锂 (药物)
此条目的主题是药学上使用的锂盐。关于其他与“锂”名称相近或相同的条目,请见“锂 (消歧义)”。
 | |
| 临床资料 | |
|---|---|
| 商品名 | Many[1] |
| AHFS/Drugs.com | Monograph |
| MedlinePlus | a681039 |
| 怀孕分级 |
|
| 给药途径 | 口服、肠道外给药 |
| ATC码 | |
| 法律规范状态 | |
| 法律规范 |
|
| 药物动力学数据 | |
| 生物利用度 | 视配方而定 |
| 血浆蛋白结合率 | 无 |
| 药物代谢 | 肾代谢 |
| 生物半衰期 | 24小时,老年人36小时[2] |
| 排泄途径 | >95% 经肾排除 |
| 识别信息 | |
| |
| CAS号 | 7439-93-2 |
| PubChem CID | |
| DrugBank | |
| ChemSpider | |
| UNII | |
| ChEBI | |
| 化学信息 | |
| 化学式 | Li+ |
| 摩尔质量 | 6.941 g/mol |
| 3D模型(JSmol) | |
| |
| |
锂盐(英语:Lithium salts)为含锂离子的离子化合物,临床上通常指碳酸锂。锂盐在医学上可作为一种精神科药物,用于躁郁症与其他抗抑郁药治疗无效的重性抑郁障碍[2]。锂能够降低这些疾病患者的症状发生,进而减少患者自杀的机会。[3],经口服后由胃肠吸收,而经肾脏由尿代谢[2]。
锂盐的常见副作用有频尿、手抖、流涎(sialorrhea)、钾离子缺乏等[2]。严重者有甲状腺机能低下症、尿崩症与锂中毒[2]。因此建议监测其血中浓度,降低中毒风险[2]。如果血液中锂浓度过高,可能出现腹泻、呕吐、协调不良、嗜睡、耳鸣[2]。孕妇使用锂化合物可能造成胎儿发育问题[2]。哺乳期妇女服用则似无问题[4]。锂化合物属一种心境稳定剂[2]。这种药物的作用机转尚不明确。[2]
锂盐是一种白色结晶性粉末;无臭,无味;水溶液呈现碱性反应。有明显抑制狂躁情绪的作用,还可改善精神分裂症的情感障碍。可抑制去甲肾上腺素能和多巴胺能神经末梢递质释放,增加突触前膜对递质的再摄取,使突触后膜受体敏感性降低,增加脑内5-羟色胺合成。口服易吸收,不与血浆蛋白结合。体内的排泄速度个体差异很大。治疗躁郁症时,剂量与中毒量比较接近。大于1.5mmol/L,出现轻度毒性反应;大于2mmol/L,有严重反应发生。必须在血药浓度监测下使用。高龄患者或肾功能不全者不适合服用。
在1800年代锂盐曾被用于治疗痛风、癫痫和癌症。1948年,澳洲医师John Cade开始将锂盐使用于精神性疾病[5]。锂盐也是被列入世界卫生组织基本药物标准清单的基本药物,为基础公卫体系必备药物之一[6]。本品属通用名药物[2],2014年的批发价大约是每日0.12 到 0.20 美金[7]。在美国,每日药价大约花费 0.90 到 1.20 美金[2]。
用途
[编辑]主要用于双相障碍。可以预防未来的躁狂期,对已有躁狂也有控制作用。[8]处理抑郁期的效果比丙戊酸确切,但不如抗精神病药物。[9][10][11]或许对双相障碍合并的物质滥用障碍也有帮助。[12][13][14]传统上认为可以降低自杀,但证据并不支持。[15]
对于其他药物无效的重性抑郁障碍也有效。一般作为SSRI的附加治疗,[16][17][18]不但可以提高起效率,还可以缩短起效所需时间。[19]也有用于附加给拉莫三嗪等抗癫痫药的。[20]极少有单独用的,似乎用于复发者比用于新发者更有效。[21]
也用于阿尔茨海默症。可以缓解疾病发展。[22][23]似乎也有预防作用。双相患者患阿尔茨海默症概率总体高于常人,但长期服用锂的双相患者患病率低于常人。[22]使用丙戊酸者和锂、丙戊酸联用者的发病率高于常人。[24]
注意事项
[编辑]服用锂盐的注意事项是要把血中的锂浓度控制在安全而有效的范围内,发病的急性期要控制在0.8-1.2mmol/L,稳定期要维持在0.4-1.0 mmol/L。浓度太高,会有中毒的危险,太低则无法达到疗效。而这里所谓的锂浓度指的是距离最后一次服锂盐9到13小时抽血测定的资料,也就是一天当中血中锂浓度最低的值。开始服药的头二个星期,要每周测量血中锂浓度,接下来每个月测量一次,之后可以每半年抽血追踪。
