通用中文 | 依伐卡托片 | 通用外文 | IVACAFTOR |
品牌中文 | 品牌外文 | Kalydeco | |
其他名称 | |||
公司 | Vertex(Vertex) | 产地 | 德国(Germany) |
含量 | 75mg | 包装 | 56片/盒 |
剂型给药 | 储存 | 室温 | |
适用范围 | 囊性纤维化 |
通用中文 | 依伐卡托片 |
通用外文 | IVACAFTOR |
品牌中文 | |
品牌外文 | Kalydeco |
其他名称 | |
公司 | Vertex(Vertex) |
产地 | 德国(Germany) |
含量 | 75mg |
包装 | 56片/盒 |
剂型给药 | |
储存 | 室温 |
适用范围 | 囊性纤维化 |
免责声明:
本说明书仅供参考,不作为治疗的依据
不可取代任何医生、药剂师等专业性的指导.
本站不提供治疗建议。
药物是否适合您,请专业医生(或药剂师)决定。
Kalydeco(ivacaftor)使用说明书
2012年第一版
批准日期:2012年1月31日;
公司:Vertex Pharmaceuticals Incorporated
品牌英文KALYDECO
通用英文ivacaftor
美国初次批准:2012年
[适应证和用途]
KALYDECO被分类为一种囊性纤维化跨膜电导调节器(cystic fibrosis transmembrane conductance regulator,CFTR)增效剂。KALYDECO是适用于在年龄6岁和以上,CFTR基因有一种G551D突变患者的囊性纤维化(CF)的治疗。如果患者的基因型是未知,应使用FDA批准的CF突变试验检测G551D突变的存在。(1)
[使用的限制]
(1)对在CFTR基因中F508del突变纯合子CF患者无效。(1, 14)
(2)尚未研究在其它人群CF患者中研究KALYDECO。(1, 14)
[剂量和给药方法]
(1)年龄6岁和以上成年和儿童患者:每12小时与含脂肪食物口服1片150 mg。(2, 12.3)
(2)在有中度和严重肝受损患者中减低剂量。(8.6, 12.3)
(3)当与中度或强CYP3A抑制剂药物共同给药时减低剂量。(7.1, 12.3)
[剂型和规格]
片:150 mg (3)
[禁忌证]
无已知的。
[警告和注意事项]
(1)转氨酶升高(ALT或AST):开始KALYDECO前,治疗头一年期间每3个月,和其后每年应评估转氨酶(ALT和AST)。发生增加转氨酶水平患者应严密监视直至异常解决。在有ALT或AST大于正常上限(ULN)的5倍患者应中断给药。转氨酶升高解决后,考虑恢复KALYDECO给药的获益和风险。(5.1, 6)
(2)与CYP3A诱导剂使用:与强CYP3A诱导剂同时使用(如,利福平[rifampin],圣约翰草[St. John’s Wort]) 实质上减低ivacaftor的暴露可能减弱有效性。所以,不建议共同给药(5.2, 7.2, 12.3)。
[不良反应]
最常见对KALYDECO药物不良反应(在CFTR基因中发生 ≥8%有一种G551D 突变CF患者)是头痛,口咽痛,上呼吸道感染,鼻充血,腹痛,鼻咽炎,腹泻,皮疹,恶心,和头晕。6.1)
[药物相互作用]
CYP3A抑制剂:当与强CYP3A抑制剂共同给药时,减低KALYDECO剂量至150 mg一周2次(如,酮康唑[ketoconazole])。当与中度CYP3A抑制剂共同给药时(如,氟康唑[fluconazole])减低KALYDECO剂量至150 mg每天1次。避免食物含柚子汁或塞维利亚桔子。(7.1, 12.3)
1 适应证和用途
KALYDECO被分类为一种囊性纤维化跨膜电导调节器(CFTR)增效剂。KALYDECO适用于年龄6岁和以上在CFTR基因中有一种G551D突变囊性纤维化(CF)患者的治疗。如患者的基因型未知,应使用FDA批准的CF突变试验检测G551D突变的存在。
[使用限制]
KALYDECO对在CFTR基因中F508del突变纯合子CF患者无效和未曾研究CF其它患者群。
2 剂量和给药方法
2.1 在成年和儿童年龄 6岁和以上中的给药信息
对成年和儿童患者年龄6岁和以上的推荐KALYDECO剂量是150 mg片口服每12小时(300 mg每天总量)与含脂肪食物。适当的含脂肪食物实例包括蛋,黄油,花生黄油,奶酪比萨,等。[见临床药理学(12.3)和患者咨询资料(17.4)].
2.2 对有肝受损患者剂量调整
对有中度肝受损患者KALYDECO的剂量应减低至150 mg每天1次(Child-Pugh类别B)。有严重肝受损患者(Child-Pugh类别C)应在KALYDECO剂量150 mg每天次或频数更低谨慎使用[见特殊人群中使用 (8.6), 临床药理学(12.3),和患者咨询资料(17.3)]。
2.3 对服用CYP3A抑制剂药物患者的剂量调整
当KALYDECO正在与强CYP3A抑制剂(如,酮康唑)共同给药时剂量应减低至150 mg每周2次。当与中度CYP3A抑制剂共同给药时(如,氟康唑)KALYDECO的剂量应减低至150 mg每天1次。应避免含柚子汁或塞维利亚桔子食物[见药物相互作用(7.1), 临床药理学(12.3),和患者咨询资料(17.2)]。
3 剂型和规格
150 mg片。
4 禁忌证
不知道。
5 警告和注意事项
5.1 转氨酶(ALT或AST) 升高
有CF患者接受KALYDECO曾报道转氨酶升高。建议在开始KALYDECO前,治疗头一年期间每3个月,和其后每年评估ALT和AST。发生转氨酶水平增加患者应被严密监视直至异常解决。在有ALT或AST大于正常上限(ULN)的5倍患者中应中断给药。转氨酶升高解决后, 考虑恢复KALYDECO给药的获益和风险[见不良反应(6)].
5.2 与CYP3A诱导剂同时使用
KALYDECO与强CYP3A诱导剂,例如利福平使用,实质上减低ivacaftor的暴露,可能减低KALYDECO治疗有效性。所以,建议KALYDECO不要与强CYP3A诱导剂(如,利福平, 圣约翰草)共同给药[见药物相互作用(7.2)和临床药理学(12.3)]。
6 不良反应
在说明书的其它章节更详细讨论下列不良反应:
(1)转氨酶升高[见警告和注意事项(5.1)]
6.1 临床试验经验
因为临床试验是在广泛不同情况下进行的,临床试验观察到不良反应率不能与另药临床试验发生率直接比较而且可能不反映实践中观察到的发生率。
KALYDECO的总体安全性图形是根据来自安慰剂-对照临床试验来自CFTR基因中有一种G551D突变或是对F508del突变纯合子的353例有CF患者的合并数据。353例患者中,50%患者是女性和97%是高加索人;221例接受KALYDECO和132例接受安慰剂来自16至48周。用KALYDECO治疗患者年龄是6和53岁间。
在这些试验中,由于不良反应提前终止研究药物患者比例对KALYDECO-治疗患者是2%而对安慰剂-治疗患者为5%。由研究中考虑严重的不良反应是否药物-相关,在KALYDECO-治疗患者发生更频,包括腹痛,增加肝酶,和低血糖。.
总而言之,在353例有CF患者最常见不良反应是头痛(17%),上呼吸道感染(16%),鼻充血(16%),恶心(10%),皮疹(10%),鼻炎(6%),头晕(5%),关节痛(5%),和痰中细菌(5%)。
下面是根据两项双盲,安慰剂-对照48-周临床试验总共213例在CFTR基因中有一种G551D突变有CF患者年龄6至53岁和用KALYDECO 150 mg口服治疗或安慰剂每天2次的不良反应的发生率。表1 显示在两项双盲,安慰剂-对照试验中在CFTR基因中有G551D突变有CF患者KALYDECO-治疗发生 ≥8%还比安慰剂-治疗患者发生率较高的不良反应。
在KALYDECO组发生频数4至7%其发生率超过安慰剂组的不良反应包括:
感染和虫染:鼻炎
调查研究:谷草转氨酶升高,痰中细菌,血糖增加,肝酶增加
肌肉骨骼和结缔组织疾病:关节痛,肌肉骨骼胸痛,肌痛
神经系统疾病:窦性头痛
呼吸,胸和纵隔疾病:咽红斑,胸痛,鼻窦充血,喘息
皮肤和皮下组织疾病:痤疮
[实验室异常]
转氨酶升高:在四周期间, 安慰剂-对照临床研究,在KALYDECO-治疗患者中最高转氨酶(ALT或AST)的发生率 >8,>5或>3 × ULN分别是2%,3%和6%而安慰剂-治疗患者分别2%,2%和8%。2例患者(2%)用安慰剂和1例用KALYDECO患者(0.5 %)所有 >8 ×ULN永远终止治疗对升高的转氨酶。2例用KALYDECO治疗患者报道有肝转氨酶升高严重的不良反应与之比较安慰剂无[见警告和注意事项(5.1)]。
7 药物相互作用
其它药物影响ivacaftor的潜能
7.1 CYP3A抑制剂
Ivacaftor是一种敏感的CYP3A底物。与酮康唑,一种强CYP3A抑制剂共同给药,显著地增加ivacaftor暴露[用曲线下面积(AUC)测量]8.5-倍。所以,建议与强CYP3A抑制剂,例如酮康唑, 伊曲康唑[itraconazole], 泊沙康唑[posaconazole],伏立康唑[voriconazole],泰利霉素[telithromycin],和克拉霉素[clarithromycin]共同给药时减低KALYDECO剂量至150 mg一周2次。
与氟康唑,一种CYP3A中度抑制剂共同给药,增加ivacaftor暴露3-倍。所以, 建议同时服用中度CYP3A抑制剂患者,例如氟康唑和红霉素[erythromycin],减低KALYDECO剂量至150 mg每天1次。
KALYDECO与柚子汁,含一种或以上成分中度抑制CYP3A的共同给药可能增加ivacaftor的暴露。所以,用KALYDECO治疗时应避免含柚子汁或塞维利亚桔子食物[见临床药理学(12.3)]。
7.2 CYP3A的诱导剂
与利福平,一种强CYP3A诱导剂共同给药显著减低ivacaftor暴露(AUC)约9-倍。所以,建议不与强CYP3A诱导剂,例如利福平、利福布汀[rifabutin]、苯巴比妥[Phenobarbital]、 卡马西平[carbamazepine]、苯妥英[phenytoin]、和圣约翰草共同给药[见警告和注意事项(5.2)和临床药理学(12.3)].
Ivacaftor影响其它药物的潜能
7.3 CYP3A和/或P-gp底物
Ivacaftor及其M1代谢物有抑制CYP3A和P-gp的潜能。与咪达唑仑[midazolam],一个敏感的CYP3A底物共同给药,增加咪达唑仑暴露1.5-倍,与CYP3A被ivacaftor的弱抑制作用。KALYDECO的给药可能增加CYP3A/或P-gp底物药物的全身暴露,可能增加或延长其治疗效应和不良事件。所以,建议当KALYDECO与CYP3A和/或P-gp底物,例如地高辛[digoxin],环孢霉素[cyclosporine],和他克莫司[tacrolimus]共同给药谨慎[见临床药理学(12.3)]。
8 特殊人群中使用
8.1 妊娠
致畸效应: 妊娠类别B。在妊娠妇女中没有KALYDECO的适当和良好-对照研究。在大鼠中在约为最大推荐人用(MRHD)(根据vacaftor及其代谢物AUC之和在母体剂量200 mg/kg/day)的6倍,Ivacaftor无致畸胎性。在兔中在MRHD(基于母体剂量100 mg/kg/day,分别对ivacaftor AUC)的约12倍,Ivacafto无致畸胎性。妊娠大鼠和兔中观察到ivacafto胎盘转运。因为动物生殖研究并非总能预测人反应,妊娠期间只有明确需求才应使用KALYDECO。
8.3 哺乳母亲
Ivacaftor排泄至哺乳雌性大鼠乳汁中。Ivacaftor很可能排泄至人乳汁。没有人研究ivacaftor对哺乳婴儿的影响。当给予哺乳妇女KALYDECO应谨慎。
8.4 儿童使用
在6至7岁CFTR基因中有G551D突变CF患者的2项安慰剂-对照临床试验曾显示KALYDECO的安全性和疗效。试验1评价161例12岁或以上有CF患者和试验2评价52例6至11岁有CF患者[见临床研究(14.1)]。
尚未确定KALYDECO在年龄6岁更小CF患者的安全性和疗效。
8.5 老年人使用
CF很大程度是一种儿童和年轻成人的疾病。KALYDECO的临床试验没有包括足够数65岁和以上患者以确定他们是否与较年轻患者反应不同。
8.6 肝受损
对轻度肝受损患者(Child-Pugh类别A)无需调整剂量。中度肝受损患者(Child-Pugh类别B)建议减低剂量至150 mg每天1次。未曾在严重肝受损患者进行研究(Child-Pugh类别C)但预计暴露较高于中度肝受损患者。所以,严重肝受损患者中权衡治疗风险和获益后慎用剂量150 mg每天1次或频数更低[见药代动力学(12.3)]。
8.7 肾受损
未曾在轻度,中度,或严重肾受损或末期肾病患者中研究KALYDECO。对轻至中度肾受损患者无需调整剂量;然而,建议严重肾受损患者(肌酐清除率小于或等于30 mL/min)或肾病末期患者中慎用KALYDECO。
8.8 对在CFTR基因中F508del突变纯合子CF患者
来自CFTR基因中F508del突变纯合子CF患者中一项双盲,安慰剂-对照试验的疗效结果显示历时16周KALYDECO治疗与安慰剂比较,一秒钟用力呼气量(FEV1)无统计上显著差别[见临床研究(14.2)]。所以,对CFTR基因中F508del突变纯合子患者中不应使用KALYDECO。
10 药物过量
没有用KALYDECO过量的报告。
在一项临床研究使用最高单次剂量是800 mg在一种溶液剂无任何治疗-相关不良事件。
最高重复剂量是450 mg(片剂)每12小时1次共4.5天(9剂)在一项试验在健康受试者中评价KALYDECO对ECGs影响。与安慰剂比较报道的不良事件包括头晕和腹泻。
对KALYDECO过量无可供利用特异性抗毒药。用KALYDECO过量的治疗由一般支持措施组成包括监视生命体征和患者临床状态的观察。
11 一般描述
KALYDECO 片中活性成分是ivacaftor有下面化学名:N-(2,4-di-tert-butyl-5-hydroxyphenyl)-1,4-dihydro-4oxoquinoline-3-carboxamide. 其分子式是C24H28N2O3和分子量392.49。结构式如下:
Ivacaftor是一种白色淡白色粉实际上不溶于水(<0.05 μg/mL)。可得到KALYDECO为淡蓝色胶囊-形,薄膜衣片为口服给药含150 mg ivacaftor。每片含无活性成分胶体二氧化硅,交联羧甲基钠,羟丙基甲基纤维素醋酸琥珀,乳糖一水合物,硬脂酸镁,微晶纤维素,和十二烷基硫酸钠。片膜衣含巴西棕榈蜡,FD&C蓝#2,PEG 3350,聚乙烯醇,滑石粉,和二氧化钛。印墨水含氢氧化铵,氧化铁黑,丙二醇,和虫漆。
12 临床药理学
12.1 作用机制
Ivacaftor是CFTR蛋白的一种增效剂。CFTR蛋白是在许多器官内上皮细胞表面存在的一种氯离子通道。Ivacaftor有利于增加氯离子运输通过增强G551D-CFTR蛋白的通道开放概率(或门控选通[gating])。
在体外,ivacaftor增加CFTR-介导的穿越上皮电流[transepithelial current, IT)在表达G551D-CFTR蛋白啮齿类细胞中加入一种环腺苷酸(cAMP)激动剂EC50为100 ± 47 nM后;然而,在缺乏cAMP激动剂时ivacaftor不增加IT。在表达G551D-CFTR蛋白的人支气管上皮细胞中加入一种有EC50为236 nM的cAMP激动剂后Ivacaftor也增加IT。在单通道膜片钳实验中用来自啮齿动物表达G551D-CFTR蛋白膜片钳Ivacaftor增加G551D-CFTR蛋白开放概率与加入PKA和ATP相比为10-倍。
12.2 药效动力学
汗氯化物评价
在CFTR基因中有G551D突变患者临床试验中,KALYDECO导致汗中氯化物浓度统计上显著减低。在两项随机化,双盲,安慰剂-对照临床试验中(一项在12岁和以上患者和另一项患者6-11岁),汗中氯化物从基线至24周中位变化分别是-48 mmol/L(95% CI -51,-45)和-54 mmol/L(95% CI -62,-47)。这些变化持续至48周。汗中氯化物水平减低和肺功能(FEV1)中改善间无直接相关。
ECG评价
在72例健康受试者一项随机化,安慰剂-和阳性-对照(莫西沙星[moxifloxacin]400 mg)四阶段交叉至QT研究中评价多剂量ivacaftor 150 mg和450 mg每天2次对QTc间期的影响。在一项研究显示检测小效应能力,根据Fridericia的校正法(QTcF)基线-校正QTc对最大安慰剂校正的,单侧95%可信区间的上限是低于监管关注阈值10 ms。
12.3 药代动力学
健康成年志愿者和CF患者间 ivacaftor的药代动力学相似。
健康志愿者在饱腹状态口服给予单次150 mg剂量后,峰血浆浓度时间(Tmax)发生在约4小时,和均数(±SD) AUC和Cmax分别为10600(5260) ng*hr/mL和768(233) ng/mL。
每2小时给药,在第3至5天达到ivacaftor的稳态血浆浓度,与积蓄比值范围2.2至2.9。
吸收
当与含脂肪食物给予ivacaftor暴露增加约2-至4-倍。所以, KALYDECO应与含脂肪食物给药。含脂肪食物实例包括蛋,黄油,花生黄油,和奶酪比萨。在饱腹状态tmax中位数(范围)是约4.0(3.0; 6.0)小时。
分布
约99%的Ivacaftor结合至血浆蛋白,主要至α1-酸性糖蛋白和白蛋白。Ivacaftor不结合至人红细胞。
健康受试者和CF患者在饱腹状态单剂量275 mg KALYDECO后ivacaftor的平均表观分布容积(Vz/F)相似。健康志愿者在饱腹状态口服给予150 mg每12小时共7天后,平均(±SD)表观分布容积为353(122) L。
代谢
Ivacaftor在人中被广泛地代谢。在体外和临床研究表明ivacaftor主要是被CYP3A代谢。M1和M6是ivacaftor在人中的两个主要代谢物。M1的效力约ivacaftor的1/6和被认为有药理学活性。M6低于ivacaftor效力的1/50而不认为有药理学活性。
消除
口服给药后,大部分ivacaftor(87.8%)在粪中代谢转化后被消除。主要代谢物M1和M6约占总剂量的65%有22%以M1被消除和43%为M6。以未变化母药ivacaftor在尿中排泄量可忽略不计。单剂量后表观末端半衰期是约12小时。健康受试者和CF患者中ivacaftor的平均表观清除率(CL/F)相似。健康受试者150 mg剂量CL/F(SD)为17.3(8.4)L/hr。
特殊人群
肝受损
中度受损肝功能(Child-Pugh类型B,评分7至9)患者与人口统计指标匹配的健康受试者比较有相似的ivacaftor Cmax,但ivacaftor AUC0-∞增加约2-倍。所以,建议对有中度肝受损患者减低KALYDECO剂量150 mg每天1次。未曾研究轻度肝受损(Child-Pugh类别A)对ivacaftor的药代动力学的影响,但ivacaftor的AUC0-∞增加预计小于2-倍。所以,对轻度肝受损患者无需调整剂量。未曾研究严重肝受损(Child-Pugh类别C,评分10-15)对ivacaftor药代动力学的影响。不知道在这些患者中暴露增加的大小但预计大大高于中度肝受损患者观察值。当获益预计胜过风险,严重肝受损患者中KALYDECO应谨慎每天1次或更不频繁使用剂量150 mg给药。
肾受损
尚未在轻度、中度或严重肾受损患者(肌酐清除率小于或等于30 mL/min)或肾病末期患者中研究KALYDECO。对轻度和中度肾受损患者无需调整剂量因为在尿中ivacaftor及其代谢物消除可忽略不计(在一项人PK研究尿中仅回收6.6%总放射性);然而,当严重肾受损或肾病终末期患者给予KALYDECO建议谨慎。
性别
用来自KALYDECO临床研究数据群体药代动力学评价性别对KALYDECO药代动力学的影响。无需根据性别调整剂量。
药物相互作用
用KALYDECO和很可能共同给药或药代动力学相互作用研究中常被用作探针的药物的其它药物进行药物相互作用研究 [见药物相互作用(7)].
