizures (almost two-thirds of patients), and visual disturbance due to involvement of posterior cerebral regions and vasogenic edema. Focal neurological signs such as aphasia seen in our patient are present in a minority of cases (up to 15%).<span><sup>10</sup></span> It could, however, involve white matter tracts, have DWI restriction, and present bilaterally. Our patient also received therapy with bevacizumab, which indeed may induce leukoencephalopathy mostly in terms of PRES.<span><sup>11</sup></span> However, possible augmentation of capecitabine-induced callosal lesion through concomitant bevacizumab administration could not be completely ruled-out.</p><p>Marchiafava-Bignami disease results from osmotic demyelination and necrosis of the corpus callosum.<span><sup>12</sup></span> It present in patients having chronic ethanol use and vitamin B complex deficiency, both not presented in our patient. DWI would not also show any changes in the acute phase.</p><p>Reversible splenial lesion (RSL), most probably would occur due to viral infection and hypoglycemia, hypernatremia, acute alcohol poisoning, and epileptic seizures. It may also manifest between 24 h to 3 weeks after withdrawal of antiepileptic drugs.<span><sup>13</sup></span></p><p>In a retrospective study, six adult patients with solid cancers developed acute toxic leukoencephalopathies with splenial lesions following treatment with 5-FU or capecitabine within 3 days of the first treatment cycle. Brain MRI showed T2/FLAIR hyperintensities in the corpus callosum, with diffusion restriction and no contrast enhancement. Upon capecitabine discontinuiation, all patients experienced full clinical-radiological recovery after a median of 8.5 days from symptom onset.<span><sup>14</sup></span></p><p>Obadia et al. reported a 45-year-old woman treated by capecitabine for breast cancer with metastatic bone lesions, who presented with nausea, headaches, muscle cramps, dysarthria, and swallowing disorder. MRI showed bilateral and symmetric high signal intensities of deep white matter, corpus callosum, and corticospinal tracts with regression upon discontinuation.<span><sup>2</sup></span></p><p>In 2005, Videnovic et al. had reported a case series of five capecitabine-induced leukoencephalopathies in four patients with advanced breast cancer and one with pancreatic carcinoma. All patients were women between 40 and 74 years of age who developed neurologic symptoms including nausea, confusion, short-term memory loss, headaches, vertigo, ataxia, and dysarthria within 7 days of initiating capecitabine for tumor progression. Brain MRI revealed increased signals in the areas of the corpus callosum, brachium pontis, and deep periventricular matter. The splenium of the corpus callosum was primarily affected in all cases. All patients improved over a few days after capecitabine withdrawal.<span><sup>15</sup></span></p><p>Wagner-Altendorf et al. reported a patient with bilateral degeneration of the corticospinal tract and progressive spastic tetraplegia after chemotherapy with capecitabine whose symptoms substantially worsened over the following years after discontinuation of therapy and finally died from aspiration pneumonia.<span><sup>1</sup></span></p><p>Resuming capecitabine might be feasible in some cases if expected benefits outweigh the risks. Perrain et al. for example, suggested resuming capecitabine in selected cases after excluding DYPD deficiency.<span><sup>14</sup></span> Bougea et al. also reported a 50-year-old woman who presented an isolated episode of dysarthria and ataxia under capecitabine, bevacizumab, and oxaliplatin treatment due to reversible multifocal leukoencephalopathy, which did not recur after readministration of chemotherapy.<span><sup>3</sup></span> Tipples et al., however, suggest seeking an alternative chemotherapy regime even after excluding DYPD deficiency.<span><sup>4</sup></span> No MRI abnormalities were, however, found in a young patient with metastatic colorectal cancer reported by Saif, who developed clinically acute cerebellar syndrome after starting capecitabine. The patient was found to have genotype deficiencies in the TYMS gene, and improved after discontinuation of capecitabine.<span><sup>16</sup></span></p><p>A summary of recent cases has been provided in the Supporting Information Table.<span><sup>17-23</sup></span></p><p>In conclusion, capecitabine-induced leukoencephalopathy is an acute toxic phenomenon resulting from mostly reversible intramyelinic edema upon exposure to 5-FU metabolites in highly active white matter tracts that can develop within days after starting treatment. Important differential consideration is reversible splenial lesions, mostly due to epileptic seizure or drug withdrawal. Clinicians should be aware of this probable side effect as early discontinuation of treatment usually leads to a good clinical outcome. Symptoms of neurotoxicity could vary but mainly consist of ataxia, dysarthria, headache, and confusion. Any sudden neurologic status change after initiating capecitabine should be investigated with a brain MRI, which generally shows subcortical white matter changes (leukoencephalopathy) in the splenium of the corpus callosum and corticospinal tracts. Discontinuation of capecitabine would usually result in rapid recovery of both clinical and imaging abnormalities.</p><p>Slaven Pikija, Julia Feige, Fritz Klausner, and Johannes A. R. Pfaff collected the data of the case. Slaven Pikija and Mahdi Safdarian drafted the manuscript. All the authors read and confirmed the final manuscript.</p><p>The authors declare no conflict of interest.</p><p>An informed concent was signed by the patient and she agreed about reporting her case anonymously.</p>","PeriodicalId":32096,"journal":{"name":"Chronic Diseases and Translational Medicine","volume":"9 3","pages":"258-262"},"PeriodicalIF":0.0000,"publicationDate":"2023-06-08","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://ftp.ncbi.nlm.nih.gov/pub/pmc/oa_pdf/19/13/CDT3-9-258.PMC10497845.pdf","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Chronic Diseases and Translational Medicine","FirstCategoryId":"3","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/cdt3.72","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"Medicine","Score":null,"Total":0}
引用次数: 1