现时锂的最低有效剂量有持续向低调整的趋势,建议最低值已从传统的0.6mmol/L调整到0.4mmol/L。原则上说,使用锂应采用一个患者身上的最低有效剂量,所以剂量要缓慢增加。[25]低浓度对应的剂量对于一些患者来说不足以控制发病,[26]但也有重分析指出更大的因素是低剂量时药物的谷浓度过低,而非平均浓度过低。[27]采用缓释制剂可以降低峰值浓度,降低不良反应,对平均和谷值则影响不大。[28]
锂有异味。饭后服药,比较不会不舒服。食物也会增加吸收率。[28]
药物副作用与不良反应
[编辑]- 胃肠方面:恶心及呕吐是最常见的副作用,大约出现在50%的人身上。分成多次在饭后服药可以减轻这方面的不舒服。恶心呕吐在刚开始服药的几个星期会发生,会慢慢减轻,如果是治疗的后期变得比较严重,则要考虑锂中毒的可能性。另外有30%的人会抱怨体重增加。
- 中枢神经及肌肉方面:这方面包括疲倦、头晕、觉得手脚较沉重无力、手抖、思变得比较迟钝不敏锐。一般治疗剂量下,锂引起的手抖属微抖,锂中毒时,手抖会很明显。
- 肾脏系统肾脏系统:频尿及易口渴也是常见的副作用,多数人这类副作用会慢慢改善,但是少数人会出现尿崩症。所以在治疗前需检查肾功能,治疗期间也要定期检查肾功能。
- 心脏血管系统:锂可引起类似低血钾的心电图变化,这些变化通常是良性的。少数人会出现较严重的心脏窦节传导障碍,所以心脏病患者用锂盐要小心。
- 皮肤方面:有些人会出现长面疱、掉发。少数人会出现牛皮癣。另外有些人服用锂盐后会出现史蒂芬斯-强森综合症,严重者会致命。
- 甲状腺功能:有些人会呈现甲状腺机能低下,一些人在继续治疗中,甲状腺机能会复原,有一些需要服用甲状腺荷尔蒙。
- 精神方面:有些人服用后会有躁动的情况(两脚不住跺着地面的行为)。
- (注意)长期服用锂盐可能影响甲状腺和肾功能,患者必须定期追踪。
肾脏
[编辑]比较老的文献认为锂和肾病有关联性。[29][30] 大约一半的长期用者有肾源性尿崩症,[30]传统上认为还可能恶化到后期尿崩,[31][32]甚至0.2-0.7%最终肾衰。[33]
更新的、更严谨的临床数据并不能证明锂有这些严重伤害。[34]Nielsen et al. (2018)收集了2010年起的6个大型观察式研究,发现肾功能降低的情况有被监视偏差夸大。[35]Davis et al. (2018)采用1977–2018的文献,发现锂和慢性肾病和肾衰竭的关联证据不足,且研究数据互相矛盾。[36]
全美国的研究指出,锂维持在在0.6–0.8 mmol/L浓度,并每三到六月测量肌酸酐,足以防止肾病产生。[35]
甲状腺
[编辑]传统认为锂会导致甲状腺功能减退(甲减)。实际上甲减是双相患者常见的并发症,和锂没有关系。Lambert 等人 (2016) 比较了使用 9 种不同药物治疗的双相情感障碍患者的甲状腺功能减退症发生率,发现锂盐使用者在双相情感障碍患者中的甲状腺功能减退症发生率并不特别高 (8.8%),仅为 奥卡西平 使用者 (6.3%) 的 1.39 倍。锂盐和喹硫平在甲状腺功能减退症发生率方面没有统计学差异。然而,锂盐使用者接受甲状腺功能减退症检测的频率比使用其他药物的人高得多。作者写道,在理解锂盐对甲状腺的影响时可能存在监测偏差,因为锂盐使用者接受检测的频率是其他药物的 2.3 到 3.1 倍。此外,作者认为,由于无论是否接受锂盐治疗,甲状腺功能减退症在双相情感障碍患者中都很常见,因此应该对所有双相情感障碍患者进行定期甲状腺检测,而不仅仅是那些接受锂盐治疗的患者。[37][35]
怀孕
[编辑]病例报告显示锂会导致先天性心脏病。发病率和孕期及剂量相关,孕早期高剂量更危险。[38][39][40]
由于停用锂后果可能严重,也有医生权衡利弊后推荐怀孕病人继续使用的情况。[41]推荐这类病人使用超声检测胎儿心脏发育。[42]
未发现锂对胎儿的大脑发育有影响。[43]
哺乳
[编辑]少量锂进入乳汁,暂不明确是否有后果。[44][45][46]
服用过量和中毒