下面展示根据临床研究或潜在药物相互作用用KALYDECO的给药建议:
Ivacaftor影响其它药物的潜能
在体外研究显示ivacaftor是一种CYP3A的弱抑制剂和抑制P-gp的潜能。在治疗浓度时,和也可能抑制CYP2C8和CYP2C9同工酶。代谢物M1,但不是M6,也有抑制抑制CYP3A和P-gp潜能。Ivacaftor,M1,和M6不是CYP同工酶的诱导剂。在图1显示给予KALYDECO后对共同给药药物的给药建议:
注释: 有底物得到的数据但无KALYDECO共同给药被用作参比品。*NE:炔诺酮[Norethindrone];**EE:炔雌醇。垂直线分别分别是在0.8,1.0和1.25。
其它药物影响Ivacaftor的潜能
在体外研究显示ivacaftor和代谢物M1是CYP3A酶的底物(即,CYP3A4和CYP3A5)。在图2中显示KALYDECO与CYP3A抑制剂或诱导剂共同给药的给药建议:
图2:其它药物对KALYDECO的影响
注释:对KALYDECO无诱导剂或抑制剂用作为参比品共同给药得到数据。垂直线分别在0.8,1.0和1.25。
13 非临床毒理学
13.1 癌发生,突变发生,和生育能力受损
在小鼠和大鼠中进行3年研究评估KALYDECO的致癌性潜能。在ivacaftor口服剂量至200 mg/kg/day和50 mg/kg/day,分别(根据ivacaftor及其代谢物AUC之和约分别等于MRHD的3至5倍时),小鼠和大鼠中未观察到致瘤性证据。
Ivacaftor对以下分析中的遗传毒性是阴性:为细菌基因突变的Ames试验, 在体外 在中国仓鼠卵巢细胞染色体畸变分析,和体内小鼠微核试验。
Ivacaftor损伤生育能力和生殖性能指标,在雄性和雌性大鼠中在200 mg/kg/day时(根据ivacaftor及其代谢物AUC之和分别约为MRHD的5和6倍)。观察到在雌性中在200 mg/kg/day增加长期动情周期。在大鼠中当母兽给药前和早期妊娠期间200 mg/kg/day(根据ivacaftor及其代谢物AUC之和的MRHD约6倍)Ivacaftor还增加有全部非生存胚胎雌性数和减少黄体数,植入数,和活存胚胎数。在雄性和雌性大鼠中在200 mg/kg/day时,这些生育能力和生殖行为受损是归因于严重毒性。在≤100 mg/kg/day(根据ivacaftor及其代谢物AUC之和MRHD的约3倍)未观察到对雄性或雌性生育能力和生殖性能指标的影响。
14 临床研究
14.1在CFTR基因有一个G551D突变的CF患者中试验
剂量范围:
对剂量范围临床方案主要包括一项双盲,安慰剂-对照,交叉试验在39例成年(平均年龄31岁)高加索人有CF患者有预测的FEV1 ≥ 40%。20例患者在基线时有中位预测的FEV1 56%(范围:42%至109%)接受KALYDECO 25,75,150 mg或安慰剂每12小时共14天和19例患者在基线时有中位预测的FEV1 69%(范围:40%至122%)接受KALYDECO 150,250 mg或安慰剂每12小时共28天。150 mg每12小时剂量的选择主要根据肺功能轻微的[nominal]改善(给药前FEV1)和药效动力学参数的变化(汗氯化物和鼻潜力差别)。每天2次给药方案主要是根据表观末端血浆半衰期约12小时。对6至11岁儿童是根据观察到达到与成年患者观察到可比的药代动力学。
疗效:
在CFTR基因有一个G551D突变的CF患者中在两项随机化,双盲,安慰剂-对照临床试验在213例临床上稳定有CF患者(109例接受KALYDECO 150 mg每天2次)中评价KALYDECO的疗效。来自这些试验所有合格患者被滚动进入一项开放延伸研究。
试验1评价161例有CF患者年龄12岁或以上(平均年龄26岁)有基线预测的FEV1 40-90%间[平均预测的FEV1 64%(范围:32%至98%)]。试验2评价52例患者为6至11岁(平均年龄9岁)有基线预测的FEV1 40-105%间[平均预测的FEV1 84%(范围:44%至134%)]。在筛选时排除从痰中分离出有持久洋葱伯克霍尔德菌([Burkholderia cenocepacia], dolosa,或分支杆菌属[Mycobacterium] abcessus患者和那些有异常肝功能被定义为3或以上肝功能检验 (ALT,AST,AP,GGT,总胆红素) ≥正常上限3倍患者。
在两项试验中患者被1:1随机化至接受或150 mg KALYDECO或安慰剂每12小时与含脂肪食物共48周除了被处方CF治疗(如,妥布霉素[tobramycin],阿法链道酶[dornase alfa])。不允许使用吸入高渗盐水。
在两项研究中主要疗效终点是肺功能改善当用给药前预测的FEV1直至治疗第24周从基线平均绝对变化百分率。
在两项研究中,用KALYDECO治疗导致FEV1显著改善。在试验1中对从基线至24周预测的FEV1平均绝对变化百分率KALYDECO和安慰剂间治疗差别是10.6百分点(P < 0.0001)和在试验2中12.5百分点(P < 0.0001)(图3)。这些变化持续至48周。观察到预测的FEV1百分率改善不管年龄,疾病严重程度,性别,和地理区域。
图3: 预测的FEV1百分率从基线平均绝对变化*
其它疗效变量包括汗中氯化物从基线至第24周绝对变化[在临床药理学讨论(12.2)],直至第48周首次肺加重的时间(仅试验1),从基线至第48周体重绝对变化,和囊性纤维化症状改善 包括相关呼吸症状例如咳嗽,痰产生,和呼吸困难。对本研究的目的,肺加重被定义为抗生素治疗中变化(IV,吸入,或口服)当12项预先指定sino-肺体征/症状有4或更多的结果。用KALYDECO治疗患者显示肺加重的风险,CF症状(仅在试验1),和体重增重统计上显著改善(表2)。在患者<20岁中体重数据,当对年龄和性别用体重指数归一化表示时,与重量从基线绝对变化一致。
14.2对在CFTR基因中F508del突变纯合子患者试验
试验3是在140例年龄12岁和以上是在CFTR基因中对F508del突变纯合子和有预测的FEV1 ≥40%有CF患者中一项16-周随机化,双盲,安慰剂-对照,平行-组试验。患者被4:1随机化接受KALYDECO 150 mg (n=112) 每12小时或安慰剂(n=28)除了他们处方的CF治疗。被纳入患者平均年龄为23岁和平均基线预测的FEV1是79%(范围40%至129%)。因为在试验1和2中,排除在筛选时从痰分离持久洋葱伯克霍尔德菌([Burkholderia cenocepacia],dolosa,或分支杆菌属[Mycobacterium] abcessus和那些有异常肝功能被定义为3或更多肝功能检验(ALT,AST,AP,GGT,总胆红素) ≥正常上限3倍的患者。不允许使用吸入高渗盐水。
当用从基线至16周预测的FEV1百分率平均绝对变化测定主要终点肺功能改善。在CFTR基因中对F508del突变纯合子CF患者中用KALYDECO治疗相对于安慰剂导致FEV1无改善[从基线至16周预测的FEV1百分率平均绝对变化对患者KALYDECO和安慰剂-治疗组是分别1.5%和-0.2%(p = 0.15)]。用KALYDECO治疗患者与安慰剂比较对第二位终点间差别无意义(CF症状变化,体重变化,或汗中氯化物浓度变化)。
16 如何供应/贮存和处置
KALYDECOTM (ivacaftor)是以淡绿色,膜包衣,胶囊形含150 mg ivacaftor片供应。每片一侧印有字符“V 150”和另一侧平坦,和被包装如下:
56-计数盒(含4个独立泡卡每卡14片) NDC 51167-200-01和60-计数瓶NDC 51167-200-02
贮存在20-25ºC (68-77ºF);外出时允许15-30ºC (59-86ºF) [见美国药典控制室温]。
17 患者咨询资料
17.1 转氨酶(ALT或AST)升高和监视
告知患者用KALYDECO治疗患者中曾发生肝检验升高。开始用KALYDECO前和治疗头一年时每3个月和其后每年进行肝功能检验[见警告和注意事项(5.1)]。
17.2与CYP3A诱导剂和抑制剂药物相互作用
要求患者告诉你他们所用全部药物包括任何草药补品或维生素。建议KALYDECO不要与强CYP3A诱导剂(如,利福平, 圣约翰草)共同给药,因为它们减低KALYDECO的治疗有效性。当与强CYP3A抑制剂,例如酮康唑共同给药时建议减低KALYDECO剂量至150 mg一周2次。当与中度CYP3A抑制剂,例如氟康唑共同给药时建议减低剂量至150 mg 每天1次。应避免含柚子汁或Seville橘子食物[见药物相互作用(7.1, 7.2)和临床药理学(12.3)]。
17.3 有肝受损患者中使用
询问和/或评估患者是否有肝受损。中度受损肝功能患者中减低KALYDECO剂量(Child-Pugh类别B,评分7 至9)至每天1次150 mg。未曾在严重肝受损患者中研究KALYDECO (Child-Pugh类别C,评分10-15);然而,预计暴露大大高于中度肝受损患者观察值。当预计获益大于风险,严重肝受损患者应慎用KALYDECO剂量每天1次150 mg或频数更低。建议轻度肝受损患者无需调整剂量(Child-Pugh类别A,评分5-6)[见临床药理学(12.3)].
17.4 与含脂肪食物服用
告知患者当与脂肪食物服用KALYDECO机体吸收最佳。典型CF膳食将满足此要求。实例包括蛋、黄油、花生黄油、奶酪比萨等。
免责声明:
本说明书仅供参考,不作为治疗的依据
不可取代任何医生、药剂师等专业性的指导.
本站不提供治疗建议。
药物是否适合您,请专业医生(或药剂师)决定。
Kalydeco(ivacaftor)使用说明书
2012年第一版
批准日期:2012年1月31日;
公司:Vertex Pharmaceuticals Incorporated
品牌英文KALYDECO
通用英文ivacaftor
美国初次批准:2012年
[适应证和用途]
KALYDECO被分类为一种囊性纤维化跨膜电导调节器(cystic fibrosis transmembrane conductance regulator,CFTR)增效剂。KALYDECO是适用于在年龄6岁和以上,CFTR基因有一种G551D突变患者的囊性纤维化(CF)的治疗。如果患者的基因型是未知,应使用FDA批准的CF突变试验检测G551D突变的存在。(1)
[使用的限制]
(1)对在CFTR基因中F508del突变纯合子CF患者无效。(1, 14)
(2)尚未研究在其它人群CF患者中研究KALYDECO。(1, 14)
[剂量和给药方法]
(1)年龄6岁和以上成年和儿童患者:每12小时与含脂肪食物口服1片150 mg。(2, 12.3)
(2)在有中度和严重肝受损患者中减低剂量。(8.6, 12.3)
(3)当与中度或强CYP3A抑制剂药物共同给药时减低剂量。(7.1, 12.3)
[剂型和规格]
片:150 mg (3)
[禁忌证]
无已知的。
[警告和注意事项]
(1)转氨酶升高(ALT或AST):开始KALYDECO前,治疗头一年期间每3个月,和其后每年应评估转氨酶(ALT和AST)。发生增加转氨酶水平患者应严密监视直至异常解决。在有ALT或AST大于正常上限(ULN)的5倍患者应中断给药。转氨酶升高解决后,考虑恢复KALYDECO给药的获益和风险。(5.1, 6)
(2)与CYP3A诱导剂使用:与强CYP3A诱导剂同时使用(如,利福平[rifampin],圣约翰草[St. John’s Wort]) 实质上减低ivacaftor的暴露可能减弱有效性。所以,不建议共同给药(5.2, 7.2, 12.3)。
[不良反应]
最常见对KALYDECO药物不良反应(在CFTR基因中发生 ≥8%有一种G551D 突变CF患者)是头痛,口咽痛,上呼吸道感染,鼻充血,腹痛,鼻咽炎,腹泻,皮疹,恶心,和头晕。6.1)
[药物相互作用]
CYP3A抑制剂:当与强CYP3A抑制剂共同给药时,减低KALYDECO剂量至150 mg一周2次(如,酮康唑[ketoconazole])。当与中度CYP3A抑制剂共同给药时(如,氟康唑[fluconazole])减低KALYDECO剂量至150 mg每天1次。避免食物含柚子汁或塞维利亚桔子。(7.1, 12.3)
1 适应证和用途
KALYDECO被分类为一种囊性纤维化跨膜电导调节器(CFTR)增效剂。KALYDECO适用于年龄6岁和以上在CFTR基因中有一种G551D突变囊性纤维化(CF)患者的治疗。如患者的基因型未知,应使用FDA批准的CF突变试验检测G551D突变的存在。
[使用限制]
KALYDECO对在CFTR基因中F508del突变纯合子CF患者无效和未曾研究CF其它患者群。
2 剂量和给药方法
2.1 在成年和儿童年龄 6岁和以上中的给药信息
对成年和儿童患者年龄6岁和以上的推荐KALYDECO剂量是150 mg片口服每12小时(300 mg每天总量)与含脂肪食物。适当的含脂肪食物实例包括蛋,黄油,花生黄油,奶酪比萨,等。[见临床药理学(12.3)和患者咨询资料(17.4)].
