通用中文 | 洛匹那韦利托那韦口服液 | 通用外文 | Lopinavir/ritonavir |
品牌中文 | 克力芝口服液 | 品牌外文 | Kaletra |
其他名称 | 武汉冠状病毒 武汉肺炎 新型冠状病毒 ALUVIA | ||
公司 | 艾伯维/雅培(Aberdeen / Abbott) | 产地 | 德国(Germany) |
含量 | (LOP80mg+RIT20mg)/ml,60ml/瓶 | 包装 | 5瓶/盒 |
剂型给药 | 液体 口服 | 储存 | 2度-8度(冰箱冷藏,禁止冷冻) |
适用范围 | Kaletra与其他抗逆转录病毒药物联合使用,可用于治疗感染人免疫缺陷病毒(HIV-1)的成人,青少年和14天及以上的儿童。 |
通用中文 | 洛匹那韦利托那韦口服液 |
通用外文 | Lopinavir/ritonavir |
品牌中文 | 克力芝口服液 |
品牌外文 | Kaletra |
其他名称 | 武汉冠状病毒 武汉肺炎 新型冠状病毒 ALUVIA |
公司 | 艾伯维/雅培(Aberdeen / Abbott) |
产地 | 德国(Germany) |
含量 | (LOP80mg+RIT20mg)/ml,60ml/瓶 |
包装 | 5瓶/盒 |
剂型给药 | 液体 口服 |
储存 | 2度-8度(冰箱冷藏,禁止冷冻) |
适用范围 | Kaletra与其他抗逆转录病毒药物联合使用,可用于治疗感染人免疫缺陷病毒(HIV-1)的成人,青少年和14天及以上的儿童。 |
1.药品名称
Kaletra(80毫克+ 20毫克)/毫升口服溶液
2.定性和定量组成
每1毫升Kaletra口服溶液含有80毫克洛匹那韦与20毫克利托那韦共同配制,作为药代动力学增强剂。
具有已知作用的辅料:
每1毫升含356.3毫克酒精(42.4%v / v),168.6毫克高果糖玉米糖浆,152.7毫克丙二醇(15.3%w / v)(请参阅第4.3节),10.2毫克聚氧乙烯40氢化蓖麻油和4.1毫克的乙酰磺胺酸钾(请参阅第4.4节)。
有关赋形剂的完整列表,请参见第6.1节。
3.药物形式
口服液
溶液为浅黄色至橙色。
4.临床细节
4.1治疗适应症
Kaletra与其他抗逆转录病毒药物联合使用,可用于治疗感染人免疫缺陷病毒(HIV-1)的成人,青少年和14天及以上的儿童。
选择Kaletra治疗蛋白酶抑制剂感染HIV-1的患者应根据个体的病毒抗药性测试和患者的治疗史(请参阅第4.4和5.1节)。
4.2给药方式和方法
Kaletra应该由具有HIV感染治疗经验的医生开具处方。
本体论
成人和青少年
推荐的Kaletra剂量为5毫升口服溶液(400/100毫克),每日两次与食物一起服用。
14天以上的儿童
根据儿童的体表面积或体重,口服溶液制剂是推荐给儿童的最准确剂量选择。但是,如果对于体重不足40千克或BSA在0.5至1.4平方米之间且能够吞咽片剂的儿童,有必要诉诸固体口服剂型,则可以使用100 mg / 25 mg Kaletra片剂。 Kaletra片剂的成人剂量(400/100 mg,每天两次)可用于40 kg或更大或体表面积(BSA)*大于1.4平方米的儿童。 Kaletra片剂经口服给药,必须完全吞咽且不能咀嚼,破碎或压碎。请参阅Kaletra 100 mg / 25 mg薄膜衣片产品特性摘要。
为了避免这些赋形剂产生毒性,应考虑将所有药物(包括Kaletra口服溶液)中的酒精和丙二醇的总量提供给婴儿(请参阅第4.4节)。
Paediatric dosing guidelines 2 weeks to 6 months |
||
Based on weight (mg/kg) |
Based on BSA (mg/m2)* |
Frequency |
16/4 mg/kg (corresponding to 0.2 ml/kg) |
300/75 mg/m2 (corresponding to 3.75 ml/m2) |
Given twice daily with food |
*身体表面积可通过以下公式计算
BSA(m2)=√(高度(cm)X重量(kg)/ 3600)
对于小于6个月的患者,建议不要将Kaletra与依非韦伦或奈韦拉平联合使用。
6个月以上至18岁以下小儿患者的剂量推荐
没有伴随的依法韦仑或奈韦拉平
下表包含基于体重和BSA的Kaletra口服溶液的剂量指南。
Paediatric dosing guidelines based on body weight* > 6 months to 18 years |
||
Body weight (kg) |
Twice daily oral solution dose (dose in mg/kg) |