[编辑]当人意外或故意服用过量,也许会发生锂中毒的急性作用。当人在治疗中累积高剂量,也许会发生锂中毒的慢性作用。 症状包括恶心、呕吐、腹泻、虚弱、失调、混乱、无生气、多尿症、癫痫发作和昏迷。其它锂中毒反应包括普遍的颤抖、肌束颤搐、惊厥和肾功能衰竭。[47] 关于急性锂中毒或长期用恰当的剂量治疗,从中毒存活下来的人可能产生持续性的神经毒性,许多人已经描述是一种"不可逆的神经锂中毒症状" (SILENT)。包括小脑的官能障碍。[48]
服用过量时,通常血液浓度超过1.5 mmol Li+/l, 可能是严重的,并且中毒反应包括颤抖、失调、发音困难、眼球震颤、肾功能衰竭、混乱和惊厥。假如这些潜在的危害症状出现,应该停止治疗,依血液的锂浓度再决定回复锂中毒的措施。
锂中毒会消耗钠。同时使用利尿剂时,禁止由远位尿细管摄取钠(例如:噻嗪类利尿剂),这是应该避免而且有危害的,因为这可能会加强锂在近位尿细管的再吸收,导致潜在的中毒层级提高。在轻微的案例,抽出锂并且给予充足的钠流体将会从中毒中回复。血液浓度超过2.5 mmol Li+ /l通常算是严重中毒,需要急救。当达到中毒浓度,最强烈的中毒也许有1或2天的延迟才发生。
- 锂中毒:锂中毒的症状从轻到重如下。
- 轻度中毒:血液锂浓度在1.5-2.0 mmol/L,人讲话会变得口齿不清、显著手抖、水泻、嗜睡。
- 中度中毒:血液锂浓度超过2.0 mmol/L时,病人会呈现意识障碍、肌腱反射高亢、抽筋、血压不稳、循环衰竭、急性肾小管坏死、心电图异常、全身僵硬。
- 重度中毒:血液锂浓度超过4.0 mmol/L可能会危及生命,或留下脑不可逆性性的损伤。
- 认知障碍。
- 有些患者则有口齿不清、嗜睡的情形出现,须考虑是否为血中锂盐浓度过高所起的中毒现象,须紧急送医。
- 话多、情绪亢奋、每天睡眠少于3小时,严重会有暴力倾向,甚至自杀等。
机理
[编辑]目前对作用机理不明确,不排除同时存在多个机理的可能。比较受支持的理论是锂激活MEK通路,从而抑制GSK3B,激活mTOR通路,通过Akt/PKB信号通路起到神经保护作用。[49]支持这一理论的证据是:
- GSK3B受单胺系统调控,躁狂期被激活。[50][49]
- GSK3B通过磷酸基化抑制Β-连环蛋白和CREB两种转录因子,导致神经营养因子表达下降。锂可以造成BDNF等因子表达回升。[51][52][53]长期使用锂的患者负责情绪和认知的大脑区域,灰质体积有提升。[54]不用锂双相患者的大脑白质完整性较正常人低,但用锂的则无区别。[55]丙戊酸对灰质有类似的效果,对白质没有。[54]长期使用锂可以增加双相患者的认知能力。[56]
- 抑制CREB也会增加Bcl-2转录。这样可以增加线粒体抗氧化能力,抑制细胞凋亡,延长神经元寿命。[54][57]
此外锂也会通过AP-1转录因子增加中脑星形胶质细胞衍生的神经营养因子表达。MANF可以调控涉及未折叠蛋白反应的因子GRP78。[58]
另外还有pAp-磷酸酶、[59]一氧化氮、[60]、NMDA受体[61]等可能原理。
研究
[编辑]暂不清楚锂对于人类寿命的影响。曾有研究说锂导致端粒延长、全因死亡率下降,但2024年大型的英国BioBank研究并无发现此效果,只是静息心率稍低。[62]2023年基于英国BioBank的研究声称锂可降低全因死亡率,但由于数据授权原因(BioBank数据当时授权给作者用于新冠病毒相关研究)已撤回。[63]
参考资料
[编辑]- ^ Lithium brands. Drugs.com. [4 April 2017]. (原始内容存档于5 April 2017).
- ^ 2.00 2.01 2.02 2.03 2.04 2.05 2.06 2.07 2.08 2.09 2.10 2.11 2.12 Lithium Salts. The American Society of Health-System Pharmacists. [Dec 1, 2015]. (原始内容存档于2015-12-08).
- ^ Baldessarini, Ross J; Tondo, Leonardo; Davis, Paula; Pompili, Maurizio; Goodwin, Frederick K; Hennen, John. Decreased risk of suicides and attempts during long-term lithium treatment: A meta-analytic review. Bipolar Disorders. 2006, 8 (5p2): 625–39. PMID 17042835. doi:10.1111/j.1399-5618.2006.00344.x.