2.2 对有肝受损患者剂量调整
对有中度肝受损患者KALYDECO的剂量应减低至150 mg每天1次(Child-Pugh类别B)。有严重肝受损患者(Child-Pugh类别C)应在KALYDECO剂量150 mg每天次或频数更低谨慎使用[见特殊人群中使用 (8.6), 临床药理学(12.3),和患者咨询资料(17.3)]。
2.3 对服用CYP3A抑制剂药物患者的剂量调整
当KALYDECO正在与强CYP3A抑制剂(如,酮康唑)共同给药时剂量应减低至150 mg每周2次。当与中度CYP3A抑制剂共同给药时(如,氟康唑)KALYDECO的剂量应减低至150 mg每天1次。应避免含柚子汁或塞维利亚桔子食物[见药物相互作用(7.1), 临床药理学(12.3),和患者咨询资料(17.2)]。
3 剂型和规格
150 mg片。
4 禁忌证
不知道。
5 警告和注意事项
5.1 转氨酶(ALT或AST) 升高
有CF患者接受KALYDECO曾报道转氨酶升高。建议在开始KALYDECO前,治疗头一年期间每3个月,和其后每年评估ALT和AST。发生转氨酶水平增加患者应被严密监视直至异常解决。在有ALT或AST大于正常上限(ULN)的5倍患者中应中断给药。转氨酶升高解决后, 考虑恢复KALYDECO给药的获益和风险[见不良反应(6)].
5.2 与CYP3A诱导剂同时使用
KALYDECO与强CYP3A诱导剂,例如利福平使用,实质上减低ivacaftor的暴露,可能减低KALYDECO治疗有效性。所以,建议KALYDECO不要与强CYP3A诱导剂(如,利福平, 圣约翰草)共同给药[见药物相互作用(7.2)和临床药理学(12.3)]。
6 不良反应
在说明书的其它章节更详细讨论下列不良反应:
(1)转氨酶升高[见警告和注意事项(5.1)]
6.1 临床试验经验
因为临床试验是在广泛不同情况下进行的,临床试验观察到不良反应率不能与另药临床试验发生率直接比较而且可能不反映实践中观察到的发生率。
KALYDECO的总体安全性图形是根据来自安慰剂-对照临床试验来自CFTR基因中有一种G551D突变或是对F508del突变纯合子的353例有CF患者的合并数据。353例患者中,50%患者是女性和97%是高加索人;221例接受KALYDECO和132例接受安慰剂来自16至48周。用KALYDECO治疗患者年龄是6和53岁间。
在这些试验中,由于不良反应提前终止研究药物患者比例对KALYDECO-治疗患者是2%而对安慰剂-治疗患者为5%。由研究中考虑严重的不良反应是否药物-相关,在KALYDECO-治疗患者发生更频,包括腹痛,增加肝酶,和低血糖。.
总而言之,在353例有CF患者最常见不良反应是头痛(17%),上呼吸道感染(16%),鼻充血(16%),恶心(10%),皮疹(10%),鼻炎(6%),头晕(5%),关节痛(5%),和痰中细菌(5%)。
下面是根据两项双盲,安慰剂-对照48-周临床试验总共213例在CFTR基因中有一种G551D突变有CF患者年龄6至53岁和用KALYDECO 150 mg口服治疗或安慰剂每天2次的不良反应的发生率。表1 显示在两项双盲,安慰剂-对照试验中在CFTR基因中有G551D突变有CF患者KALYDECO-治疗发生 ≥8%还比安慰剂-治疗患者发生率较高的不良反应。
在KALYDECO组发生频数4至7%其发生率超过安慰剂组的不良反应包括:
感染和虫染:鼻炎
调查研究:谷草转氨酶升高,痰中细菌,血糖增加,肝酶增加
肌肉骨骼和结缔组织疾病:关节痛,肌肉骨骼胸痛,肌痛
神经系统疾病:窦性头痛
呼吸,胸和纵隔疾病:咽红斑,胸痛,鼻窦充血,喘息
皮肤和皮下组织疾病:痤疮
[实验室异常]
转氨酶升高:在四周期间, 安慰剂-对照临床研究,在KALYDECO-治疗患者中最高转氨酶(ALT或AST)的发生率 >8,>5或>3 × ULN分别是2%,3%和6%而安慰剂-治疗患者分别2%,2%和8%。2例患者(2%)用安慰剂和1例用KALYDECO患者(0.5 %)所有 >8 ×ULN永远终止治疗对升高的转氨酶。2例用KALYDECO治疗患者报道有肝转氨酶升高严重的不良反应与之比较安慰剂无[见警告和注意事项(5.1)]。
7 药物相互作用
其它药物影响ivacaftor的潜能
7.1 CYP3A抑制剂
Ivacaftor是一种敏感的CYP3A底物。与酮康唑,一种强CYP3A抑制剂共同给药,显著地增加ivacaftor暴露[用曲线下面积(AUC)测量]8.5-倍。所以,建议与强CYP3A抑制剂,例如酮康唑, 伊曲康唑[itraconazole], 泊沙康唑[posaconazole],伏立康唑[voriconazole],泰利霉素[telithromycin],和克拉霉素[clarithromycin]共同给药时减低KALYDECO剂量至150 mg一周2次。
与氟康唑,一种CYP3A中度抑制剂共同给药,增加ivacaftor暴露3-倍。所以, 建议同时服用中度CYP3A抑制剂患者,例如氟康唑和红霉素[erythromycin],减低KALYDECO剂量至150 mg每天1次。
KALYDECO与柚子汁,含一种或以上成分中度抑制CYP3A的共同给药可能增加ivacaftor的暴露。所以,用KALYDECO治疗时应避免含柚子汁或塞维利亚桔子食物[见临床药理学(12.3)]。
7.2 CYP3A的诱导剂
与利福平,一种强CYP3A诱导剂共同给药显著减低ivacaftor暴露(AUC)约9-倍。所以,建议不与强CYP3A诱导剂,例如利福平、利福布汀[rifabutin]、苯巴比妥[Phenobarbital]、 卡马西平[carbamazepine]、苯妥英[phenytoin]、和圣约翰草共同给药[见警告和注意事项(5.2)和临床药理学(12.3)].
Ivacaftor影响其它药物的潜能
7.3 CYP3A和/或P-gp底物
Ivacaftor及其M1代谢物有抑制CYP3A和P-gp的潜能。与咪达唑仑[midazolam],一个敏感的CYP3A底物共同给药,增加咪达唑仑暴露1.5-倍,与CYP3A被ivacaftor的弱抑制作用。KALYDECO的给药可能增加CYP3A/或P-gp底物药物的全身暴露,可能增加或延长其治疗效应和不良事件。所以,建议当KALYDECO与CYP3A和/或P-gp底物,例如地高辛[digoxin],环孢霉素[cyclosporine],和他克莫司[tacrolimus]共同给药谨慎[见临床药理学(12.3)]。
8 特殊人群中使用
8.1 妊娠
致畸效应: 妊娠类别B。在妊娠妇女中没有KALYDECO的适当和良好-对照研究。在大鼠中在约为最大推荐人用(MRHD)(根据vacaftor及其代谢物AUC之和在母体剂量200 mg/kg/day)的6倍,Ivacaftor无致畸胎性。在兔中在MRHD(基于母体剂量100 mg/kg/day,分别对ivacaftor AUC)的约12倍,Ivacafto无致畸胎性。妊娠大鼠和兔中观察到ivacafto胎盘转运。因为动物生殖研究并非总能预测人反应,妊娠期间只有明确需求才应使用KALYDECO。
8.3 哺乳母亲
Ivacaftor排泄至哺乳雌性大鼠乳汁中。Ivacaftor很可能排泄至人乳汁。没有人研究ivacaftor对哺乳婴儿的影响。当给予哺乳妇女KALYDECO应谨慎。
8.4 儿童使用
在6至7岁CFTR基因中有G551D突变CF患者的2项安慰剂-对照临床试验曾显示KALYDECO的安全性和疗效。试验1评价161例12岁或以上有CF患者和试验2评价52例6至11岁有CF患者[见临床研究(14.1)]。
尚未确定KALYDECO在年龄6岁更小CF患者的安全性和疗效。
8.5 老年人使用
CF很大程度是一种儿童和年轻成人的疾病。KALYDECO的临床试验没有包括足够数65岁和以上患者以确定他们是否与较年轻患者反应不同。
8.6 肝受损
对轻度肝受损患者(Child-Pugh类别A)无需调整剂量。中度肝受损患者(Child-Pugh类别B)建议减低剂量至150 mg每天1次。未曾在严重肝受损患者进行研究(Child-Pugh类别C)但预计暴露较高于中度肝受损患者。所以,严重肝受损患者中权衡治疗风险和获益后慎用剂量150 mg每天1次或频数更低[见药代动力学(12.3)]。
8.7 肾受损
未曾在轻度,中度,或严重肾受损或末期肾病患者中研究KALYDECO。对轻至中度肾受损患者无需调整剂量;然而,建议严重肾受损患者(肌酐清除率小于或等于30 mL/min)或肾病末期患者中慎用KALYDECO。
8.8 对在CFTR基因中F508del突变纯合子CF患者
来自CFTR基因中F508del突变纯合子CF患者中一项双盲,安慰剂-对照试验的疗效结果显示历时16周KALYDECO治疗与安慰剂比较,一秒钟用力呼气量(FEV1)无统计上显著差别[见临床研究(14.2)]。所以,对CFTR基因中F508del突变纯合子患者中不应使用KALYDECO。
10 药物过量
没有用KALYDECO过量的报告。
在一项临床研究使用最高单次剂量是800 mg在一种溶液剂无任何治疗-相关不良事件。
最高重复剂量是450 mg(片剂)每12小时1次共4.5天(9剂)在一项试验在健康受试者中评价KALYDECO对ECGs影响。与安慰剂比较报道的不良事件包括头晕和腹泻。
对KALYDECO过量无可供利用特异性抗毒药。用KALYDECO过量的治疗由一般支持措施组成包括监视生命体征和患者临床状态的观察。
11 一般描述
KALYDECO 片中活性成分是ivacaftor有下面化学名:N-(2,4-di-tert-butyl-5-hydroxyphenyl)-1,4-dihydro-4oxoquinoline-3-carboxamide. 其分子式是C24H28N2O3和分子量392.49。结构式如下:
Ivacaftor是一种白色淡白色粉实际上不溶于水(<0.05 μg/mL)。可得到KALYDECO为淡蓝色胶囊-形,薄膜衣片为口服给药含150 mg ivacaftor。每片含无活性成分胶体二氧化硅,交联羧甲基钠,羟丙基甲基纤维素醋酸琥珀,乳糖一水合物,硬脂酸镁,微晶纤维素,和十二烷基硫酸钠。片膜衣含巴西棕榈蜡,FD&C蓝#2,PEG 3350,聚乙烯醇,滑石粉,和二氧化钛。印墨水含氢氧化铵,氧化铁黑,丙二醇,和虫漆。
12 临床药理学
12.1 作用机制
Ivacaftor是CFTR蛋白的一种增效剂。CFTR蛋白是在许多器官内上皮细胞表面存在的一种氯离子通道。Ivacaftor有利于增加氯离子运输通过增强G551D-CFTR蛋白的通道开放概率(或门控选通[gating])。
在体外,ivacaftor增加CFTR-介导的穿越上皮电流[transepithelial current, IT)在表达G551D-CFTR蛋白啮齿类细胞中加入一种环腺苷酸(cAMP)激动剂EC50为100 ± 47 nM后;然而,在缺乏cAMP激动剂时ivacaftor不增加IT。在表达G551D-CFTR蛋白的人支气管上皮细胞中加入一种有EC50为236 nM的cAMP激动剂后Ivacaftor也增加IT。在单通道膜片钳实验中用来自啮齿动物表达G551D-CFTR蛋白膜片钳Ivacaftor增加G551D-CFTR蛋白开放概率与加入PKA和ATP相比为10-倍。
12.2 药效动力学
汗氯化物评价
在CFTR基因中有G551D突变患者临床试验中,KALYDECO导致汗中氯化物浓度统计上显著减低。在两项随机化,双盲,安慰剂-对照临床试验中(一项在12岁和以上患者和另一项患者6-11岁),汗中氯化物从基线至24周中位变化分别是-48 mmol/L(95% CI -51,-45)和-54 mmol/L(95% CI -62,-47)。这些变化持续至48周。汗中氯化物水平减低和肺功能(FEV1)中改善间无直接相关。
ECG评价
在72例健康受试者一项随机化,安慰剂-和阳性-对照(莫西沙星[moxifloxacin]400 mg)四阶段交叉至QT研究中评价多剂量ivacaftor 150 mg和450 mg每天2次对QTc间期的影响。在一项研究显示检测小效应能力,根据Fridericia的校正法(QTcF)基线-校正QTc对最大安慰剂校正的,单侧95%可信区间的上限是低于监管关注阈值10 ms。
12.3 药代动力学
健康成年志愿者和CF患者间 ivacaftor的药代动力学相似。
健康志愿者在饱腹状态口服给予单次150 mg剂量后,峰血浆浓度时间(Tmax)发生在约4小时,和均数(±SD) AUC和Cmax分别为10600(5260) ng*hr/mL和768(233) ng/mL。
每2小时给药,在第3至5天达到ivacaftor的稳态血浆浓度,与积蓄比值范围2.2至2.9。
吸收
当与含脂肪食物给予ivacaftor暴露增加约2-至4-倍。所以, KALYDECO应与含脂肪食物给药。含脂肪食物实例包括蛋,黄油,花生黄油,和奶酪比萨。在饱腹状态tmax中位数(范围)是约4.0(3.0; 6.0)小时。
分布
约99%的Ivacaftor结合至血浆蛋白,主要至α1-酸性糖蛋白和白蛋白。Ivacaftor不结合至人红细胞。
健康受试者和CF患者在饱腹状态单剂量275 mg KALYDECO后ivacaftor的平均表观分布容积(Vz/F)相似。健康志愿者在饱腹状态口服给予150 mg每12小时共7天后,平均(±SD)表观分布容积为353(122) L。
代谢
Ivacaftor在人中被广泛地代谢。在体外和临床研究表明ivacaftor主要是被CYP3A代谢。M1和M6是ivacaftor在人中的两个主要代谢物。M1的效力约ivacaftor的1/6和被认为有药理学活性。M6低于ivacaftor效力的1/50而不认为有药理学活性。
消除
口服给药后,大部分ivacaftor(87.8%)在粪中代谢转化后被消除。主要代谢物M1和M6约占总剂量的65%有22%以M1被消除和43%为M6。以未变化母药ivacaftor在尿中排泄量可忽略不计。单剂量后表观末端半衰期是约12小时。健康受试者和CF患者中ivacaftor的平均表观清除率(CL/F)相似。健康受试者150 mg剂量CL/F(SD)为17.3(8.4)L/hr。
特殊人群
肝受损
中度受损肝功能(Child-Pugh类型B,评分7至9)患者与人口统计指标匹配的健康受试者比较有相似的ivacaftor Cmax,但ivacaftor AUC0-∞增加约2-倍。所以,建议对有中度肝受损患者减低KALYDECO剂量150 mg每天1次。未曾研究轻度肝受损(Child-Pugh类别A)对ivacaftor的药代动力学的影响,但ivacaftor的AUC0-∞增加预计小于2-倍。所以,对轻度肝受损患者无需调整剂量。未曾研究严重肝受损(Child-Pugh类别C,评分10-15)对ivacaftor药代动力学的影响。不知道在这些患者中暴露增加的大小但预计大大高于中度肝受损患者观察值。当获益预计胜过风险,严重肝受损患者中KALYDECO应谨慎每天1次或更不频繁使用剂量150 mg给药。
肾受损
尚未在轻度、中度或严重肾受损患者(肌酐清除率小于或等于30 mL/min)或肾病末期患者中研究KALYDECO。对轻度和中度肾受损患者无需调整剂量因为在尿中ivacaftor及其代谢物消除可忽略不计(在一项人PK研究尿中仅回收6.6%总放射性);然而,当严重肾受损或肾病终末期患者给予KALYDECO建议谨慎。
性别
用来自KALYDECO临床研究数据群体药代动力学评价性别对KALYDECO药代动力学的影响。无需根据性别调整剂量。
药物相互作用
用KALYDECO和很可能共同给药或药代动力学相互作用研究中常被用作探针的药物的其它药物进行药物相互作用研究 [见药物相互作用(7)].