Abstract

Capecitabine is an oral prodrug of 5-fluorouracil (5-FU), which is widely used for adjuvant and neoadjuvant chemotherapy of different solid tumors, particularly breast and colorectal cancers.1 Neurotoxicity of capecitabine has been consistently reported as capecitabine-induced toxic leukoencephalopathy, which includes bilateral lesions in the corpus callosum and corticospinal tract presenting as acute or delayed central nervous system toxicity.2 This side effect requires discontinuation of chemotherapy3; however, neurological symptoms due to capecitabine are reported to be usually reversible upon drug withdrawal.1

The patients presenting with acute stroke-like symptoms with accompanied restricted diffusion outside typical vessel territory pose a significant diagnostic challenge. In the case of exclusively white matter involvement, the observed low apparent diffusion coefficient (ADC) could be due to the severe intramyelinic edema and not cell death, that is, cytotoxic edema. Multifocal leukoencephalopathy has been associated with capecitabine, but only a few cases have been reported in the literature.4

A 51-year-old woman was admitted due to acute onset of dizziness, dysarthria, and right-sided central facial paresis. The patient had been diagnosed with bilateral breast cancer 5 years ago for which neoadjuvant chemotherapy was done as well as surgical and radiation therapy. The primary tumor was a moderately differentiated invasive breast carcinoma of nonspecific type (right breast: stadium cT1b, human epidermal growth factor receptor 2 [HER2] negative with Ki67 10%–20%, and left breast: Stadium cT1c cN1 cM0. HER2 negative. Ki67 10%). Neoadjuvant chemotherapy regime consisted of four cycles of epirubicin/cyclophosphamide (every 2 weeks [q2w]) afterwards four cycles of paclitaxel (q2w) with granulocyte-colony-stimulating factor (G-CSF) support for 4 months. In the follow-up fluorodeoxyglucose-positron emission tomography (FDG-PET) scan, a solitary osseous metastasis was detected in the sacrum, for which capecitabine and bevacizumab had been initiated.

At our department, the patient reported a feeling of dizziness and difficulties in swallowing 1 day after starting capecitabine and bevacizumab. The CT at admission showed no infarction or hemorrhage and she was also outside thrombolysis therapeutic window. In the evening that day, there was a sudden onset of motoric aphasia. MR-tomography showed a pronounced hyperintense white matter lesion affecting the splenium of the corpus callosum and the medullary beds with pronounced fiber rarefication in arcuate fasciculus (Figure 1A–C). There was a mild pleocytosis of 15 cells/μL in the CSF, with normal protein and lactate. A JC virus polymerase chain reaction (PCR) from the CSF was negative. Onco-neural and antineuronal antibodies were all negative (Table 1). Clinical symptoms resolved rapidly 1 day after discontinuation of capecitabine. About 2 months later, a control MRI showed only discrete hyperintensity in the splenium with normal fiber-tracking (Figure 1D–F).