- ^ Lithium use while Breastfeeding. LactMed. 2015-03-10 [1 December 2015]. (原始内容存档于8 December 2015).
- ^ Sneader, Walter. Drug discovery : a history Rev. and updated. Chichester: Wiley. 2005: 63. ISBN 9780471899792. (原始内容存档于2017-09-08).
- ^ WHO Model List of Essential Medicines (19th List) (PDF). World Health Organization. April 2015 [8 December 2016]. (原始内容存档 (PDF)于13 December 2016).
- ^ Lithium Carbonate. International Drug Price Indicator Guide. [1 December 2015].[永久失效链接]
- ^ McKnight RF, de La Motte de Broöns de Vauvert SJ, Chesney E, Amit BH, Geddes J, Cipriani A. Lithium for acute mania. The Cochrane Database of Systematic Reviews. June 2019, 2019 (6): CD004048. PMC 6544558
. PMID 31152444. doi:10.1002/14651858.CD004048.pub4.
- ^ Rakofsky JJ, Lucido MJ, Dunlop BW. Lithium in the treatment of acute bipolar depression: A systematic review and meta-analysis. Journal of Affective Disorders. July 2022, 308: 268–280. PMID 35429528. S2CID 248161621. doi:10.1016/j.jad.2022.04.058.
- ^ Riedinger MA, van der Wee NJ, Giltay EJ, de Leeuw M. Lithium in bipolar depression: A review of the evidence. Human Psychopharmacology. September 2023, 38 (5): e2881. PMID 37789577. doi:10.1002/hup.2881 . hdl:10067/2003410151162165141 .
- ^ Cai L, Chen G, Yang H, Bai Y. Efficacy and safety profiles of mood stabilizers and antipsychotics for bipolar depression: a systematic review. International Clinical Psychopharmacology. July 2023, 38 (4): 249–260. PMID 36947416. S2CID 257665886. doi:10.1097/YIC.0000000000000449.
- ^ Rosenberg JM, Salzman C. Update: new uses for lithium and anticonvulsants. CNS Spectrums. November 2007, 12 (11): 831–841. PMID 17984856. S2CID 26227696. doi:10.1017/S1092852900015571.