下面展示根据临床研究或潜在药物相互作用用KALYDECO的给药建议:
Ivacaftor影响其它药物的潜能
在体外研究显示ivacaftor是一种CYP3A的弱抑制剂和抑制P-gp的潜能。在治疗浓度时,和也可能抑制CYP2C8和CYP2C9同工酶。代谢物M1,但不是M6,也有抑制抑制CYP3A和P-gp潜能。Ivacaftor,M1,和M6不是CYP同工酶的诱导剂。在图1显示给予KALYDECO后对共同给药药物的给药建议:
注释: 有底物得到的数据但无KALYDECO共同给药被用作参比品。*NE:炔诺酮[Norethindrone];**EE:炔雌醇。垂直线分别分别是在0.8,1.0和1.25。
其它药物影响Ivacaftor的潜能
在体外研究显示ivacaftor和代谢物M1是CYP3A酶的底物(即,CYP3A4和CYP3A5)。在图2中显示KALYDECO与CYP3A抑制剂或诱导剂共同给药的给药建议:
图2:其它药物对KALYDECO的影响
注释:对KALYDECO无诱导剂或抑制剂用作为参比品共同给药得到数据。垂直线分别在0.8,1.0和1.25。
13 非临床毒理学
13.1 癌发生,突变发生,和生育能力受损
在小鼠和大鼠中进行3年研究评估KALYDECO的致癌性潜能。在ivacaftor口服剂量至200 mg/kg/day和50 mg/kg/day,分别(根据ivacaftor及其代谢物AUC之和约分别等于MRHD的3至5倍时),小鼠和大鼠中未观察到致瘤性证据。
Ivacaftor对以下分析中的遗传毒性是阴性:为细菌基因突变的Ames试验, 在体外 在中国仓鼠卵巢细胞染色体畸变分析,和体内小鼠微核试验。
Ivacaftor损伤生育能力和生殖性能指标,在雄性和雌性大鼠中在200 mg/kg/day时(根据ivacaftor及其代谢物AUC之和分别约为MRHD的5和6倍)。观察到在雌性中在200 mg/kg/day增加长期动情周期。在大鼠中当母兽给药前和早期妊娠期间200 mg/kg/day(根据ivacaftor及其代谢物AUC之和的MRHD约6倍)Ivacaftor还增加有全部非生存胚胎雌性数和减少黄体数,植入数,和活存胚胎数。在雄性和雌性大鼠中在200 mg/kg/day时,这些生育能力和生殖行为受损是归因于严重毒性。在≤100 mg/kg/day(根据ivacaftor及其代谢物AUC之和MRHD的约3倍)未观察到对雄性或雌性生育能力和生殖性能指标的影响。
14 临床研究
14.1在CFTR基因有一个G551D突变的CF患者中试验
剂量范围:
对剂量范围临床方案主要包括一项双盲,安慰剂-对照,交叉试验在39例成年(平均年龄31岁)高加索人有CF患者有预测的FEV1 ≥ 40%。20例患者在基线时有中位预测的FEV1 56%(范围:42%至109%)接受KALYDECO 25,75,150 mg或安慰剂每12小时共14天和19例患者在基线时有中位预测的FEV1 69%(范围:40%至122%)接受KALYDECO 150,250 mg或安慰剂每12小时共28天。150 mg每12小时剂量的选择主要根据肺功能轻微的[nominal]改善(给药前FEV1)和药效动力学参数的变化(汗氯化物和鼻潜力差别)。每天2次给药方案主要是根据表观末端血浆半衰期约12小时。对6至11岁儿童是根据观察到达到与成年患者观察到可比的药代动力学。
疗效:
在CFTR基因有一个G551D突变的CF患者中在两项随机化,双盲,安慰剂-对照临床试验在213例临床上稳定有CF患者(109例接受KALYDECO 150 mg每天2次)中评价KALYDECO的疗效。来自这些试验所有合格患者被滚动进入一项开放延伸研究。
试验1评价161例有CF患者年龄12岁或以上(平均年龄26岁)有基线预测的FEV1 40-90%间[平均预测的FEV1 64%(范围:32%至98%)]。试验2评价52例患者为6至11岁(平均年龄9岁)有基线预测的FEV1 40-105%间[平均预测的FEV1 84%(范围:44%至134%)]。在筛选时排除从痰中分离出有持久洋葱伯克霍尔德菌([Burkholderia cenocepacia], dolosa,或分支杆菌属[Mycobacterium] abcessus患者和那些有异常肝功能被定义为3或以上肝功能检验 (ALT,AST,AP,GGT,总胆红素) ≥正常上限3倍患者。
在两项试验中患者被1:1随机化至接受或150 mg KALYDECO或安慰剂每12小时与含脂肪食物共48周除了被处方CF治疗(如,妥布霉素[tobramycin],阿法链道酶[dornase alfa])。不允许使用吸入高渗盐水。
在两项研究中主要疗效终点是肺功能改善当用给药前预测的FEV1直至治疗第24周从基线平均绝对变化百分率。
在两项研究中,用KALYDECO治疗导致FEV1显著改善。在试验1中对从基线至24周预测的FEV1平均绝对变化百分率KALYDECO和安慰剂间治疗差别是10.6百分点(P < 0.0001)和在试验2中12.5百分点(P < 0.0001)(图3)。这些变化持续至48周。观察到预测的FEV1百分率改善不管年龄,疾病严重程度,性别,和地理区域。
图3: 预测的FEV1百分率从基线平均绝对变化*
其它疗效变量包括汗中氯化物从基线至第24周绝对变化[在临床药理学讨论(12.2)],直至第48周首次肺加重的时间(仅试验1),从基线至第48周体重绝对变化,和囊性纤维化症状改善 包括相关呼吸症状例如咳嗽,痰产生,和呼吸困难。对本研究的目的,肺加重被定义为抗生素治疗中变化(IV,吸入,或口服)当12项预先指定sino-肺体征/症状有4或更多的结果。用KALYDECO治疗患者显示肺加重的风险,CF症状(仅在试验1),和体重增重统计上显著改善(表2)。在患者<20岁中体重数据,当对年龄和性别用体重指数归一化表示时,与重量从基线绝对变化一致。
14.2对在CFTR基因中F508del突变纯合子患者试验
试验3是在140例年龄12岁和以上是在CFTR基因中对F508del突变纯合子和有预测的FEV1 ≥40%有CF患者中一项16-周随机化,双盲,安慰剂-对照,平行-组试验。患者被4:1随机化接受KALYDECO 150 mg (n=112) 每12小时或安慰剂(n=28)除了他们处方的CF治疗。被纳入患者平均年龄为23岁和平均基线预测的FEV1是79%(范围40%至129%)。因为在试验1和2中,排除在筛选时从痰分离持久洋葱伯克霍尔德菌([Burkholderia cenocepacia],dolosa,或分支杆菌属[Mycobacterium] abcessus和那些有异常肝功能被定义为3或更多肝功能检验(ALT,AST,AP,GGT,总胆红素) ≥正常上限3倍的患者。不允许使用吸入高渗盐水。
当用从基线至16周预测的FEV1百分率平均绝对变化测定主要终点肺功能改善。在CFTR基因中对F508del突变纯合子CF患者中用KALYDECO治疗相对于安慰剂导致FEV1无改善[从基线至16周预测的FEV1百分率平均绝对变化对患者KALYDECO和安慰剂-治疗组是分别1.5%和-0.2%(p = 0.15)]。用KALYDECO治疗患者与安慰剂比较对第二位终点间差别无意义(CF症状变化,体重变化,或汗中氯化物浓度变化)。
16 如何供应/贮存和处置
KALYDECOTM (ivacaftor)是以淡绿色,膜包衣,胶囊形含150 mg ivacaftor片供应。每片一侧印有字符“V 150”和另一侧平坦,和被包装如下:
56-计数盒(含4个独立泡卡每卡14片) NDC 51167-200-01和60-计数瓶NDC 51167-200-02
贮存在20-25ºC (68-77ºF);外出时允许15-30ºC (59-86ºF) [见美国药典控制室温]。
17 患者咨询资料
17.1 转氨酶(ALT或AST)升高和监视
告知患者用KALYDECO治疗患者中曾发生肝检验升高。开始用KALYDECO前和治疗头一年时每3个月和其后每年进行肝功能检验[见警告和注意事项(5.1)]。
17.2与CYP3A诱导剂和抑制剂药物相互作用
要求患者告诉你他们所用全部药物包括任何草药补品或维生素。建议KALYDECO不要与强CYP3A诱导剂(如,利福平, 圣约翰草)共同给药,因为它们减低KALYDECO的治疗有效性。当与强CYP3A抑制剂,例如酮康唑共同给药时建议减低KALYDECO剂量至150 mg一周2次。当与中度CYP3A抑制剂,例如氟康唑共同给药时建议减低剂量至150 mg 每天1次。应避免含柚子汁或Seville橘子食物[见药物相互作用(7.1, 7.2)和临床药理学(12.3)]。
17.3 有肝受损患者中使用
询问和/或评估患者是否有肝受损。中度受损肝功能患者中减低KALYDECO剂量(Child-Pugh类别B,评分7 至9)至每天1次150 mg。未曾在严重肝受损患者中研究KALYDECO (Child-Pugh类别C,评分10-15);然而,预计暴露大大高于中度肝受损患者观察值。当预计获益大于风险,严重肝受损患者应慎用KALYDECO剂量每天1次150 mg或频数更低。建议轻度肝受损患者无需调整剂量(Child-Pugh类别A,评分5-6)[见临床药理学(12.3)].
17.4 与含脂肪食物服用
告知患者当与脂肪食物服用KALYDECO机体吸收最佳。典型CF膳食将满足此要求。实例包括蛋、黄油、花生黄油、奶酪比萨等。
KALYDECO®
(ivacaftor) Tablets and Oral Granules
The active ingredient in KALYDECO tablets and oral granules is ivacaftor, a cystic fibrosistransmembrane conductance regulator potentiator, which has the following chemical name: N-(2,4-di-tert-butyl-5-hydroxyphenyl)-1,4-dihydro-4-oxoquinoline-3-carboxamide. Its molecular formula is C24H28N2O3 and its molecular weight is 392.49. Ivacaftor has the following structural formula:
|
Ivacaftor is a white to off-white powder that is practically insoluble in water (<0.05 microgram/mL).
KALYDECO is available as a light blue, capsule-shaped, film-coated tablet for oral administration containing 150 mg of ivacaftor. Each KALYDECO tablet contains 150 mg of ivacaftor and the following inactive ingredients: colloidal silicon dioxide, croscarmellose sodium, hypromellose acetate succinate, lactose monohydrate, magnesium stearate, microcrystalline cellulose, and sodium lauryl sulfate. The tablet film coat contains carnauba wax, FD&C Blue #2, PEG 3350, polyvinyl alcohol, talc, and titanium dioxide. The printing ink contains ammonium hydroxide, iron oxide black, propylene glycol, and shellac.
KALYDECO is also available as white to off-white granules for oral administration (sweetened but unflavored) and enclosed in a unit-dose packet containing 50 mg of ivacaftor or 75 mg of ivacaftor. Each unit-dose packet of KALYDECO oral granules contains 50 mg of ivacaftor or 75 mg of ivacaftor and the following inactive ingredients: colloidal silicon dioxide, croscarmellose sodium, hypromellose acetate succinate, lactose monohydrate, magnesium stearate, mannitol, sucralose, and sodium lauryl sulfate.
Indications
INDICATIONSKALYDECO is a cystic fibrosis transmembrane conductance regulator (CFTR) potentiator indicated for the treatment of cystic fibrosis (CF) in patients age 2 years and older who have one mutation in the CFTR gene that is responsive to ivacaftor potentiation based on clinical and/or in vitro assay data [see CLINICAL PHARMACOLOGY and Clinical Studies].
If the patient's genotype is unknown, an FDA-cleared CF mutation test should be used to detect the presence of a CFTR mutation followed by verification with bi-directional sequencing when recommended by the mutation test instructions for use.
Dosage
DOSAGE AND ADMINISTRATIONGeneral Dosing InformationKALYDECO should be taken with fat-containing food. Examples include eggs, butter, peanut butter, cheese pizza, whole-milk dairy products (such as whole milk, cheese, and yogurt), etc. [seeCLINICAL PHARMACOLOGY and Patient Counseling Information].
Dosing Information In Adults And Children Ages 6 Years And OlderThe recommended dose of KALYDECO for both adults and pediatric patients ages 6 years and older is one 150 mg tablet taken orally every 12 hours (300 mg total daily dose) with fat-containing food [see General Dosing Information].
Dosing Information In Pediatric Patients Ages 2 To Less Than 6 YearsThe recommended dose of KALYDECO (oral granules) for patients ages 2 to less than 6 years is weight-based according to Table 1.
Table 1: Dosage of KALYDECO Oral Granules by Body Weight in Pediatric Patients Ages 2 to less than 6 Years
Body Weight (kg) |
KALYDECO Dose |
Total Daily Dose |
Less than 14 kg |
One 50 mg packet every 12 hours |
100 mg/day |
14 kg or greater |
One 75 mg packet every 12 hours |
150 mg/day |
The entire contents of each packet of oral granules should be mixed with one teaspoon (5 mL) of age-appropriate soft food or liquid and completely consumed. Food or liquid should be at or below room temperature. Once mixed, the product has been shown to be stable for one hour, and therefore should be consumed during this period. Some examples of soft foods or liquids may include puréed fruits or vegetables, yogurt, applesauce, water, milk, or juice. Each dose should be administered just before or just after fat-containing food [see General Dosing Information].
Dosing Information In Pediatric Patients Less Than 2 YearsA safe and efficacious dose of KALYDECO for pediatric patients less than 2 years of age has not been established. The use of KALYDECO (oral granules) in children under the age of 2 years is not recommended.
Dosage Adjustment For Patients With Hepatic ImpairmentThe dose of KALYDECO should be reduced to one tablet or one packet of oral granules once daily for patients with moderate hepatic impairment (Child-Pugh Class B). KALYDECO should be used with caution in patients with severe hepatic impairment (Child-Pugh Class C) at a dose of one tablet or one packet of oral granules once daily or less frequently [see Use In Specific Populations, CLINICAL PHARMACOLOGY, and PATIENT INFORMATION].
Dosage Adjustment For Patients Taking Drugs That Are CYP3A InhibitorsWhen KALYDECO is being co-administered with strong CYP3A inhibitors (e.g., ketoconazole), the dose should be reduced to one tablet or one packet of oral granules twice a week. The dose of KALYDECO should be reduced to one tablet or one packet of granules once daily when co-administered with moderate CYP3A inhibitors (e.g., fluconazole). Food containing grapefruit or Seville oranges should be avoided [see DRUG INTERACTIONS, CLINICAL PHARMACOLOGY, and PATIENT INFORMATION].
HOW SUPPLIEDDosage Forms And StrengthsTablets: 150 mg; supplied as light blue, film-coated, capsule-shaped tablets containing 150 mg of ivacaftor. Each tablet is printed with the characters “V 150” on one side and plain on the other.
Oral granules: Unit-dose packets containing 50 mg or 75 mg per packet; supplied as small, white to off-white granules and enclosed in unit-dose packets.
Storage And HandlingKALYDECO (ivacaftor) tablets are supplied as light blue, film-coated, capsule-shaped tablets containing 150 mg of ivacaftor. Each tablet is printed with the characters “V 150” on one side and plain on the other, and is packaged as follows:
56-count carton (contains 4 individual blister cards of 14 tablets per card) NDC 51167-200-01
60-count bottle NDC 51167-200-02
KALYDECO (ivacaftor) oral granules are supplied as small, white to off-white granules and enclosed in unit-dose packets as follows:
56-count carton (contains 56 unit-dose packets of 50 mg ivacaftor per packet) NDC 51167-300-01
56-count carton (contains 56 unit-dose packets of 75 mg ivacaftor per packet) NDC 51167-400-01
Store at 20-25°C (68-77°F); excursions permitted to 15-30°C (59-86°F) [see USP Controlled Room Temperature].
Manufactured for Vertex Pharmaceuticals Incorporated Boston, MA 02210. Revised : Aug 2017
Side Effects
SIDE EFFECTSThe following adverse reaction is discussed in greater detail in other sections of the label:
· Transaminase Elevations [see WARNINGS AND PRECAUTIONS]
Clinical Trials ExperienceBecause clinical trials are conducted under widely varying conditions, adverse reaction rates observed in the clinical trials of a drug cannot be directly compared to rates in the clinical trials of another drug and may not reflect the rates observed in clinical practice.
The overall safety profile of KALYDECO is based on pooled data from three placebo-controlled clinical trials conducted in 353 patients 6 years of age and older with CF who had a G551D mutation in the CFTR gene (Trials 1 and 2) or were homozygous for the F508del mutation (Trial 3). In addition, the following clinical trials have also been conducted [see CLINICAL PHARMACOLOGY and Clinical Studies]:
· An 8-week, crossover design trial (Trial 4) involving 39 patients between the ages of 6 and 57 years with a G1244E, G1349D, G178R, G551S, G970R, S1251N, S1255P, S549N, or S549R mutation in the CFTR gene.
· A 24-week, placebo-controlled trial (Trial 5) involving 69 patients between the ages of 6 and 68 years with an R117H mutation in the CFTR gene.