Upon discharge, 3 weeks radiation of solitary metastasis in S1 sacral bone with 15 × 3 Gy (cumulative 45 Gy) was done as an alternative treatment for her metastatic disease.

Here we presented a case of acute onset of motoric aphasia developed immediately after initiating capecitabine, with prompt resolution of clinical symptoms upon its discontinuation.

Capecitabine, upon oral ingestion, is activated through the triple enzymatic process (carboxylesterase, cytidine deaminase, and thymidine phosphorylase), resulting in the formation of 5-FU.5 5-FU would be preferentially produced in cancer cells due to higher levels of thymidine phosphorylase,6 and undergo catabolism through dihydropyrimidine dehydrogenase (DYPD) in the liver. DYPD deficiency, therefore, leads to severe toxicity due to accumulating 5-FU. However, DYPD deficiency is nowadays a rare cause of 5-FU toxicity due to regular screening. Nevertheless, other polymorphisms of the DYPD gene, which are not regularly screened, and other genes such as thymidylate synthase (TYMS) can be responsible for increased toxicity. For example, patients homozygous for the TS 3RG allele have higher toxicity and less response to treatment compared to the nonhomozygous cohort.7 The capecitabine intermediate metabolite 50-deoxy-5-fluorouridine (50-DFUR) crosses the blood-brain barrier, providing the substrate for this final step of capecitabine transformation into 5-FU locally in the brain.8

The lesions seen in patients with capecitabine-induced leukoencephalopathy are mostly localized in the white matter tracts and are mostly reversible. However, the imaging is inconsistent with reports ranging from “no abnormality” to extensive white matter involvement, including infratentorial as well as supratentorial tracts.

Low ADC, as seen in our patient could point to the presence of intramyelinic edema, as suggested by de Oliveira.9 It postulates the existence of nonneurotoxic edema in the virtual space of myelin layers enveloping and insulating the axons. The characteristic pattern is of truly restricted water diffusibility—imitating irreversible cytotoxic edema—however, without lasting consequences on control imaging.

Posterior reversible leukoencephalopathy syndrome (PRES) could present with similar clinical symptoms. PRES presents in patients with elevated blood pressure, disorders of consciousness, epileptic seizures (almost two-thirds of patients), and visual disturbance due to involvement of posterior cerebral regions and vasogenic edema. Focal neurological signs such as aphasia seen in our patient are present in a minority of cases (up to 15%).10 It could, however, involve white matter tracts, have DWI restriction, and present bilaterally. Our patient also received therapy with bevacizumab, which indeed may induce leukoencephalopathy mostly in terms of PRES.11 However, possible augmentation of capecitabine-induced callosal lesion through concomitant bevacizumab administration could not be completely ruled-out.

Marchiafava-Bignami disease results from osmotic demyelination and necrosis of the corpus callosum.12 It present in patients having chronic ethanol use and vitamin B complex deficiency, both not presented in our patient. DWI would not also show any changes in the acute phase.

Reversible splenial lesion (RSL), most probably would occur due to viral infection and hypoglycemia, hypernatremia, acute alcohol poisoning, and epileptic seizures. It may also manifest between 24 h to 3 weeks after withdrawal of antiepileptic drugs.13

In a retrospective study, six adult patients with solid cancers developed acute toxic leukoencephalopathies with splenial lesions following treatment with 5-FU or capecitabine within 3 days of the first treatment cycle. Brain MRI showed T2/FLAIR hyperintensities in the corpus callosum, with diffusion restriction and no contrast enhancement. Upon capecitabine discontinuiation, all patients experienced full clinical-radiological recovery after a median of 8.5 days from symptom onset.14

Obadia et al. reported a 45-year-old woman treated by capecitabine for breast cancer with metastatic bone lesions, who presented with nausea, headaches, muscle cramps, dysarthria, and swallowing disorder. MRI showed bilateral and symmetric high signal intensities of deep white matter, corpus callosum, and corticospinal tracts with regression upon discontinuation.2