- ^ Frye MA, Salloum IM. Bipolar disorder and comorbid alcoholism: prevalence rate and treatment considerations. Bipolar Disorders. December 2006, 8 (6): 677–685. PMID 17156154. doi:10.1111/j.1399-5618.2006.00370.x.
- ^ Vornik LA, Brown ES. Management of comorbid bipolar disorder and substance abuse. The Journal of Clinical Psychiatry. 2006, 67 (Suppl 7): 24–30. PMID 16961421.
- ^ Nabi Z, Stansfeld J, Plöderl M, Wood L, Moncrieff J. Effects of lithium on suicide and suicidal behaviour: a systematic review and meta-analysis of randomised trials. Epidemiology and Psychiatric Sciences. September 2022, 31: e65. PMC 9533115 . PMID 36111461. doi:10.1017/S204579602200049X .
- ^ Bauer M, Adli M, Ricken R, Severus E, Pilhatsch M. Role of lithium augmentation in the management of major depressive disorder. CNS Drugs. April 2014, 28 (4): 331–342. PMID 24590663. S2CID 256840. doi:10.1007/s40263-014-0152-8.
- ^ Bauer M, Adli M, Baethge C, Berghöfer A, Sasse J, Heinz A, Bschor T. Lithium augmentation therapy in refractory depression: clinical evidence and neurobiological mechanisms. Canadian Journal of Psychiatry. August 2003, 48 (7): 440–448. PMID 12971013. doi:10.1177/070674370304800703.
- ^ Undurraga J, Sim K, Tondo L, Gorodischer A, Azua E, Tay KH, Tan D, Baldessarini RJ. Lithium treatment for unipolar major depressive disorder: Systematic review. Journal of Psychopharmacology. February 2019, 33 (2): 167–176 [20 February 2024]. PMID 30698058. S2CID 59411183. doi:10.1177/0269881118822161. (原始内容存档于20 February 2024).
- ^ Crossley, NA; Bauer, M. Acceleration and augmentation of antidepressants with lithium for depressive disorders: two meta-analyses of randomized, placebo-controlled trials.. The Journal of clinical psychiatry. 2007-06, 68 (6): 935–40. PMID 17592920. doi:10.4088/jcp.v68n0617.
- ^ Finley PR. Drug Interactions with Lithium: An Update. Clinical Pharmacokinetics. August 2016, 55 (8): 925–941. PMID 26936045. doi:10.1007/s40262-016-0370-y.
- ^ Bauer M, Gitlin M. Treatment of Depression with Lithium. The Essential Guide to Lithium Treatment. Cham: Springer International Publishing. 2016: 71–80. ISBN 978-3-319-31212-5. doi:10.1007/978-3-319-31214-9_7.
- ^ 22.0 22.1 Haussmann R, Noppes F, Brandt MD, Bauer M, Donix M. Lithium: A therapeutic option in Alzheimer's disease and its prodromal stages?. Neuroscience Letters. August 2021, 760: 136044. PMID 34119602. S2CID 235385875. doi:10.1016/j.neulet.2021.136044.
- ^ Wei HF, Anchipolovsky S, Vera R, Liang G, Chuang DM. Potential mechanisms underlying lithium treatment for Alzheimer's disease and COVID-19. European Review for Medical and Pharmacological Sciences. March 2022, 26 (6): 2201–2214. PMC 9173589 . PMID 35363371. doi:10.26355/eurrev_202203_28369.
- ^ Moon, Woori; Ji, Eunjeong; Shin, Juyoung; Kwon, Jun Soo; Kim, Ki Woong. Effect of valproate and lithium on dementia onset risk in bipolar disorder patients. Scientific Reports. 2022-08-19, 12 (1). doi:10.1038/s41598-022-18350-1.
- ^ Grandjean EM, Aubry JM. Lithium: updated human knowledge using an evidence-based approach. Part II: Clinical pharmacology and therapeutic monitoring. CNS Drugs (Springer Science and Business Media LLC). 2009, 23 (4): 331–349. PMID 19374461. S2CID 38042857. doi:10.2165/00023210-200923040-00005.