· A 24-week, open-label trial (Trial 6) in 34 patients 2 to less than 6 years of age. Patients eligible for Trial 6 were those with the G551D, G1244E, G1349D, G178R, G551S, G970R, S1251N, S1255P, S549N, or S549R mutation in the CFTR gene. Of 34 patients enrolled, 32 had the G551D mutation and 2 had the S549N mutation.
· An 8-week, crossover design trial (Trial 7) involving patients between the ages of 12 and 72 years who were heterozygous for the F508del mutation and a second CFTR mutation predicted to be responsive to ivacaftor. A total of 156 patients were randomized to and received KALYDECO.
Of the 353 patients included in the pooled analyses of patients with CF who had either a G551D mutation or were homozygous for the F508del mutation in the CFTR gene, 50% of patients were female and 97% were Caucasian; 221 received KALYDECO, and 132 received placebo from 16 to 48 weeks.
The proportion of patients who prematurely discontinued study drug due to adverse reactions was 2% for KALYDECO-treated patients and 5% for placebo-treated patients. Serious adverse reactions, whether considered drug-related or not by the investigators, that occurred more frequently in KALYDECO-treated patients included abdominal pain, increased hepatic enzymes, and hypoglycemia.
The most common adverse reactions in the 221 patients treated with KALYDECO were headache (17%), upper respiratory tract infection (16%), nasal congestion (16%), nausea (10%), rash (10%), rhinitis (6%), dizziness (5%), arthralgia (5%), and bacteria in sputum (5%).
The incidence of adverse reactions below is based upon two double-blind, placebo-controlled, 48-week clinical trials (Trials 1 and 2) in a total of 213 patients with CF ages 6 to 53 who have a G551D mutation in the CFTR gene and who were treated with KALYDECO 150 mg orally or placebo twice daily. Table 2 shows adverse reactions occurring in ≥8% of KALYDECO-treated patients with CF who have a G551D mutation in the CFTR gene that also occurred at a higher rate than in the placebo-treated patients in the two double-blind, placebo-controlled trials.
Table 2: Incidence of Adverse Drug Reactions in ≥8% of KALYDECO-Treated Patients with a G551D Mutation in the CFTR Gene and Greater than Placebo in 2 Placebo-Controlled Phase 3 Clinical Trials of 48 Weeks Duration
Adverse Reaction (Preferred Term) |
Incidence: Pooled 48-Week Trials |
|
KALYDECO |
Placebo |
|
Headache |
26 (24) |
17 (16) |
Oropharyngeal pain |
24 (22) |
19 (18) |
Upper respiratory tract infection |
24 (22) |
14 (14) |
Nasal congestion |
22 (20) |
16 (15) |
Abdominal pain |
17 (16) |
13(13) |
Nasopharyngitis |
16 (15) |
12 (12) |
Diarrhea |
14(13) |
10 (10) |
Rash |
14(13) |
7 (7) |
Nausea |
13 (12) |
11 (11) |
Dizziness |
10 (9) |
1 (1) |
Adverse reactions in the 48-week clinical trials that occurred in the KALYDECO group at a frequency of 4 to 7% where rates exceeded that in the placebo group include:
Infections and infestations: rhinitis
Investigations: aspartate aminotransferase increased, bacteria in sputum, blood glucose increased, hepatic enzyme increased
Musculoskeletal and connective tissue disorders: arthralgia, musculoskeletal chest pain, myalgia
Nervous system disorders: sinus headache
Respiratory, thoracic and mediastinal disorders: pharyngeal erythema, pleuritic pain, sinuscongestion, wheezing
Skin and subcutaneous tissue disorders: acne
The safety profile for the CF patients enrolled in the other clinical trials (Trials 3-7) was similar to that observed in the 48-week, placebo-controlled trials (Trials 1 and 2).
Laboratory AbnormalitiesTransaminase Elevations
In Trials 1, 2, and 3 the incidence of maximum transaminase (ALT or AST) >8, >5, or >3 x ULN was 2%, 2%, and 6% in KALYDECO-treated patients and 2%, 2%, and 8% in placebo-treated patients, respectively. Two patients (2%) on placebo and 1 patient (0.5%) on KALYDECO permanently discontinued treatment for elevated transaminases, all >8 x ULN. Two patients treated with KALYDECO were reported to have serious adverse reactions of elevated liver transaminases compared to none on placebo. Transaminase elevations were more common in patients with a history of transaminase elevations [see WARNINGS AND PRECAUTIONS].
During the 24-week, open-label, clinical trial in 34 patients ages 2 to less than 6 years (Trial 6), where patients received either 50 mg (less than 14 kg) or 75 mg (14 kg or greater) ivacaftor granules twice daily, the incidence of patients experiencing transaminase elevations (ALT or AST) >3 x ULN was 14.7% (5/34). All 5 patients had maximum ALT or AST levels >8 x ULN, which returned to baseline levels following interruption of KALYDECO dosing. Transaminase elevations were more common in patients who had abnormal transaminases at baseline. KALYDECO was permanently discontinued in one patient [see WARNINGS AND PRECAUTIONS].
Drug Interactions
DRUG INTERACTIONSPotential for other drugs to affect ivacaftor
Inhibitors Of CYP3AIvacaftor is a sensitive CYP3A substrate. Co-administration with ketoconazole, a strong CYP3A inhibitor, significantly increased ivacaftor exposure [measured as area under the curve (AUC)] by 8.5-fold. Based on simulations of these results, a reduction of the KALYDECO dose is recommended when co-administered with strong CYP3A inhibitors, such as ketoconazole, itraconazole, posaconazole, voriconazole, telithromycin, and clarithromycin, as follows: in patients 6 years and older reduce dose to one 150 mg tablet twice a week; in patients 2 to less than 6 years with body weight less than 14 kg, reduce dose to one 50 mg packet of granules twice a week; and in patients 2 to less than 6 years with body weight 14 kg or greater, reduce dose to one 75 mg packet of granules twice a week.
Co-administration with fluconazole, a moderate inhibitor of CYP3A, increased ivacaftor exposure by 3-fold. Therefore, a reduction of the KALYDECO dose is recommended for patients taking concomitant moderate CYP3A inhibitors, such as fluconazole and erythromycin, as follows: in patients 6 years and older reduce dose to one 150 mg tablet once daily; in patients 2 to less than 6 years with body weight less than 14 kg, reduce dose to one 50 mg packet of granules once daily; and in patients 2 to less than 6 years with body weight 14 kg or greater, reduce dose to one 75 mg packet of granules once daily.
Co-administration of KALYDECO with grapefruit juice, which contains one or more components that moderately inhibit CYP3A, may increase exposure of ivacaftor. Therefore, food containing grapefruit or Seville oranges should be avoided during treatment with KALYDECO [see CLINICAL PHARMACOLOGY].
Inducers Of CYP3ACo-administration with rifampin, a strong CYP3A inducer, significantly decreased ivacaftor exposure (AUC) by approximately 9-fold. Therefore, co-administration with strong CYP3A inducers, such as rifampin, rifabutin, phenobarbital, carbamazepine, phenytoin, and St. John's wort is not recommended [see WARNINGS AND PRECAUTIONS and CLINICAL PHARMACOLOGY].
CiprofloxacinCo-administration of KALYDECO with ciprofloxacin had no effect on the exposure of ivacaftor. Therefore, no dose adjustment is necessary during concomitant administration of KALYDECO with ciprofloxacin [see CLINICAL PHARMACOLOGY].
Potential for ivacaftor to affect other drugs
CYP3A And/Or P-gp SubstratesIvacaftor and its M1 metabolite have the potential to inhibit CYP3A and P-gp. Co-administration with oral midazolam, a sensitive CYP3A substrate, increased midazolam exposure 1.5-fold, consistent with weak inhibition of CYP3A by ivacaftor. Co-administration with digoxin, a sensitive P-gp substrate, increased digoxin exposure by 1.3-fold, consistent with weak inhibition of P-gp by ivacaftor. Administration of KALYDECO may increase systemic exposure of drugs that are substrates of CYP3A and/or P-gp, which may increase or prolong their therapeutic effect and adverse events. Therefore, caution and appropriate monitoring are recommended when co-administering KALYDECO with sensitive CYP3A and/or P-gp substrates, such as digoxin, cyclosporine, and tacrolimus [seeCLINICAL PHARMACOLOGY].
Warnings & Precautions
WARNINGSIncluded as part of the PRECAUTIONS section.
PRECAUTIONSTransaminase (ALT Or AST) ElevationsElevated transaminases have been reported in patients with CF receiving KALYDECO. It is recommended that ALT and AST be assessed prior to initiating KALYDECO, every 3 months during the first year of treatment, and annually thereafter. For patients with a history of transaminase elevations, more frequent monitoring of liver function tests should be considered. Patients who develop increased transaminase levels should be closely monitored until the abnormalities resolve. Dosing should be interrupted in patients with ALT or AST of greater than 5 times the upper limit of normal (ULN). Following resolution of transaminase elevations, consider the benefits and risks of resuming KALYDECO dosing [see ADVERSE REACTIONS and Use In Specific Populations].
Concomitant Use With CYP3A InducersUse of KALYDECO with strong CYP3A inducers, such as rifampin, substantially decreases the exposure of ivacaftor, which may reduce the therapeutic effectiveness of KALYDECO. Therefore, co-administration of KALYDECO with strong CYP3A inducers (e.g., rifampin, St. John's wort) is not recommended [see DRUG INTERACTIONS and CLINICAL PHARMACOLOGY].
CataractsCases of non-congenital lens opacities/cataracts have been reported in pediatric patients treated with KALYDECO. Although other risk factors were present in some cases (such as corticosteroid use and/or exposure to radiation), a possible risk attributable to KALYDECO cannot be excluded. Baseline and follow-up ophthalmological examinations are recommended in pediatric patients initiating KALYDECO treatment.
Patient Counseling InformationAdvise the patient to read the FDA-approved patient labeling (PATIENT INFORMATION).
Transaminase (ALT or AST) Elevations And MonitoringInform patients that elevation in liver tests have occurred in patients treated with KALYDECO. Liver function tests will be performed prior to initiating KALYDECO, every 3 months during the first year of treatment and annually thereafter. More frequent monitoring of liver function tests should be considered in patients with a history of transaminase elevations [see WARNINGS AND PRECAUTIONS].
Drug Interactions With CYP3A Inducers And InhibitorsAsk patients to tell you all the medications they are taking including any herbal supplements or vitamins. Co-administration of KALYDECO with strong CYP3A inducers (e.g., rifampin, St. John's wort) is not recommended, as they may reduce the therapeutic effectiveness of KALYDECO. Reduction of the dose of KALYDECO to one tablet or one packet of granules twice a week is recommended when co-administered with strong CYP3A inhibitors, such as ketoconazole. Dose reduction to one tablet or one packet of granules once daily is recommended when co-administered with moderate CYP3A inhibitors, such as fluconazole. Food containing grapefruit or Seville oranges should be avoided [see DRUG INTERACTIONS and CLINICAL PHARMACOLOGY].
Use In Patients With Hepatic ImpairmentInquire and/or assess whether patients have liver impairment. Reduce the dose of KALYDECO in patients with moderately impaired hepatic function (Child-Pugh Class B, score 7-9) to one tablet or one packet of granules once daily. KALYDECO has not been studied in patients with severe hepatic impairment (Child-Pugh Class C, score 10-15); however, exposure is expected to be substantially higher than that observed in patients with moderate hepatic impairment. When benefits are expected to outweigh the risks, KALYDECO should be used with caution in patients with severe hepatic impairment at a dose of one tablet or one packet of granules given once daily or less frequently. No dose adjustment is recommended for patients with mild hepatic impairment (Child-Pugh Class A, score 5-6) [see Use In Specific Populations].
AdministrationKALYDECO® (ivacaftor) tablets 150 mg Inform patients that KALYDECO tablet is best absorbed by the body when taken with food that contains fat. A typical CF diet will satisfy this requirement. Examples include eggs, butter, peanut butter, cheese pizza, whole-milk dairy products (such as whole milk, cheese, and yogurt), etc.
KALYDECO® (ivacaftor) oral granules 50 mg or 75 mg Inform patients and caregivers that KALYDECO oral granules should be mixed with one teaspoon (5 mL) of age-appropriate soft food or liquid and completely consumed to ensure delivery of the entire dose. Food or liquid should be at or below room temperature. Once mixed, the product has been shown to be stable for one hour, and therefore should be consumed during this period. Some examples of appropriate soft foods or liquids may include puréed fruits or vegetables, yogurt, applesauce, water, milk, or juice.
Inform patients and caregivers that KALYDECO is best absorbed by the body when taken with food that contains fat; therefore, KALYDECO oral granules should be taken just before or just after consuming food that contains fat. A typical CF diet will satisfy this requirement. Examples include eggs, butter, peanut butter, cheese pizza, whole-milk dairy products (such as whole milk, cheese, and yogurt), etc.
Patients should be informed about what to do in the event they miss a dose of KALYDECO:
· In case a dose of KALYDECO is missed within 6 hours of the time it is usually taken, patients should be instructed to take the prescribed dose of KALYDECO with fat-containing food as soon as possible.
· If more than 6 hours have passed since KALYDECO is usually taken, the missed dose should NOT be taken and the patient should resume the usual dosing schedule.
· Patients should be advised to contact their health care provider if they have questions.
CataractsInform patients that abnormality of the eye lens (cataract) has been noted in some children and adolescents receiving KALYDECO. Baseline and follow-up ophthalmological examinations should be performed in pediatric patients initiating KALYDECO treatment [see WARNINGS AND PRECAUTIONS].
Nonclinical ToxicologyCarcinogenesis, Mutagenesis, Impairment Of FertilityTwo-year studies were conducted in CD-1 mice and Sprague-Dawley rats to assess carcinogenicpotential of KALYDECO. No evidence of tumorigenicity was observed in mice or rats at ivacaftor oral doses up to 200 mg/kg/day and 50 mg/kg/day, respectively (approximately equal to 1 and 4 times the MRHD based on summed AUCs of ivacaftor and its metabolites).
Ivacaftor was negative for genotoxicity in the following assays: Ames test for bacterial gene mutation, in vitro chromosomal aberration assay in Chinese hamster ovary cells, and in vivo mouse micronucleus test.
Ivacaftor impaired fertility and reproductive performance indices in male and female rats at 200 mg/kg/day (yielding exposures approximately 8 and 5 times, respectively, the MRHD based on summed AUCs of ivacaftor and its major metabolites). Increases in prolonged diestrus were observed in females at 200 mg/kg/day. Ivacaftor also increased the number of females with all nonviable embryos and decreased corpora lutea, implantations, and viable embryos in rats at 200 mg/kg/day (approximately 5 times the MRHD based on summed AUCs of ivacaftor and its major metabolites) when dams were dosed prior to and during early pregnancy. These impairments of fertility and reproductive performance in male and female rats at 200 mg/kg/day were attributed to severe toxicity. No effects on male or female fertility and reproductive performance indices were observed at ≤100 mg/kg/day (yielding exposures approximately 6 and 3 times, respectively, the MRHD based on summed AUCs of ivacaftor and its major metabolites).
Use In Specific PopulationsPregnancyRisk SummaryThere are limited and incomplete human data from clinical trials and post marketing reports on use of KALYDECO in pregnant women. In animal reproduction studies, oral administration of ivacaftor to pregnant rats and rabbits during organogenesis demonstrated no teratogenicity or adverse effects on fetal development at doses that produced maternal exposures up to approximately 5 (rats) and 11 (rabbits) times the exposure at the maximum recommended human dose (MRHD). No adverse developmental effects were observed after oral administration of ivacaftor to pregnant rats from organogenesis through lactation at doses that produced maternal exposures approximately 3 times the exposures at the MRHD, respectively (see Data).
The background risk of major birth defects and miscarriage for the indicated population is unknown. In the U.S. general population, the estimated background risk of major birth defects is 2% to 4% and miscarriage is 15% to 20% in clinically recognized pregnancies.
DataAnimal Data
In an embryo-fetal development study in pregnant rats dosed during the period of organogenesis from gestation days 7-17, ivacaftor was not teratogenic and did not affect fetal survival at exposures up to 5 times the MRHD (based on summed AUCs for ivacaftor and its metabolites at maternal oral doses up to 200 mg/kg/day). In an embryo-fetal development study in pregnant rabbits dosed during the period of organogenesis from gestation days 7-19, ivacaftor was not teratogenic and did not affect fetal development or survival at exposures up to 11 times the MRHD (on an ivacaftor AUC basis at maternal oral doses up to 100 mg/kg/day). In a pre-and postnatal development study in pregnant female rats dosed from gestation day 7 through lactation day 20, ivacaftor had no effects on delivery or growth and development of offspring at exposures up to 3 times the MRHD (based on summed AUCs for ivacaftor and its metabolites at maternal oral doses up to 100 mg/kg/day). Decreased fetal body weights were observed at a maternally toxic dose that produced exposures 5 times the MRHD (based on summed AUCs for ivacaftor and its metabolites at a maternal oral dose of 200 mg/kg/day). Placental transfer of ivacaftor was observed in pregnant rats and rabbits.