Volume of oral solution twice daily taken with food (80 mg lopinavir/20 mg ritonavir per ml)** |
7 to < 15 kg 7 to 10 kg > 10 to < 15 kg |
12/3 mg/kg |
1.25 ml 1.75 ml |
≥ 15 to 40 kg 15 to 20 kg > 20 to 25 kg > 25 to 30 kg > 30 to 35 kg > 35 to 40 kg |
10/2.5 mg/kg |
2.25 ml 2.75 ml 3.50 ml 4.00 ml 4.75 ml |
≥ 40 kg |
See adult dosage recommendation |
*weight based dosing recommendations are based on limited data
** the volume (ml) of oral solution represents the average dose for the weight range
Paediatric dosing guidelines for the dose 230/57.5 mg/m2 > 6 months to < 18 years |
|
Body Surface Area* (m2) |
Twice daily oral solution dose (dose in mg) |
0.25 |
0.7 ml (57.5/14.4 mg) |
0.40 |
1.2 ml (96/24 mg) |
0.50 |
1.4 ml (115/28.8 mg) |
0.75 |
2.2 ml (172.5/43.1 mg) |
0.80 |
2.3 ml (184/46 mg) |
1.00 |
2.9 ml (230/57.5 mg) |
1.25 |
3.6 ml (287.5/71.9 mg) |
1.3 |
3.7 ml (299/74.8 mg) |
1.4 |
4.0 ml (322/80.5 mg) |
1.5 |
4.3 ml (345/86.3 mg) |
1.7 |
5 ml (402.5/100.6 mg) |
*Body surface area can be calculated with the following equation
BSA (m2) = √ (Height (cm) X Weight (kg) / 3600)
Concomitant Therapy: Efavirenz or Nevirapine
与奈韦拉平或依非韦伦合用时,某些孩子的230 / 57.5 mg / m2剂量可能不足。这些患者需要将Kaletra的剂量增加至300/75 mg / m2。不应超过每日两次的建议剂量533/133 mg或6.5 ml。
小于14天的儿童和早产儿
在婴儿的月经年龄(母亲最后一个月经的第一天加上出生后的时间)达到42周之前,并且已达到至少14天的出生后年龄,不得向婴儿服用Kaletra口服液(请参阅第4.4节) )。
肝功能不全
在患有轻度至中度肝功能不全的HIV感染患者中,已观察到洛匹那韦的暴露量增加了约30%,但预计没有临床意义(见5.2节)。没有严重肝功能不全患者的数据。不得将Kaletra给予这些患者(参见第4.3节)。
肾功能不全
由于洛匹那韦和利托那韦的肾脏清除率可以忽略不计,因此在肾功能不全患者中血浆浓度不会升高。由于洛匹那韦和利托那韦是高度蛋白质结合的,因此不太可能通过血液透析或腹膜透析将其显着去除。
给药方法
Kaletra口服给药,应始终与食物一起服用(请参阅第5.2节)。应使用最符合规定剂量的校准2毫升或5毫升口服剂量注射器进行给药。
4.3禁忌症
对活性物质或任何赋形剂过敏。
严重肝功能不全。
Kaletra含有洛匹那韦和利托那韦,两者均为P450亚型CYP3A的抑制剂。 Kaletra不应与高度依赖CYP3A进行清除且血浆浓度升高与严重和/或威胁生命的事件相关的药物共同给药。这些药品包括:
药品类别基本原理内的药品
伴随药品水平上升
Alpha1-肾上腺素受体拮抗剂阿夫唑嗪阿夫唑嗪的血浆浓度升高,可能导致严重的低血压。禁忌与阿夫唑嗪同时给药(见4.5节)。
抗心绞痛雷诺嗪雷诺嗪的血浆浓度升高,可能会增加发生严重和/或威胁生命的反应的可能性(请参阅第4.5节)。
抗心律失常药胺碘酮,决奈达隆胺碘酮和决奈达隆的血浆浓度升高。因此,增加了心律不齐或其他严重不良反应的风险(请参阅第4.5节)。
抗生素夫西地酸夫西地酸的血浆浓度增加。夫西地酸的同时使用在皮肤感染中是禁忌的(见4.5节)。
抗癌药物Neratinib升高的neratinib血浆浓度可能会增加发生严重和/或威胁生命的反应的可能性(请参阅第4.5节)。