- ^ Solomon DA, Ristow WR, Keller MB, Kane JM, Gelenberg AJ, Rosenbaum JF, Warshaw MG. Serum lithium levels and psychosocial function in patients with bipolar I disorder. The American Journal of Psychiatry. October 1996, 153 (10): 1301–1307. PMID 8831438. doi:10.1176/ajp.153.10.1301.
- ^ Perlis RH, Sachs GS, Lafer B, Otto MW, Faraone SV, Kane JM, Rosenbaum JF. Effect of abrupt change from standard to low serum levels of lithium: a reanalysis of double-blind lithium maintenance data. The American Journal of Psychiatry. July 2002, 159 (7): 1155–1159. PMID 12091193. doi:10.1176/appi.ajp.159.7.1155.
- ^ 28.0 28.1 Girardi, P; Brugnoli, R; Manfredi, G; Sani, G. Lithium in Bipolar Disorder: Optimizing Therapy Using Prolonged-Release Formulations.. Drugs in R&D. 2016-12, 16 (4): 293–302. PMID 27770296. doi:10.1007/s40268-016-0139-7.
- ^ Nielsen J, Kwon TH, Christensen BM, Frøkiaer J, Nielsen S. Dysregulation of renal aquaporins and epithelial sodium channel in lithium-induced nephrogenic diabetes insipidus. Seminars in Nephrology. May 2008, 28 (3): 227–244. PMID 18519084. doi:10.1016/j.semnephrol.2008.03.002.
- ^ 30.0 30.1 Alexander MP, Farag YM, Mittal BV, Rennke HG, Singh AK. Lithium toxicity: a double-edged sword. Kidney International. January 2008, 73 (2): 233–237. PMID 17943083. doi:10.1038/sj.ki.5002578 .
- ^ Sands JM, Bichet DG. Nephrogenic diabetes insipidus. Annals of Internal Medicine. February 2006, 144 (3): 186–194. PMID 16461963. S2CID 6732380. doi:10.7326/0003-4819-144-3-200602070-00007.
- ^ Garofeanu CG, Weir M, Rosas-Arellano MP, Henson G, Garg AX, Clark WF. Causes of reversible nephrogenic diabetes insipidus: a systematic review. American Journal of Kidney Diseases. April 2005, 45 (4): 626–637. PMID 15806465. doi:10.1053/j.ajkd.2005.01.008.
- ^ Presne C, Fakhouri F, Noël LH, Stengel B, Even C, Kreis H, Mignon F, Grünfeld JP. Lithium-induced nephropathy: Rate of progression and prognostic factors. Kidney International. August 2003, 64 (2): 585–592. PMID 12846754. doi:10.1046/j.1523-1755.2003.00096.x .
- ^ 引用错误:没有为名为
pmid38289425的参考文献提供内容 - ^ 35.0 35.1 35.2 Kessing LV. Why is lithium [not] the drug of choice for bipolar disorder? a controversy between science and clinical practice. International Journal of Bipolar Disorders. January 2024, 12 (1): 3. PMC 10792154 . PMID 38228882. doi:10.1186/s40345-023-00322-7 .
- ^ Davis J, Desmond M, Berk M. Lithium and nephrotoxicity: Unravelling the complex pathophysiological threads of the lightest metal. Nephrology (Wiley). October 2018, 23 (10): 897–903. PMID 29607573. S2CID 4552345. doi:10.1111/nep.13263 . hdl:11343/283773 .
- ^ Lambert CG, Mazurie AJ, Lauve NR, Hurwitz NG, Young SS, Obenchain RL, Hengartner NW, Perkins DJ, Tohen M, Kerner B. Hypothyroidism risk compared among nine common bipolar disorder therapies in a large US cohort. Bipolar Disorders. May 2016, 18 (3): 247–260. PMC 5089566 . PMID 27226264. doi:10.1111/bdi.12391.
- ^ Essential Reads: Lithium and Pregnancy. MGH Center for Women's Mental Health. 2021-03-04 [2024-12-05] (美国英语).