In 2005, Videnovic et al. had reported a case series of five capecitabine-induced leukoencephalopathies in four patients with advanced breast cancer and one with pancreatic carcinoma. All patients were women between 40 and 74 years of age who developed neurologic symptoms including nausea, confusion, short-term memory loss, headaches, vertigo, ataxia, and dysarthria within 7 days of initiating capecitabine for tumor progression. Brain MRI revealed increased signals in the areas of the corpus callosum, brachium pontis, and deep periventricular matter. The splenium of the corpus callosum was primarily affected in all cases. All patients improved over a few days after capecitabine withdrawal.15

Wagner-Altendorf et al. reported a patient with bilateral degeneration of the corticospinal tract and progressive spastic tetraplegia after chemotherapy with capecitabine whose symptoms substantially worsened over the following years after discontinuation of therapy and finally died from aspiration pneumonia.1

Resuming capecitabine might be feasible in some cases if expected benefits outweigh the risks. Perrain et al. for example, suggested resuming capecitabine in selected cases after excluding DYPD deficiency.14 Bougea et al. also reported a 50-year-old woman who presented an isolated episode of dysarthria and ataxia under capecitabine, bevacizumab, and oxaliplatin treatment due to reversible multifocal leukoencephalopathy, which did not recur after readministration of chemotherapy.3 Tipples et al., however, suggest seeking an alternative chemotherapy regime even after excluding DYPD deficiency.4 No MRI abnormalities were, however, found in a young patient with metastatic colorectal cancer reported by Saif, who developed clinically acute cerebellar syndrome after starting capecitabine. The patient was found to have genotype deficiencies in the TYMS gene, and improved after discontinuation of capecitabine.16

A summary of recent cases has been provided in the Supporting Information Table.17-23

In conclusion, capecitabine-induced leukoencephalopathy is an acute toxic phenomenon resulting from mostly reversible intramyelinic edema upon exposure to 5-FU metabolites in highly active white matter tracts that can develop within days after starting treatment. Important differential consideration is reversible splenial lesions, mostly due to epileptic seizure or drug withdrawal. Clinicians should be aware of this probable side effect as early discontinuation of treatment usually leads to a good clinical outcome. Symptoms of neurotoxicity could vary but mainly consist of ataxia, dysarthria, headache, and confusion. Any sudden neurologic status change after initiating capecitabine should be investigated with a brain MRI, which generally shows subcortical white matter changes (leukoencephalopathy) in the splenium of the corpus callosum and corticospinal tracts. Discontinuation of capecitabine would usually result in rapid recovery of both clinical and imaging abnormalities.

Slaven Pikija, Julia Feige, Fritz Klausner, and Johannes A. R. Pfaff collected the data of the case. Slaven Pikija and Mahdi Safdarian drafted the manuscript. All the authors read and confirmed the final manuscript.

The authors declare no conflict of interest.

An informed concent was signed by the patient and she agreed about reporting her case anonymously.