LactationRisk SummaryThere is no information regarding the presence of ivacaftor in human milk, the effects on the breastfed infant, or the effects on milk production. Ivacaftor is excreted into the milk of lactating rats; however, due to species-specific differences in lactation physiology, animal lactation data may not reliably predict levels in human milk (see Data). The developmental and health benefits of breastfeeding should be considered along with the mother's clinical need for KALYDECO, and any potential adverse effects on the breastfed child from KALYDECO or from the underlying maternal condition.
DataLacteal excretion of ivacaftor in rats was demonstrated following a single oral dose (100 mg/kg) of 14C-ivacaftor administered 9 to 10 days postpartum to lactating mothers (dams). Exposure (AUC0-24h) values for ivacaftor in milk were approximately 1.5 times higher than plasma levels.
Pediatric UseKALYDECO is indicated for the treatment CF in pediatric patients age 2-17 years of age who have one mutation in the CFTR gene that is responsive to ivacaftor potentiation based on clinical and/or in vitro assay data [see CLINICAL PHARMACOLOGY and Clinical Studies].
Clinical trials included the following CF patients:
· 6 to 17 years of age with a G551D, G1244E, G1349D, G178R, G551S, S1251N, S1255P, S549N, S549R, or R117H mutation in the CFTR gene [see ADVERSE REACTIONS and Clinical Studies].
· 12 to 17 years of age who are heterozygous for the F508del mutation and a second mutation predicted to be responsive to ivacaftor [see ADVERSE REACTIONS and Clinical Studies].
The efficacy of KALYDECO in patients 2 to less than 6 years was extrapolated from patients 6 years of age and older with support from population pharmacokinetic analyses showing similar drug exposure levels in adults and children 2 to less than 6 years of age [see CLINICAL PHARMACOLOGY]. Safety of KALYDECO in this population was derived from a 24 week, open label, clinical trial in 34 patients ages 2 to less than 6 years (mean age 3 years) administered either 50 mg or 75 mg of ivacaftor granules twice daily (Trial 6). The type and frequency of adverse reactions in this trial were similar to those in patients 6 years and older. Transaminase elevations were more common in patients who had abnormal transaminases at baseline [see WARNINGS AND PRECAUTIONS and ADVERSE REACTIONS].
The safety and efficacy of KALYDECO in patients with CF younger than 2 years of age have not been studied. The use of KALYDECO in children under the age of 2 years is not recommended.
Juvenile Animal Toxicity DataIn a juvenile toxicology study in which ivacaftor was administered to rats from postnatal days 7 to 35, cataracts were observed at all dose levels, ranging from 0.1 to 0.8 times the MRHD (based on summed AUCs for ivacaftor and its metabolites at oral doses of 10-50 mg/kg/day). This finding has not been observed in older animals.
Geriatric UseCF is largely a disease of children and young adults. Clinical trials of KALYDECO did not include sufficient numbers of patients 65 years of age and over to determine whether they respond differently from younger patients.
Hepatic ImpairmentNo dose adjustment is necessary for patients with mild hepatic impairment (Child-Pugh Class A). A reduced dose of KALYDECO is recommended in patients with moderate hepatic impairment (Child-Pugh Class B), as follows: in patients 6 years and older, one 150 mg tablet once daily; in patients 2 to less than 6 years with body weight less than 14 kg, one 50 mg packet of granules once daily; and in patients 2 to less than 6 years with body weight 14 kg or greater, one 75 mg packet of granules once daily. Studies have not been conducted in patients with severe hepatic impairment (Child-Pugh Class C), but exposure is expected to be higher than in patients with moderate hepatic impairment. Therefore, use with caution at a dose of one tablet or one packet of granules once daily or less frequently in patients with severe hepatic impairment after weighing the risks and benefits of treatment [see CLINICAL PHARMACOLOGY].
Renal ImpairmentKALYDECO has not been studied in patients with mild, moderate, or severe renal impairment or in patients with end-stage renal disease. No dose adjustment is necessary for patients with mild to moderate renal impairment; however, caution is recommended while using KALYDECO in patients with severe renal impairment (creatinine clearance less than or equal to 30 mL/min) or end-stage renal disease.
Overdosage & Contraindications
OVERDOSEThere have been no reports of overdose with KALYDECO.
The highest single dose used in a clinical study was 800 mg in a solution formulation without any treatment-related adverse events.
The highest repeated dose was 450 mg (in a tablet formulation) every 12 hours for 4.5 days (9 doses) in a trial evaluating the effect of KALYDECO on ECGs in healthy subjects. Adverse events reported at a higher incidence compared to placebo included dizziness and diarrhea.
No specific antidote is available for overdose with KALYDECO. Treatment of overdose with KALYDECO consists of general supportive measures including monitoring of vital signs and observation of the clinical status of the patient.
CONTRAINDICATIONSNone.
Clinical Pharmacology
CLINICAL PHARMACOLOGYMechanism Of ActionIvacaftor is a potentiator of the CFTR protein. The CFTR protein is a chloride channel present at the surface of epithelial cells in multiple organs. Ivacaftor facilitates increased chloride transport by potentiating the channel open probability (or gating) of CFTR protein located at the cell surface. The overall level of ivacaftor-mediated CFTR chloride transport is dependent on the amount of CFTR protein at the cell surface and how responsive a particular mutant CFTR protein is to ivacaftor potentiation.
CFTR Chloride Transport Assay In Fisher Rat Thyroid (FRT) Cells Expressing Mutant CFTRIn order to evaluate the response of mutant CFTR protein to ivacaftor, total chloride transport was determined in Ussing chamber electrophysiology studies using a panel of FRT cell lines transfected with individual CFTR mutations. Ivacaftor increased chloride transport in FRT cells expressing CFTR mutations that result in CFTR protein being delivered to the cell surface.
Data shown in Figure 1 are the mean (n=3-7) net change over baseline in CFTR mediated chloride transport following the addition of ivacaftor in FRT cells expressing mutant CFTR proteins. The in vitro CFTR chloride response threshold was designated as a net increase of at least 10% of normal over baseline (dotted line) because it is predictive or reasonably expected to predict clinical benefit. Mutations with an increase in chloride transport of 10% or greater are considered responsive. A patient must have at least one CFTR mutation responsive to ivacaftor to be indicated. Mutations including F508del that are not responsive to ivacaftor potentiation, based on the in vitro CFTR chloride response threshold, are listed in Figure 1 below the dotted line.
Figure 1: Net Change Over Baseline (% of Normal) in CFTR-Mediated Chloride Transport Following Addition of Ivacaftor in FRT Cells Expressing Mutant CFTR (Ussing Chamber Electrophysiology Data)
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*Clinical data exist for these mutations [see Clinical Studies].
#A46D, G85E, E92K, P205S, R334W,R347P, T338I, S492F, I507del, V520F, A559T, R560S, R560T, A561E, L927P, H1054D, G1061R, L1065P, R1066C, R1066H, R1066M, L1077P, H1085R, M1101K, W1282X, N1303K mutations in the CFTR gene do not meet the threshold of change in CFTR mediated chloride transport of at least 10% of normal over baseline.
Note that splice mutations cannot be studied in this FRT assay and are not included in Figure 1. Evidence of clinical efficacy exists for non-canonical splice mutations 2789+5G→A, 3272-26A→G, 3849+10kbC→T, 711+3A→G and E831X and these are listed in Table 3 below [see also Clinical Studies]. The G970R mutation causes a splicing defect resulting in little-to-no CFTR protein at the cell surface that can be potentiated by ivacaftor [see Clinical Studies].
Ivacaftor also increased chloride transport in cultured human bronchial epithelial (HBE) cells derived from CF patients who carried F508del on one CFTR allele and either G551D or R117H-5T on the second CFTR allele.
Table 3 lists mutations that are responsive to ivacaftor based on 1) a positive clinical response and/or 2) in vitro data in FRT cells indicating that ivacaftor increases chloride transport to at least 10% over baseline (% of normal).
Table 3: List of CFTR Gene Mutations that Produce CFTR Protein and are Responsive to KALYDECO
E56K |
G178R |
S549R |
S977F |
F1074L |
2789+5G→A |
P67L |
E193K |
G551D |
F1052V |
D1152H |
3272-26A→G |
R74W |
L206W |
G551S |
K1060T |
G1244E |
3849+10kbC→T |
D110E |
R347H |
D579G |
A1067T |
S1251N |
|
D110H |
R352Q |
711+3A→G |
G1069R |
S1255P |
|
R117C |
A455E |
E831X |
R1070Q |
D1270N |
|
R117H |
S549N |
S945L |
R1070W |
G1349D |
|
Changes in sweat chloride (a biomarker) response to KALYDECO were evaluated in seven clinical trials [see Clinical Studies]. In a two-part, randomized, double-blind, placebo-controlled, crossover clinical trial in patients with CF who had a G1244E, G1349D, G178R, G551S, G970R, S1251N, S1255P, S549N, or S549R mutation in the CFTR gene (Trial 4), the treatment difference in mean change in sweat chloride from baseline through 8 weeks of treatment was -49 mmol/L (95% CI -57, -41). The mean changes in sweat chloride for the mutations for which KALYDECO is indicated ranged from -51 to -8, whereas the range for individual subjects with the G970R mutation was -1 to -11 mmol/L. In an open-label clinical trial in 34 patients ages 2 to less than 6 years administered either 50 mg or 75 mg of ivacaftor twice daily (Trial 6), the mean absolute change from baseline in sweat chloride through 24 weeks of treatment was -45 mmol/L (95% CI -53, -38) [see Use In Specific Populations]. In a randomized, double-blind, placebo controlled, 2-period, 3-treatment, 8-week crossover study in patients with CF age 12 years and older who were heterozygous for the F508del mutation and with a second CFTR mutation predicted to be responsive to ivacaftor (Trial 7), the treatment difference in mean change in sweat chloride from study baseline to the average of week 4 and week 8 of treatment for KALYDECO treated patients was -4.5 mmol/L (95% CI -6.7, -2.3).
There was no direct correlation between decrease in sweat chloride levels and improvement in lung function (FEV1).
Cardiac ElectrophysiologyThe effect of multiple doses of ivacaftor 150 mg and 450 mg twice daily on QTc interval was evaluated in a randomized, placebo-and active-controlled (moxifloxacin 400 mg) four-period crossover thorough QT study in 72 healthy subjects. In a study with demonstrated ability to detect small effects, the upper bound of the one-sided 95% confidence interval for the largest placebo adjusted, baseline-corrected QTc based on Fridericia's correction method (QTcF) was below 10 ms, the threshold for regulatory concern.
PharmacokineticsThe pharmacokinetics of ivacaftor is similar between healthy adult volunteers and patients with CF.
After oral administration of a single 150 mg dose to healthy volunteers in a fed state, peak plasma concentrations (Tmax) occurred at approximately 4 hours, and the mean (±SD) for AUC and Cmax were 10600 (5260) ng*hr/mL and 768 (233) ng/mL, respectively.
After every 12-hour dosing, steady-state plasma concentrations of ivacaftor were reached by days 3 to 5, with an accumulation ratio ranging from 2.2 to 2.9.
AbsorptionThe exposure of ivacaftor increased approximately 2.5-to 4-fold when given with food that contains fat. Therefore, KALYDECO should be administered with fat-containing food. Examples of fat-containing foods include eggs, butter, peanut butter, cheese pizza, whole-milk dairy products (such as whole milk, cheese, and yogurt), etc. The median (range) Tmax is approximately 4.0 (3.0; 6.0) hours in the fed state.
KALYDECO granules (2 x 75 mg) had similar bioavailability as the 150 mg tablet when given with fat-containing food in adult subjects. The effect of food on ivacaftor absorption is similar for KALYDECO granules and the 150 mg tablet formulation.
DistributionIvacaftor is approximately 99% bound to plasma proteins, primarily to alpha 1-acid glycoprotein and albumin. Ivacaftor does not bind to human red blood cells.
After oral administration of 150 mg every 12 hours for 7 days to healthy volunteers in a fed state, the mean (±SD) for apparent volume of distribution was 353 (122) L.
MetabolismIvacaftor is extensively metabolized in humans. In vitro and clinical studies indicate that ivacaftor is primarily metabolized by CYP3A. M1 and M6 are the two major metabolites of ivacaftor in humans. M1 has approximately one-sixth the potency of ivacaftor and is considered pharmacologically active. M6 has less than one-fiftieth the potency of ivacaftor and is not considered pharmacologically active.
EliminationFollowing oral administration, the majority of ivacaftor (87.8%) is eliminated in the feces after metabolic conversion. The major metabolites M1 and M6 accounted for approximately 65% of the total dose eliminated with 22% as M1 and 43% as M6. There was negligible urinary excretion of ivacaftor as unchanged parent. The apparent terminal half-life was approximately 12 hours following a single dose. The mean apparent clearance (CL/F) of ivacaftor was similar for healthy subjects and patients with CF. The CL/F (SD) for the 150 mg dose was 17.3 (8.4) L/hr in healthy subjects.
Specific populationsPediatric PatientsThe following conclusions about exposures between adults and the pediatric population are based on population PK analyses:
Pediatric Patients 2 To Less Than 6 Years Of Age Who Weigh Less Than 14 kgFollowing oral administration of KALYDECO granules, 50 mg every 12 hours, the mean (±SD) steady state AUC (AUCss) was 10500 (4260) ng/mL*h and is similar to the mean AUCss of 10700 (4100) ng/mL*h in adult patients administered KALYDECO tablets, 150 mg every 12 hours.
Pediatric Patients 2 To Less Than 6 Years Of Age Who Weigh 14 kg Or GreaterFollowing oral administration of KALYDECO granules, 75 mg every 12 hours, the mean (±SD) AUC (AUCss) was 11300 (3820) ng/mL*h and is similar to the mean AUC in adult patients administered KALYDECO tablets, 150 mg every 12 hours.
Pediatric Patients 6 To Less Than 12 Years Of AgeFollowing oral administration of KALYDECO tablets, 150 mg every 12 hours, the mean (±SD) AUCss was 20000 (8330) ng/mL*h and is 87% higher than the mean AUC in adult patients administered KALYDECO tablets, 150 mg every 12 hours.
Pediatric Patients 12 To Less Than 18 Years Of AgeFollowing oral administration of KALYDECO tablets, 150 mg every 12 hours, the mean (±SD) AUCss was 9240 (3420) ng/mL*h and is similar to the mean AUCss in adult patients administered KALYDECO tablets, 150 mg every 12 hours.
Patients With Hepatic ImpairmentAdult subjects with moderately impaired hepatic function (Child-Pugh Class B, score 7-9) had similar ivacaftor Cmax, but an approximately two-fold increase in ivacaftor AUC0-∞ compared with healthy subjects matched for demographics. Based on simulations of these results, a reduced KALYDECO dose to one tablet or packet of granules once daily is recommended for patients with moderate hepatic impairment. The impact of mild hepatic impairment (Child-Pugh Class A) on the pharmacokinetics of ivacaftor has not been studied, but the increase in ivacaftor AUC0-∞ is expected to be less than two-fold. Therefore, no dose adjustment is necessary for patients with mild hepatic impairment. The impact of severe hepatic impairment (Child-Pugh Class C, score 10-15) on the pharmacokinetics of ivacaftor has not been studied. The magnitude of increase in exposure in these patients is unknown, but is expected to be substantially higher than that observed in patients with moderate hepatic impairment. When benefits are expected to outweigh the risks, KALYDECO should be used with caution in patients with severe hepatic impairment at a dose of one tablet or one packet of granules given once daily or less frequently [see DOSAGE AND ADMINISTRATION and Use In Specific Populations].
Patients With Renal ImpairmentKALYDECO has not been studied in patients with mild, moderate, or severe renal impairment (creatinine clearance less than or equal to 30 mL/min) or in patients with end-stage renal disease. No dose adjustments are recommended for mild and moderate renal impairment patients because of minimal elimination of ivacaftor and its metabolites in urine (only 6.6% of total radioactivity was recovered in the urine in a human PK study); however, caution is recommended when administering KALYDECO to patients with severe renal impairment or end-stage renal disease.
Male And Female PatientsThe effect of gender on KALYDECO pharmacokinetics was evaluated using population pharmacokinetics of data from clinical studies of KALYDECO. No dose adjustments are necessary based on gender.
Drug Interaction StudiesDrug interaction studies were performed with KALYDECO and other drugs likely to be co-administered or drugs commonly used as probes for pharmacokinetic interaction studies [see DRUG INTERACTIONS].
Dosing recommendations based on clinical studies or potential drug interactions with KALYDECO are presented below.