- ^ Poels EM, Bijma HH, Galbally M, Bergink V. Lithium during pregnancy and after delivery: a review. International Journal of Bipolar Disorders. December 2018, 6 (1): 26. PMC 6274637 . PMID 30506447. doi:10.1186/s40345-018-0135-7 .
- ^ Reprotox • Login. reprotox.org. [2024-12-05].
- ^ Lithium in pregnancy and breastfeeding. www.rcpsych.ac.uk. [2024-12-05] (英语).
- ^ Armstrong C. ACOG Guidelines on Psychiatric Medication Use During Pregnancy and Lactation. American Family Physician. 2008-09-15, 78 (6): 772–778 (美国英语).
- ^ Poels, Eline M. P.; Kamperman, Astrid M.; Bijma, Hilmar H.; Honig, Adriaan; van Kamp, Inge L.; Kushner, Steven A.; Hoogendijk, Witte J. G.; Bergink, Veerle; White, Tonya. Brain development after intrauterine exposure to lithium: A magnetic resonance imaging study in school‐age children. Bipolar Disorders. 2023-05, 25 (3): 181–190. doi:10.1111/bdi.13297.
- ^ Reprotox • Login. reprotox.org. [2024-12-05].
- ^ Nonacs R. Essential Reads: Lithium and Breastfeeding (2024) - MGH Center for Women's Mental Health. 2024-11-13 [2024-12-05] (美国英语).
- ^ Pregnancy, breastfeeding and fertility while taking lithium. nhs.uk. 2023-08-14 [2024-12-05] (英语).
- ^ Gelder, M., Mayou, R. and Geddes, J. 2005. Psychiatry. 3rd ed. New York: Oxford. pp249.
- ^ Adityanjee; Munshi, Thampy. The syndrome of irreversible lithium-effectuated neurotoxicity.. Clinical Neuropharmacology. 2005, 28 (1): 38–49. PMID 15714160. doi:10.1097/01.wnf.0000150871.52253.b7.
- ^ 49.0 49.1 Malhi GS, Masson M, Bellivier F. The Science and Practice of Lithium Therapy. Springer International Publishing. 2017: 62. ISBN 978-3-319-45923-3. OCLC 979600268.
- ^ Einat H, Manji HK. Cellular plasticity cascades: genes-to-behavior pathways in animal models of bipolar disorder. Biological Psychiatry. June 2006, 59 (12): 1160–1171. PMID 16457783. S2CID 20669215. doi:10.1016/j.biopsych.2005.11.004.
- ^ Gould TD, Picchini AM, Einat H, Manji HK. Targeting glycogen synthase kinase-3 in the CNS: implications for the development of new treatments for mood disorders. Current Drug Targets. November 2006, 7 (11): 1399–1409. PMID 17100580. doi:10.2174/1389450110607011399.
- ^ Böer U, Cierny I, Krause D, Heinrich A, Lin H, Mayr G, Hiemke C, Knepel W. Chronic lithium salt treatment reduces CRE/CREB-directed gene transcription and reverses its upregulation by chronic psychosocial stress in transgenic reporter gene mice. Neuropsychopharmacology. September 2008, 33 (10): 2407–2415. PMID 18046304. doi:10.1038/sj.npp.1301640 .
- ^ Berk M, Kapczinski F, Andreazza AC, Dean OM, Giorlando F, Maes M, Yücel M, Gama CS, Dodd S, Dean B, Magalhães PV, Amminger P, McGorry P, Malhi GS. Pathways underlying neuroprogression in bipolar disorder: focus on inflammation, oxidative stress and neurotrophic factors. Neuroscience and Biobehavioral Reviews. January 2011, 35 (3): 804–817. PMID 20934453. S2CID 11421586. doi:10.1016/j.neubiorev.2010.10.001.
- ^ 54.0 54.1 54.2 Quiroz JA, Machado-Vieira R, Zarate CA, Manji HK. Novel insights into lithium's mechanism of action: neurotrophic and neuroprotective effects. Neuropsychobiology. 2010, 62 (1): 50–60. PMC 2889681 . PMID 20453535. doi:10.1159/000314310.