Abstract Image

卡培他滨治疗引起的急性中毒性白质脑病伴广泛的髓内水肿的卒中样表现
卡培他滨是5-氟尿嘧啶(5-FU)的口服前药,广泛用于各种实体肿瘤的辅助和新辅助化疗,尤其是乳腺癌和结直肠癌卡培他滨的神经毒性一直被报道为卡培他滨诱导的中毒性白质脑病,包括胼胝体和皮质脊髓束双侧病变,表现为急性或迟发性中枢神经系统毒性这种副作用需要停止化疗3;然而,据报道,卡培他滨引起的神经系统症状在停药后通常是可逆的。出现急性卒中样症状并伴有典型血管外扩散受限的患者给诊断带来了重大挑战。在仅累及白质的情况下,观察到的低表观扩散系数(ADC)可能是由于严重的髓内水肿,而不是细胞死亡,即细胞毒性水肿。多灶性白质脑病与卡培他滨有关,但文献中仅有少数病例报道。一位51岁女性因急性起病头晕、构音障碍和右侧中央面部轻瘫而入院。患者5年前被诊断为双侧乳腺癌,并接受了新辅助化疗以及手术和放疗。原发肿瘤为非特异性中分化浸润性乳腺癌(右乳:stadium cT1b,人表皮生长因子受体2 [HER2]阴性,Ki67 10%-20%,左乳:stadium cT1c cN1 cM0)。HER2阴性。Ki67 10%)。新辅助化疗方案包括4个周期的表柔比星/环磷酰胺(每2周[q2w]),随后4个周期的紫杉醇(q2w),支持粒细胞集落刺激因子(G-CSF) 4个月。在后续的氟脱氧葡萄糖-正电子发射断层扫描(FDG-PET)扫描中,在骶骨中检测到孤立性骨转移,卡培他滨和贝伐单抗已开始治疗。在我科,患者报告在开始卡培他滨和贝伐单抗后1天出现头晕和吞咽困难的感觉。入院时CT未见梗死及出血,亦在溶栓治疗窗外。那天晚上,她突然患上了运动性失语症。核磁共振断层扫描显示胼胝体脾脏和髓床明显的高信号白质病变,弓状束纤维明显稀薄(图1A-C)。脑脊液轻度增多,15个/μL,蛋白和乳酸正常。脑脊液JC病毒聚合酶链反应(PCR)阴性。肿瘤神经和抗神经抗体均为阴性(表1)。停用卡培他滨1天后临床症状迅速缓解。约2个月后,对照MRI仅显示脾脏离散性高强度,纤维追踪正常(图1D-F)。出院后,对S1骶骨进行3周15 × 3 Gy(累计45 Gy)的孤立性转移放射治疗,作为转移性疾病的替代治疗。在这里,我们提出了一例急性发作的运动性失语症,在开始使用卡培他滨后立即发展,临床症状在停药后立即解决。卡培他滨口服后,通过三重酶过程(羧酸酯酶、胞苷脱氨酶和胸苷磷酸化酶)被激活,形成5-FU。5- fu会优先在癌细胞中产生,因为胸腺嘧啶磷酸化酶水平较高,6并通过肝脏中的二氢嘧啶脱氢酶(diypd)进行分解代谢。因此,DYPD缺乏会由于5-FU的积累而导致严重的毒性。然而,由于定期筛查,DYPD缺乏症现在是一种罕见的5-FU毒性原因。然而,没有定期筛选的DYPD基因的其他多态性,以及其他基因,如胸苷酸合成酶(TYMS),可能是毒性增加的原因。例如,与非纯合的患者相比,TS 3RG等位基因纯合的患者具有更高的毒性和更低的治疗反应卡培他滨中间代谢物50-脱氧-5-氟吡啶(50-DFUR)穿过血脑屏障,为卡培他滨在脑局部转化为5-FU的最后一步提供底物。卡培他滨诱导的白质脑病患者的病变大多局限于白质束,并且大多数是可逆的。然而,从“无异常”到广泛的白质受累(包括幕下束和幕上束)的报道与影像学不一致。正如de Oliveira所提示的,本例患者ADC低可能提示存在髓内水肿。 它假定在包裹和隔离轴突的髓鞘层的虚拟空间中存在非神经毒性水肿。其特征是水扩散受限,类似于不可逆的细胞毒性水肿,但对对照成像没有持久影响。后部可逆性白质脑病综合征(PRES)可出现类似的临床症状。PRES表现为血压升高、意识障碍、癫痫发作(几乎三分之二的患者)以及由于后脑区受累和血管源性水肿而引起的视觉障碍。少数病例(15%)出现局灶性神经症状,如本例患者的失语然而,它可能涉及白质束,有DWI限制,并表现为双侧。我们的患者也接受了贝伐单抗的治疗,这确实可能导致脑白质病变,主要是在pres11方面。然而,不能完全排除卡培他滨诱导的胼胝体病变通过同时使用贝伐单抗而增加的可能性。Marchiafava-Bignami病是由胼胝体渗透性脱髓鞘和坏死引起的它存在于长期使用乙醇和维生素B复合物缺乏症的患者中,这两种情况在我们的患者中都没有出现。急性期DWI也未见任何变化。可逆性脾损害(RSL),最可能发生于病毒感染和低血糖、高钠血症、急性酒精中毒、癫痫发作。它也可能在停药后24小时至3周内出现。13在一项回顾性研究中,6名患有实体癌的成年患者在第一个治疗周期的3天内接受5-FU或卡培他滨治疗后出现急性中毒性白质脑病伴脾脏病变。脑MRI示胼胝体T2/FLAIR高信号,扩散受限,无增强。卡培他滨停药后,所有患者均在症状出现后8.5天内完全临床放射学恢复。14Obadia等人报道了一名45岁的女性接受卡培他滨治疗伴有转移性骨病变的乳腺癌,患者表现为恶心、头痛、肌肉痉挛、构音障碍和吞咽障碍。