Potential For Ivacaftor To Affect Other DrugsBased on in vitro results, ivacaftor and metabolite M1 have the potential to inhibit CYP3A and P-gp. Clinical studies showed that KALYDECO is a weak inhibitor of CYP3A and P-gp, but not an inhibitor of CYP2C8. In vitro studies suggest that ivacaftor and M1 may inhibit CYP2C9. In vitro, ivacaftor, M1, and M6 were not inducers of CYP isozymes. Dosing recommendations for co-administered drugs with KALYDECO are shown in Figure 2.
Figure 2: Impact of KALYDECO on Other Drugs
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Note: The data obtained with substrates but without co-administration of KALYDECO are used as reference.
*NE: Norethindrone; **EE: Ethinyl Estradiol
The vertical lines are at 0.8, 1.0, and 1.25, respectively.
In vitro studies showed that ivacaftor and metabolite M1 were substrates of CYP3A enzymes (i.e., CYP3A4 and CYP3A5). Exposure to ivacaftor is reduced by concomitant CYP3A inducers and increased by concomitant CYP3A inhibitors [see DOSAGE AND ADMINISTRATION and DRUG INTERACTIONS]. KALYDECO dosing recommendations for co-administration with other drugs are shown in Figure 3.
Figure 3: Impact of Other Drugs on KALYDECO
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Note: The data obtained for KALYDECO without co-administration of inducers or inhibitors are used as reference.
The vertical lines are at 0.8, 1.0, and 1.25, respectively.
Dose ranging for the clinical program consisted primarily of one double-blind, placebo-controlled, crossover trial in 39 adult (mean age 31 years) Caucasian patients with CF who had FEV1 ≥40% predicted. Twenty patients with median predicted FEV1 at baseline of 56% (range: 42% to 109%) received KALYDECO 25, 75, 150 mg or placebo every 12 hours for 14 days and 19 patients with median predicted FEV1 at baseline of 69% (range: 40% to 122%) received KALYDECO 150, 250 mg, or placebo every 12 hours for 28 days. The selection of the 150 mg every 12 hours dose was primarily based on nominal improvements in lung function (pre-dose FEV1) and changes in pharmacodynamic parameters (sweat chloride and nasal potential difference). The twice-daily dosing regimen was primarily based on an apparent terminal plasma half-life of approximately 12 hours.
EfficacyThe efficacy of KALYDECO in patients with CF who have a G551D mutation in the CFTR gene was evaluated in two randomized, double-blind, placebo-controlled clinical trials in 213 clinically stable patients with CF (109 receiving KALYDECO 150 mg twice daily). All eligible patients from these trials were rolled over into an open-label extension study.
Trial 1 evaluated 161 patients with CF who were 12 years of age or older (mean age 26 years) with FEV1 at screening between 40-90% predicted [mean FEV1 64% predicted at baseline (range: 32% to 98%)]. Trial 2 evaluated 52 patients who were 6 to 11 years of age (mean age 9 years) with FEV1 at screening between 40-105% predicted [mean FEV1 84% predicted at baseline (range: 44% to 134%)]. Patients who had persistent Burkholderia cenocepacia, Burkholderia dolosa, or Mycobacterium abscessus isolated from sputum at screening and those with abnormal liver function defined as 3 or more liver function tests (ALT, AST, AP, GGT, total bilirubin) ≥3 times the upper limit of normal were excluded.
Patients in both trials were randomized 1:1 to receive either 150 mg of KALYDECO or placebo every 12 hours with food containing fat for 48 weeks in addition to their prescribed CF therapies (e.g., tobramycin, dornase alfa). The use of inhaled hypertonic saline was not permitted.
The primary efficacy endpoint in both studies was improvement in lung function as determined by the mean absolute change from baseline in percent predicted pre-dose FEV1 through 24 weeks of treatment.
In both studies, treatment with KALYDECO resulted in a significant improvement in FEV1. The treatment difference between KALYDECO and placebo for the mean absolute change in percent predicted FEV1 from baseline through Week 24 was 10.6 percentage points (P<0.0001) in Trial 1 and 12.5 percentage points (P<0.0001) in Trial 2 (Figure 4). These changes persisted through 48 weeks. Improvements in percent predicted FEV1 were observed regardless of age, disease severity, sex, and geographic region.
Figure 4: Mean Absolute Change from Baseline in Percent Predicted FEV1*
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*Primary endpoint was assessed at the 24-week time point.
Other efficacy variables included absolute change from baseline in sweat chloride [see CLINICAL PHARMACOLOGY], time to first pulmonary exacerbation (Trial 1 only), absolute change from baseline in weight, and improvement from baseline in Cystic Fibrosis Questionnaire Revised (CFQ-R) respiratory domain score, a measure of respiratory symptoms relevant to patients with CF such as cough, sputum production, and difficulty breathing. For the purpose of the study, a pulmonary exacerbation was defined as a change in antibiotic therapy (IV, inhaled, or oral) as a result of 4 or more of 12 pre-specified sino-pulmonary signs/symptoms. Patients treated with KALYDECO demonstrated statistically significant improvements in risk of pulmonary exacerbations, CF symptoms (in Trial 1 only), and gain in body weight (Table 4). Weight data, when expressed as body mass index normalized for age and sex in patients <20 years of age, were consistent with absolute change from baseline in weight.
Table 4: Effect of KALYDECO on Other Efficacy Endpoints in Trials 1 and 2
Endpoint |
Trial 1 |
Trial 2 |
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Treatment differencea |
P value |
Treatment differencea |
P value |
|
Mean absolute change from baseline in CFQ-R respiratory domain score (points) |
||||
Through Week 24 |
8.1 |
<0.0001 |
6.1 |
0.1092 |
Through Week 48 |
8.6 |
<0.0001 |
5.1 |
0.1354 |
Relative risk of pulmonary exacerbation |
||||
Through Week 24 |
0.40b |
0.0016 |
NA |
NA |
Through Week 48 |
0.46b |
0.0012 |
NA |
NA |
Mean absolute change from baseline in body weight (kg) |
||||
At Week 24 |
2.8 |
<0.0001 |
1.9 |
0.0004 |
At Week 48 |
2.7 |
0.0001 |
2.8 |
0.0002 |
Absolute change in sweat chloride (mmol/L) |
||||
Through Week 24 |
-48 |
<0.0001 |
-54 |
<0.0001 |
Through Week 48 |
-48 |
<0.0001 |
-53 |
<0.0001 |
CI: confidence interval; NA: not analyzed due to low incidence of events |
The efficacy and safety of KALYDECO in patients with CF who have a G1244E, G1349D, G178R, G551S, G970R, S1251N, S1255P, S549N, or S549R mutation in the CFTR gene were evaluated in a two-part, randomized, double-blind, placebo-controlled, crossover design clinical trial in 39 patients with CF (Trial 4). Patients who completed Part 1 of this trial continued into the 16-week open-label Part 2 of the study. The mutations studied were G178R, S549N, S549R, G551S, G970R, G1244E, S1251N, S1255P, and G1349D. See Clinical Studies for efficacy in patients with a G551D mutation.
Patients were 6 years of age or older (mean age 23 years) with FEV1 ≥40% at screening [mean FEV1at baseline 78% predicted (range: 43% to 119%)]. Patients with evidence of colonization with Burkholderia cenocepacia, Burkholderia dolosa, or Mycobacterium abscessus and those with abnormal liver function defined as 3 or more liver function tests (ALT, AST, AP, GGT, total bilirubin) ≥3 times the upper limit of normal at screening were excluded.
Patients were randomized 1:1 to receive either 150 mg of KALYDECO or placebo every 12 hours with food containing fat for 8 weeks in addition to their prescribed CF therapies during the first treatment period and crossed over to the other treatment for the second 8 weeks. The two 8-week treatment periods were separated by a 4-to 8-week washout period. The use of inhaled hypertonic saline was not permitted.
The primary efficacy endpoint was improvement in lung function as determined by the mean absolute change from baseline in percent predicted FEV1 through 8 weeks of treatment. Other efficacy variables included absolute change from baseline in sweat chloride through 8 weeks of treatment [see CLINICAL PHARMACOLOGY], absolute change from baseline in body mass index (BMI) at 8 weeks of treatment (including body weight at 8 weeks), and improvement in CFQ-R respiratory domain score through 8 weeks of treatment. For the overall population of the 9 mutations studied, treatment with KALYDECO compared to placebo resulted in significant improvement in percent predicted FEV1 [10.7 through Week 8 (P<0.0001)], BMI [0.66 kg/m² at Week 8 (P<0.0001)], and CFQ-R respiratory domain score [9.6 through Week 8 (P=0.0004)]; however, there was a high degree of variability of efficacy responses among the 9 mutations (Table 5).
Table 5: Effect of KALYDECO for Efficacy Variables in the Overall Populations and for Specific CFTR Mutations
Mutation (n) |
Absolute change in percent predicted FEV1 |
BMI (kg/m²) |
CFQ-R Respiratory Domain Score (Points) |
Absolute Change in Sweat Chloride (mmol/L) |
||
At Week 2 |
At Week 4 |
At Week 8 |
At Week 8 |
At Week 8 |
At Week 8 |
|
All patients (n=39) |
||||||
Results shown as mean (95% CI) change from baseline KALYDECO vs. placebo-treated patients: |
||||||
|
8.3 (4.5, 12.1) |
10.0 (6.2, 13.8) |
13.8 (9.9, 17.6) |
0.66† (0.34, 0.99) |
12.8 (6.7, 18.9) |
-50 (-58, -41)* |
Patients grouped under mutation types (n) |
||||||
Results shown as mean (minimum, maximum) for change from baseline for KALYDECO-treated patients**: |
||||||
G1244E (5) |
11 (-5, 25) |
6 (-5, 13) |
8 (-1, 18) |
0.63 (0.34, 1.32) |
3.3 (-27.8, 22.2) |
-55 (-75, -34) |
G1349D (2) |
19 (5, 33) |
18 (2, 35) |
20 (3, 36) |
1.15 (1.07, 1.22) |
16.7 (-11.1, 44.4) |
-80 (-82, -79) |
G178R (5) |
7 (1, 17) |
10 (-2, 21) |
8 (-1, 18) |
0.85 (0.33, 1.46) |
20.0 (5.6, 50.0) |
-53 (-65, -35) |
G551S (2) |
0 (-5, 5) |
0.3 (-5, 6) |
3†† |
0.16†† |
16.7†† |
-68†† |
G970R (4) |
7 (1, 13) |
7 (1, 14) |
3 (-1, 5) |
0.48 (-0.38, 1.75) |
1.4 (-16.7, 16.7) |
-6 (-16, -2) |
S1251N (8) |
2 (-23, 20) |
8 (-13, 26) |
9 (-20, 21) |
0.73 (0.08, 1.83) |
23.3 (5.6, 50.0) |
-54 (-84, -7) |
S1255P (2) |
11 (8, 14) |
9 (5, 13) |
3 (-1, 8) |
1.62 (1.39, 1.84) |
8.3 (5.6, 11.1) |
-78 (-82, -74) |
S549N (6) |
11 (5, 16) |
8 (-9, 19) |
11 (-2, 20) |
0.79 (0.00, 1.91) |
8.8 (-8.3, 27.8) |
-74 (-93, -53) |
S549R (4) |
3 (-4, 8) |
4 (-4, 10) |
5 (-3, 13) |
0.53 (0.33, 0.80) |
6.9 (0.0, 11.1) |
-61††† (-71, -54) |
* n=36 for the analysis of absolute change in sweat chloride. |
The efficacy and safety of KALYDECO in patients with CF who have an R117H mutation in the CFTR gene were evaluated in a randomized, double-blind, placebo-controlled, parallel-group clinical trial (Trial 5). Fifty-nine of 69 patients completed 24 weeks of treatment. Two patients discontinued and 8 patients did not complete treatment due to study termination. Trial 5 evaluated 69 clinically stable patients with CF who were 6 years of age or older (mean age 31 years). Patients who were 12 years and older had FEV1 at screening between 40-90% predicted, and patients who were 6-11 years of age had FEV1 at screening between 40-105% predicted. The overall mean FEV1 was 73% predicted at baseline (range: 33% to 106%). The patients had well preserved BMIs (mean overall: 23.76 kg/m²) and a high proportion were pancreatic sufficient as assessed by a low rate of pancreatic enzyme replacement therapy use (pancreatin: 11.6%; pancrelipase: 5.8%). Patients who had persistent Burkholderia cenocepacia, Burkholderia dolosa, or Mycobacterium abscessus isolated from sputum at screening, and those with abnormal liver function defined as 3 or more liver function tests (ALT, AST, AP, GGT, total bilirubin) ≥3 times the ULN, were excluded.
Patients were randomized 1:1 to receive either 150 mg of KALYDECO (n=34) or placebo (n=35) every 12 hours with food containing fat for 24 weeks in addition to their prescribed CF therapies.
The primary efficacy endpoint was improvement in lung function as determined by the mean absolute change from baseline in percent predicted FEV1 through 24 weeks of treatment. The treatment difference for absolute change in percent predicted FEV1 through Week 24 was 2.1 percentage points (analysis conducted with the full analysis set which included all 69 patients), and did not reach statistical significance (Table 6).
Other efficacy variables that were analyzed included absolute change in sweat chloride from baseline through Week 24, improvement in cystic fibrosis respiratory symptoms through Week 24 as assessed by the CFQ-R respiratory domain score (Table 6), absolute change in body mass index (BMI) at Week 24, and time to first pulmonary exacerbation. The overall treatment difference for the absolute change from baseline in BMI at Week 24 was 0.3 kg/m² and the calculated hazard ratio for time to first pulmonary exacerbation was 0.93, which were not statistically significant.
Statistically significant improvements in clinical efficacy (FEV1, CFQ-R respiratory domain) were seen in several subgroup analyses, and decreases in sweat chloride were observed in all subgroups. The mean baseline sweat chloride for all patients was 70 mmol/L. Subgroups analyzed included those based on age, lung function, and poly-T status (Table 6).
Table 6: Effect of KALYDECO on Overall Population (Percent Predicted FEV1, CFQ-R Respiratory Domain Score, and Sweat Chloride) and in Relevant Subgroups Through 24 Weeks
Subgroup Parameter |
Study Drug |
% Predicted FEV1(Percentage Points) |
CFQ-R Respiratory Domain Score (Points) |
Sweat Chloride (mmol/L) |
||||||
n |
Mean |
Treatment Difference (95% CI) |
n |
Mean |
Treatment Difference (95% CI) |
n |
Mean |
Treatment Difference (95% CI) |
||
R117H-AII Patients |
||||||||||
|
Placebo |
35 |
0.5 |
2.1 |
34 |
-0.8 |
8.4 |
35 |
-2.3 |
-24.0 |
Kalydeco |
34 |
2.6 |
(-1.1, 5.4) |
33 |
7.6 |
(2.2, 14.6) |
32 |
-26.3 |
(-28.0, -19.9) |
|
Subgroup by Age |
||||||||||
6-11 |
Placebo |
8 |
3.5 |
-6.3 |
7 |
-1.6 |
-6.1 |
8 |
1.0 |
-27.6 |
Kalydeco |
9 |
-2.8 |
(-12.0, -0.7) |
8 |
-7.7 |
(-15.7, 3.4) |
8 |
-26.6 |
(-37.2, -18.1) |
|
12-17 |
Placebo |
1 |
- |
- |
1 |
- |
- |
1 |
- |
- |
Kalydeco |
1 |
- |
- |
1 |
|
|
1 |
- |
- |
|
≥18 |
Placebo |
26 |
-0.5 |
5.0 |
26 |
-0.5 |
12.6 |
26 |
-4.0 |
-21.9 |
Kalydeco |
24 |
4.5 |
(1.1, 8.8) |
24 |
12.2 |
(5.0, 20.3) |
23 |
-25.9 |
(-26.5, -17.3) |
|
Subgroup by Poly-T Status† |
||||||||||
5T |
Placebo |
24 |
0.7 |
5.3 |
24 |
-0.6 |
15.3 |
24 |
-4.6 |
-24.2 |
Kalydeco |
14 |
6.0 |
(1.3, 9.3) |
14 |
14.7 |
(7.7, 23.0) |
13 |
-28.7 |
(-30.2, -18.2) |
|
7T |
Placebo |
5 |
-0.9 |
0.2 |
5 |
-6.0 |
5.2 |
5 |
3.9 |
-24.1 |
Kalydeco |
11 |
-0.7 |
(-8.1, 8.5) |
11 |
-0.7 |
(-13.0, 23.4) |
10 |
-20.2 |
(-33.9, -14.3) |
|
Subgroup by Baseline FEV1 % Predicted |
||||||||||
<70% |
Placebo |
15 |
0.4 |
4.0 |
15 |
3.0 |
11.4 |
15 |
-3.8 |
-25.5 |
Kalydeco |
13 |
4.5 |
(-2.1, 10.1) |
13 |
14.4 |
(1.2, 21.6) |
12 |
-29.3 |
(-31.8, -19.3) |
|
70-90% |
Placebo |
14 |
0.2 |
2.6 |
13 |
-3.6 |
8.8 |
14 |
-3.1 |
-20.0 |
Kalydeco |
14 |
2.8 |
(-2.3, 7.5) |
14 |
5.2 |
(-2.6, 20.2) |
14 |
-23.0 |
(-26.9, -12.9) |
|
>90% |
Placebo |
6 |
2.2 |
-4.3 |
6 |
-2.5 |
-0.7 |
6 |
1.0 |
-26.8 |
Kalydeco |
7 |
-2.1 |
(-9.9, 1.3) |
6 |
-3.2 |
(-10.4, 9.0) |
6 |
-25.9 |
(-39.5, -14.1) |
|
* MMRM analysis with fixed effects for treatment, age, week, baseline value, treatment by week, and subject as a random effect |
The efficacy and safety of KALYDECO and an ivacaftor-containing combination product in 246 patients with CF was evaluated in a randomized, double-blind, placebo-controlled, 2-period, 3-treatment, 8-week crossover design clinical trial (Trial 7). Mutations predicted to be responsive to ivacaftor were selected for the study based on the clinical phenotype (pancreatic sufficiency), biomarker data (sweat chloride), and in vitro responsiveness to ivacaftor.