- ^ Necus J, Sinha N, Smith FE, Thelwall PE, Flowers CJ, Taylor PN, Blamire AM, Cousins DA, Wang Y. White matter microstructural properties in bipolar disorder in relationship to the spatial distribution of lithium in the brain. Journal of Affective Disorders. June 2019, 253: 224–231. PMC 6609924 . PMID 31054448. doi:10.1016/j.jad.2019.04.075.
- ^ Burdick, KE; Millett, CE; Russo, M; Alda, M; Alliey-Rodriguez, N; Anand, A; Balaraman, Y; Berrettini, W; Bertram, H; Calabrese, JR; Calkin, C; Conroy, C; Coryell, W; DeModena, A; Feeder, S; Fisher, C; Frazier, N; Frye, M; Gao, K; Garnham, J; Gershon, ES; Glazer, K; Goes, FS; Goto, T; Harrington, GJ; Jakobsen, P; Kamali, M; Kelly, M; Leckband, S; Løberg, EM; Lohoff, FW; Maihofer, AX; McCarthy, MJ; McInnis, M; Morken, G; Nievergelt, CM; Nurnberger, J; Oedegaard, KJ; Ortiz, A; Ritchey, M; Ryan, K; Schinagle, M; Schwebel, C; Shaw, M; Shilling, P; Slaney, C; Stapp, E; Tarwater, B; Zandi, P; Kelsoe, JR. The association between lithium use and neurocognitive performance in patients with bipolar disorder.. Neuropsychopharmacology : official publication of the American College of Neuropsychopharmacology. 2020-09, 45 (10): 1743–1749. PMID 32349118. doi:10.1038/s41386-020-0683-2.
- ^ Malhi GS, Tanious M, Das P, Coulston CM, Berk M. Potential mechanisms of action of lithium in bipolar disorder. Current understanding. CNS Drugs. February 2013, 27 (2): 135–153. PMID 23371914. S2CID 26907074. doi:10.1007/s40263-013-0039-0. hdl:11343/218106 .
- ^ Abu-Hijleh FA, Prashar S, Joshi H, Sharma R, Frey BN, Mishra RK. Novel mechanism of action for the mood stabilizer lithium. Bipolar Disorders. February 2021, 23 (1): 76–83. PMID 33037686. S2CID 222257563. doi:10.1111/bdi.13019.
- ^ Toledano E, Ogryzko V, Danchin A, Ladant D, Mechold U. 3'-5' phosphoadenosine phosphate is an inhibitor of PARP-1 and a potential mediator of the lithium-dependent inhibition of PARP-1 in vivo. The Biochemical Journal. April 2012, 443 (2): 485–490. PMC 3316155 . PMID 22240080. doi:10.1042/BJ20111057.
- ^ Ghasemi M, Sadeghipour H, Mosleh A, Sadeghipour HR, Mani AR, Dehpour AR. Nitric oxide involvement in the antidepressant-like effects of acute lithium administration in the mouse forced swimming test. European Neuropsychopharmacology. May 2008, 18 (5): 323–332. PMID 17728109. S2CID 44805917. doi:10.1016/j.euroneuro.2007.07.011.
- ^ Ghasemi M, Raza M, Dehpour AR. NMDA receptor antagonists augment antidepressant-like effects of lithium in the mouse forced swimming test. Journal of Psychopharmacology. April 2010, 24 (4): 585–594. PMID 19351802. S2CID 41634565. doi:10.1177/0269881109104845.
- ^ Mutz, Julian; Wong, Win Lee Edwin; Powell, Timothy R.; Young, Allan H.; Dawe, Gavin S.; Lewis, Cathryn M. The duration of lithium use and biological ageing: telomere length, frailty, metabolomic age and all-cause mortality. GeroScience. 2024-03-28, 46 (6): 5981–5994. doi:10.1007/s11357-024-01142-y.
- ^ Araldi, E; Jutzeler, CR; Ristow, M. Lithium treatment extends human lifespan: findings from the UK Biobank.. Aging. 2023-01-11, 15 (2): 421–440. PMID 36640269. doi:10.18632/aging.204476.