MRI显示双侧和对称的深部白质、胼胝体和皮质脊髓束高信号强度,停药后消退。2 2005年,Videnovic等报道了4例晚期乳腺癌患者和1例胰腺癌患者卡培他滨诱导的5例脑白质病变。所有患者均为40至74岁的女性,在开始使用卡培他滨治疗肿瘤进展的7天内出现神经系统症状,包括恶心、精神错乱、短期记忆丧失、头痛、眩晕、共济失调和构音障碍。脑MRI显示胼胝体、桥臂和深脑室周围物质区域信号增加。所有病例均以胼胝体的脾部为主。所有患者的卡培他滨停药后数天内均有改善。15Wagner-Altendorf等人报道了一例卡培他滨化疗后出现双侧皮质脊髓束变性和进行性痉挛性四肢瘫痪的患者,停药后症状明显恶化,最终死于吸入性肺炎。如果预期的益处大于风险,在某些情况下恢复卡培他滨可能是可行的。例如,Perrain等人建议在排除DYPD缺陷后,在选定的病例中恢复使用卡培他滨Bougea等人也报道了一名50岁女性,由于可逆性多灶性白质脑病,在卡培他滨、贝伐单抗和奥沙利铂治疗下出现孤立性构音障碍和失调,再给化疗后未复发然而,Tipples等人建议,即使排除DYPD缺陷,也要寻求替代化疗方案然而,在Saif报道的一名年轻的转移性结直肠癌患者中,未发现MRI异常,该患者在开始使用卡培他滨后出现临床急性小脑综合征。患者发现TYMS基因型缺陷,停药卡培他滨后得到改善。17-23综上所述,卡培他滨诱导的白质脑病是一种急性毒性现象,主要由暴露于高度活跃的白质束中的5-FU代谢物引起的髓内水肿引起,可在开始治疗后数天内发生。重要的鉴别考虑是可逆性脾损害,主要是由于癫痫发作或药物戒断。 临床医生应该意识到这种可能的副作用,因为早期停止治疗通常会导致良好的临床结果。神经毒性的症状各不相同,但主要包括共济失调、构音障碍、头痛和精神错乱。在开始使用卡培他滨后,任何突然的神经系统状态改变都应通过脑MRI进行调查,MRI通常显示胼胝体和皮质脊髓束脾皮质下白质改变(脑白质病)。停止卡培他滨通常会导致临床和影像学异常的快速恢复。Slaven Pikija、Julia Feige、Fritz Klausner和Johannes A. R. Pfaff收集了该病例的数据。Slaven Pikija和Mahdi Safdarian起草了手稿。所有的作者都阅读并确认了最终的手稿。作者声明无利益冲突。病人签署了一份知情同意书,她同意匿名报告她的病例。
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来源期刊
CiteScore
6.70
自引率
0.00%
发文量
195
审稿时长
35 weeks
期刊介绍: This journal aims to promote progress from basic research to clinical practice and to provide a forum for communication among basic, translational, and clinical research practitioners and physicians from all relevant disciplines. Chronic diseases such as cardiovascular diseases, cancer, diabetes, stroke, chronic respiratory diseases (such as asthma and COPD), chronic kidney diseases, and related translational research. Topics of interest for Chronic Diseases and Translational Medicine include Research and commentary on models of chronic diseases with significant implications for disease diagnosis and treatment Investigative studies of human biology with an emphasis on disease Perspectives and reviews on research topics that discuss the implications of findings from the viewpoints of basic science and clinical practic.
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