Eligible patients were heterozygous for the F508del mutation with a second mutation predicted to be responsive to ivacaftor. Of the 244 patients included in the efficacy analysis, who were randomized and dosed, 146 patients had a splice mutation and 98 patients had a missense mutation, as the second allele. 156 patients received KALYDECO and 161 patients received placebo. Patients were aged 12 years and older (mean age 35 years [range 12-72]) and had a percent predicted FEV1 at screening between 40-90 [mean ppFEV1 at study baseline 62 (range: 35 to 94)]. Patients with evidence of colonization with organisms associated with a more rapid decline in pulmonary status (e.g. Burkholderia cenocepacia, Burkholderia dolosa, or Mycobacterium abscessus) and those with abnormal liver function at screening were excluded. Abnormal liver function was defined as 2 or more liver function tests (ALT, AST, ALP, GGT) ≥3 times the upper limit of normal or total bilirubin ≥2 times the upper limit of normal, or a single increase in ALT/AST ≥5 times the upper limit of normal.
The primary efficacy endpoint was the mean absolute change from study baseline in percent predicted FEV1 averaged at Weeks 4 and 8 of treatment. The key secondary efficacy endpoint was absolute change in CFQ-R respiratory domain score from study baseline averaged at Weeks 4 and 8 of treatment. For the overall population, treatment with KALYDECO compared to placebo resulted in significant improvement in ppFEV1 [4.7 percent points from study baseline to average of Week 4 and Week 8 (P<0.0001)] and CFQ-R respiratory domain score [9.7 points from study baseline to average of Week 4 and Week 8 (P<0.0001)]. Statistically significant improvements compared to placebo were also observed in the subgroup of patients with splice mutations and missense mutations (Table 7).
Table 7: Effect of KALYDECO for Efficacy Variables
Mutation (n) |
Absolute Change in percent predicted FEV1*† |
Absolute Change in CFQ-R Respiratory Domain Score (Points)*§ |
Absolute Change in Sweat Chloride (mmol/L)*§ |
Splice mutations (n=94 for IVA and n=97 for PBO) |
|||
|
5.4 (4.1, 6.8) |
8.5 (5.3, 11.7) |
-2.4 (-5.0, 0.3) |
By individual splice mutation (n). Results shown as mean (minimum, maximum) for change from study baseline for KALYDECO-treated patients |
|||
2789+5G→A (28) |
5.1 (-7.1, 17.0) |
8.6 (-5.6, 27.8) |
0.4 (-7.5, 8.8) |
3272-26A→G (23) |
3.5 (-9.1, 16.0) |
8.0 (-11.1, 27.8) |
-2.3 (-25.0, 11.8) |
3849+10kBc→T (40) |
5.1 (-6.8, 16.2) |
7.5 (-30.6, 55.6) |
-4.6 (-80.5, 23.0) |
711+3A→G (2) |
9.2 (8.9, 9.6) |
-8.3 (-13.9, -2.8) |
-9.9 (-13.5, -6.3) |
E831X (1) |
7.1 (7.1, 7.1) |
0.0 (0.0, 0.0) |
-7.8 (-7.8, -7.8) |
Missense mutations (n=62 for IVA and n=63 for PBO) |
|||
|
3.6 (1.9, 5.2) |
11.5 (7.5, 15.4) |
-7.8 (-11.2, -4.5) |
By individual missense mutation (n). Results shown as mean (minimum, maximum) for change from study baseline for KALYDECO-treated patients |
|||
D579G (2) |
13.3 (12.4, 14.1) |
15.3 (-2.8, 33.3) |
-30.8 (-36.0, -25.5) |
D1152H (15) |
2.4 (-5.0, 10.2) |
13.7 (-16.7, 50.0) |
-4.8 (-22.0, 3.0) |
A455E (14) |
3.7 (-6.6, 19.7) |
6.8 (-13.9, 33.3) |
7.5 (-16.8, 16.0) |
L206W (2) |
4.2 (2.5, 5.9) |
12.5 (-5.6, 30.6) |
3.9 (-8.3, 16.0) |
P67L (12) |
4.3 (-2.5, 25.7) |
10.8 (-12.5, 36.1) |
-10.5 (-34.8, 9.8) |
R1070W (1) |
2.9 (2.9, 2.9) |
44.4 (44.4, 44.4) |
0.3 (0.3, 0.3) |
R117C (1) |
3.5 (3.5, 3.5) |
22.2 (22.2, 22.2) |
-36.0 (-36.0, -36.0) |
R347H (3) |
2.5 (-0.6, 6.9) |
6.5 (5.6, 8.3) |
-19.2 (-25.8, -7.0) |
R352Q (2) |
4.4 (3.5, 5.3) |
9.7 (8.3, 11.1) |
-21.9 (-45.5, 1.8) |
S945L (9) |
8.8 (-0.2, 20.5) |
10.6 (-25.0, 27.8) |
-30.8 (-50.8, -17.3) |
S977F (1) |
4.3 (4.3, 4.3) |
-2.8 (-2.8, -2.8) |
-19.5 (-19.5, -19.5) |
*Average of Week 4 and 8 values |
In an analysis of BMI at Week 8, an exploratory end-point, patients treated with KALYDECO had a mean improvement of 0.28 kg/m² [95% CI (0.14, 0.43)], 0.24 kg/m² [95% CI (0.06, 0.43)], and 0.35 kg/m² [95% CI (0.12, 0.58)] versus placebo for the overall, splice, and missense mutation populations of patients, respectively.
Trial In Patients Homozygous For The F508del Mutation In The CFTR GeneTrial 3 was a 16-week, randomized, double-blind, placebo-controlled, parallel-group trial in 140 patients with CF age 12 years and older who were homozygous for the F508del mutation in the CFTRgene and who had FEV1 ≥40% predicted. Patients were randomized 4:1 to receive KALYDECO 150 mg (n=112) every 12 hours or placebo (n=28) in addition to their prescribed CF therapies. The mean age of patients enrolled was 23 years and the mean baseline FEV1 was 79% predicted (range 40% to 129%). As in Trials 1 and 2, patients who had persistent Burkholderia cenocepacia, Burkholderia dolosa, or Mycobacterium abscessus isolated from sputum at screening and those with abnormal liver function defined as 3 or more liver function tests (ALT, AST, AP, GGT, total bilirubin) ≥3 times the upper limit of normal were excluded. The use of inhaled hypertonic saline was not permitted.
The primary endpoint was improvement in lung function as determined by the mean absolute change from baseline through Week 16 in percent predicted FEV1. The treatment difference from placebo for the mean absolute change in percent predicted FEV1 through Week 16 in patients with CF homozygous for the F508del mutation in the CFTR gene was 1.72 percentage points (1.5% and -0.2% for patients in the KALYDECO and placebo-treated groups, respectively) and did not reach statistical significance (Table 8).
Other efficacy variables that were analyzed included absolute change in sweat chloride from baseline through Week 16, change in cystic fibrosis respiratory symptoms through Week 16 as assessed by the CFQ-R respiratory domain score (Table 8), change in weight through Week 16, and rate of pulmonary exacerbation. The overall treatment difference for change from baseline in weight through Week 16 was -0.16 kg (95% CI -1.06, 0.74); the rate ratio for pulmonary exacerbation was 0.677 (95% CI 0.33, 1.37).
Table 8: Effect of KALYDECO on Overall Population (Percent Predicted FEV1, CFQ-R Respiratory Domain Score, and Sweat Chloride) Through 16 Weeks
Subgroup Parameter |
Study Drug |
Absolute Change through Week 16 - Full Analysis Set |
||||||||
% Predicted FEV1(Percentage Points) |
CFQ-R Respiratory Domain Score (Points) |
Sweat Chloride (mmol/L) |
||||||||
n |
Mean |
Treatment Difference (95% CI) |
n |
Mean |
Treatment Difference (95% CI) |
n |
Mean |
Treatment Difference (95% CI) |
||
F508del homozygous |
||||||||||
|
Placebo |
28 |
-0.2 |
1.72 |
28 |
-1.44 |
1.3 |
28 |
0.13 |
-2.9 |
|
Kalydeco |
111 |
1.5 |
(-0.6, 4.1) |
111 |
-0.12 |
(-2.9, 5.6) |
109 |
-2.74 |
(-5.6, -0.2) |
* MMRM analysis with fixed effects for treatment, age week, baseline value, treatment by week, and subject as a random effect |
Medication Guide
PATIENT INFORMATION
KALYDECO
(kuh-LYE-deh-koh)
(ivacaftor) Film-Coated Tablets and Oral Granules
Read this Patient Information before you start taking KALYDECO and each time you get a refill. There may be new information. This information does not take the place of talking to your doctor about your medical condition or your treatment.
What is KALYDECO?
KALYDECO is a prescription medicine used for the treatment of cystic fibrosis (CF) in patients age 2 years and older who have at least one mutation in their CF gene that is responsive to KALYDECO.
Talk to your doctor to learn if you have an indicated CF gene mutation.
It is not known if KALYDECO is safe and effective in children under 2 years of age.
Who should not take KALYDECO?
Do not take KALYDECO if you take certain medicines or herbal supplements such as:
· the antibiotics rifampin (Rifamate®, Rifater®) or rifabutin (Mycobutin®)
· seizure medications such as phenobarbital, carbamazepine (Tegretol®, Carbatrol®, Equetro®) or phenytoin (Dilantin®, Phenytek®)
· St. John's wort
Talk to your doctor before taking KALYDECO if you take any of the medicines or supplements listed above.
What should I tell my doctor before taking KALYDECO?
Before you take KALYDECO, tell your doctor if you:
· have liver or kidney problems
· drink grapefruit juice, or eat grapefruit or Seville oranges
· are pregnant or plan to become pregnant. It is not known if KALYDECO will harm your unborn baby. You and your doctor should decide if you will take KALYDECO while you are pregnant.
· are breastfeeding or planning to breastfeed. It is not known if KALYDECO passes into your breast milk. You and your doctor should decide if you will take KALYDECO while you are breastfeeding.
KALYDECO may affect the way other medicines work, and other medicines may affect how KALYDECO works.
Tell your doctor about all the medicines you take, including prescription and non-prescription medicines, vitamins, and herbal supplements, as the dose of KALYDECO may need to be adjusted when taken with certain medications.
Ask your doctor or pharmacist for a list of these medicines if you are not sure.
Especially tell your doctor if you take:
· antifungal medications such as ketoconazole (e.g., Nizoral®), itraconazole (e.g., Sporanox®), posaconazole (e.g., Noxafil®), voriconazole (e.g., Vfend®), or fluconazole (e.g., Diflucan®)
· antibiotics such as telithromycin (e.g., Ketek®), clarithromycin (e.g., Biaxin®), or erythromycin(e.g., Ery-Tab®)
Know the medicines you take. Keep a list of them to show your doctor and pharmacist when you get a new medicine.
How should I take KALYDECO?
· Take KALYDECO exactly as your doctor tells you to take it.
· Take your doses of KALYDECO 12 hours apart.
· If you miss a dose of KALYDECO and it is within 6 hours of when you usually take it, take your dose of KALYDECO as prescribed with fat-containing food as soon as possible.
· If you miss a dose of KALYDECO and it is more than 6 hours after the time you usually take it, skip that dose only and take the next dose when you usually take it. Do not take 2 doses at the same time to make up for your missed dose.
KALYDECO Tablets (ages 6 years and older):
· Always take KALYDECO tablets with food that contains fat. Examples of fat-containing foods include eggs, butter, peanut butter, cheese pizza, and whole-milk dairy products such as whole milk, cheese, and yogurt.
· Each KALYDECO box contains 4 individual blister cards.
· Each blister card contains 14 pills—7 morning doses and 7 evening doses.
· In the morning, unpeel the paper backing from a blister card to remove 1 KALYDECO tablet and take it with food that contains fat.
· In the evening, 12 hours later, open another blister card to remove 1 KALYDECO tablet and take it with food that contains fat.
· You may cut along the dotted line to separate your doses from the blister card.
KALYDECO Oral Granules (ages 2 to under 6 years old):
· Hold the packet with cut line on top.
· Shake the packet gently to settle the KALYDECO granules.
· Tear or cut packet open along cut line.
· Carefully pour all of the KALYDECO granules in the packet into 1 teaspoon of soft food or liquid. Food or liquid should be at or below room temperature. Some examples of soft foods or liquids include puréed fruits or vegetables, yogurt, applesauce, water, milk, or juice.
· Mix the KALYDECO granules with food or liquid.
· After mixing, give KALYDECO within 1 hour. Make sure all medicine is taken.
· Give a child fat-containing food just before or just after the KALYDECO granules dose. Examples of fat-containing foods include eggs, butter, peanut butter, cheese pizza, and whole-milk dairy products such as whole milk, cheese, and yogurt.
What should I avoid while taking KALYDECO?
· KALYDECO can cause dizziness in some people who take it. Do not drive a car, use machinery or do anything that needs you to be alert until you know how KALYDECO affects you.
· You should avoid food containing grapefruit or Seville oranges while you are taking KALYDECO.
What are the possible side effects of KALYDECO?
KALYDECO can cause serious side effects.
High liver enzymes in the blood have been reported in patients receiving KALYDECO. Your doctor will do blood tests to check your liver:
· before you start KALYDECO
· every 3 months during your first year of taking KALYDECO
· every year while you are taking KALYDECO
For patients who have had high liver enzymes in the past, the doctor may do blood tests to check the liver more often.
Call your doctor right away if you have any of the following symptoms of liver problems:
· pain or discomfort in the upper right stomach (abdominal) area
· yellowing of your skin or the white part of your eyes
· loss of appetite
· nausea or vomiting
· dark, amber-colored urine
Abnormality of the eye lens (cataract) has been noted in some children and adolescents receiving KALYDECO.
Your doctor should perform eye examinations prior to and during treatment with KALYDECO to look for cataracts.
The most common side effects of KALYDECO include:
· headache
· upper respiratory tract infection (common cold), including:
o sore throat
o nasal or sinus congestion
o runny nose
· stomach (abdominal) pain
· diarrhea
· rash
· nausea
· dizziness
Tell your doctor if you have any side effect that bothers you or that does not go away.
These are not all the possible side effects of KALYDECO. For more information, ask your doctor or pharmacist.
Call your doctor for medical advice about side effects. You may report side effects to FDA at 1-800-FDA-1088.
How should I store KALYDECO?
· Store KALYDECO at room temperature between 68°F to 77°F (20°C to 25°C).
· Do not use KALYDECO after the expiration date on the package.
Keep KALYDECO and all medicines out of the reach of children.
General information about the safe and effective use of KALYDECO
Medicines are sometimes prescribed for purposes other than those listed in a Patient Information leaflet. Do not use KALYDECO for a condition for which it was not prescribed. Do not give KALYDECO to other people, even if they have the same symptoms you have. It may harm them.
This Patient Information summarizes the most important information about KALYDECO. If you would like more information, talk with your doctor. You can ask your pharmacist or doctor for information about KALYDECO that is written for health professionals.
For more information, go to www.kalydeco.com or call 1-877-752-5933.
What are the ingredients in KALYDECO?
Active ingredient: ivacaftor
Inactive ingredients:
KALYDECO Tablets are light blue, film-coated, capsule-shaped tablets for oral administration and contain the following inactive ingredients: colloidal silicon dioxide, croscarmellose sodium, hypromellose acetate succinate, lactose monohydrate, magnesium stearate, microcrystalline cellulose, and sodium lauryl sulfate.
The tablet film coat contains: carnauba wax, FD&C Blue #2, PEG 3350, polyvinyl alcohol, talc, and titanium dioxide.
The printing ink contains: ammonium hydroxide, iron oxide black, propylene glycol, and shellac.
KALYDECO Oral Granules are white to off-white granules for oral administration (sweetened but unflavored) and contain the following inactive ingredients: colloidal silicon dioxide, croscarmellose sodium, hypromellose acetate succinate, lactose monohydrate, magnesium stearate, mannitol, sucralose, and sodium lauryl sulfate.