Venetoclax增加了Venetoclax的血浆浓度。在剂量开始和上升阶段增加肿瘤溶解综合征的风险(请参阅第4.5节)。
抗痛风秋水仙碱秋水仙碱的血浆浓度增加。肾和/或肝功能不全患者发生严重和/或威胁生命的反应的可能性(请参阅第4.4和4.5节)。
抗组胺药阿司咪唑,特非那定血浆中阿司咪唑和特非那定的浓度增加。因此,增加了这些药物引起严重心律不齐的风险(请参阅第4.5节)。
抗精神病药/精神安定药Lurasidone血浆中Lurasidone的浓度升高,可能增加发生严重和/或危及生命的反应的可能性(请参阅第4.5节)。
Pimozide增加的血浆Pimozide浓度。因此,增加了该试剂引起严重血液学异常或其他严重不良反应的风险(请参阅第4.5节)。
喹硫平喹硫平的血浆浓度升高,可能导致昏迷。禁止与喹硫平同时使用(请参阅第4.5节)。
麦角生物碱二氢麦角胺,麦角新碱,麦角胺,甲基麦角新碱麦角衍生物的血浆浓度升高,导致急性麦角毒性,包括血管痉挛和局部缺血(请参阅第4.5节)。
胃肠动力药西沙必利增加西沙必利的血浆浓度。因此,增加了该药物引起严重心律不齐的风险(请参阅第4.5节)。
丙型肝炎病毒直接作用抗病毒药物Elbasvir / grazoprevir丙氨酸转氨酶(ALT)升高的风险增加(请参阅第4.5节)。
含或不含达沙布韦的Ombitasvir / paritaprevir / ritonavir帕拉曲韦的血浆浓度升高;因此,增加了丙氨酸转氨酶(ALT)升高的风险(请参阅第4.5节)。
脂质修饰剂
HMG Co-A还原酶抑制剂
洛伐他汀,辛伐他汀
洛伐他汀和辛伐他汀的血浆浓度升高;因此,增加了包括横纹肌溶解在内的肌病的风险(请参阅第4.5节)。
微粒体甘油三酸酯转移蛋白(MTTP)抑制剂Lomitapide增加Lomitapide的血浆浓度(请参阅第4.5节)。
磷酸二酯酶(PDE5)抑制剂Avanafil增加avanafil的血浆浓度(请参阅第4.4和4.5节)。
Sildenafil仅在用于治疗肺动脉高压(PAH)时禁忌。西地那非的血浆浓度升高。因此,增加了西地那非相关不良事件(包括低血压和晕厥)的可能性。西地那非在勃起功能障碍患者中的合用请参见第4.4节和第4.5节。
伐地那非的血浆血浆中伐地那非的浓度增加(参见第4.4和4.5节)
镇静剂/催眠药口服咪达唑仑,三唑仑增加口服咪达唑仑和三唑仑的血浆浓度。因此,增加了这些药物引起的极端镇静和呼吸抑制的风险。
肠胃外使用咪达唑仑的注意事项,请参见第4.5节。
洛匹那韦/利托那韦的药用水平下降
草药制品圣约翰草含有圣约翰草(贯叶连翘)的草药制剂,由于存在降低血浆中的洛匹那韦和利托那韦的浓度和风险的风险(见4.5节)。
怀孕
通常,在决定使用抗逆转录病毒药物治疗孕妇的HIV感染并因此降低HIV垂直传播至新生儿的风险时,应考虑孕妇的动物数据和临床经验以表征胎儿的安全性。
已在怀孕期间对3000例以上的妇女进行了洛匹那韦/利托那韦的评估,包括孕早期的1000例。
自1989年1月成立以来,通过抗逆转录病毒孕妇登记处进行的上市后监测显示,在孕早期暴露的1000多名妇女中,未发现Kaletra暴露有出生缺陷的风险增加。任何三个月的洛匹那韦暴露后,出生缺陷的患病率就与普通人群中的患病率相当。没有发现暗示常见病因的出生缺陷的模式。动物研究显示生殖毒性(请参阅第5.3节)。根据提到的数据,人类不太可能发生畸形风险。如果临床需要,可在怀孕期间使用洛匹那韦。
哺乳
对大鼠的研究表明,洛匹那韦可以从牛奶中排出。尚不知道这种药物是否会从人乳中排出。一般而言,建议在任何情况下都不要将被艾滋病毒感染的母亲母乳喂养婴儿,以避免艾滋病毒的传播。
生育能力
动物研究显示对生育力没有影响。没有关于洛匹那韦/利托那韦对生育力影响的人类数据。
4.7对驾驶和使用机器的能力的影响
尚未进行有关对驱动和使用机器的能力的影响的研究。应告知患者使用Kaletra治疗期间已报告恶心(请参阅第4.8节)。
Kaletra口服溶液包含约42%v / v酒精。
4.8不良影响
一种。安全概要摘要
在II-IV期临床试验中,已经对2600多名患者进行了Kaletra安全性研究,其中每天有700例患者接受800/200 mg(6胶囊或4片)剂量的Kaletra安全性。在一些研究中,将Kaletra与核苷逆转录酶抑制剂(NRTIs)结合使用,并与依非韦伦或奈韦拉平联用。
在临床试验中,与Kaletra治疗有关的最常见不良反应为腹泻,恶心,呕吐,高甘油三酯血症和高胆固醇血症。腹泻,恶心和呕吐可能在治疗开始时发生,而高甘油三酯血症和高胆固醇血症则可能在以后发生。治疗紧急不良事件导致II-IV期研究中有7%的受试者过早终止研究。
重要的是要注意,接受Kaletra的患者(包括发生高甘油三酯血症的患者)已有胰腺炎的报道。此外,据报道在Kaletra治疗期间PR间隔极少增加(见4.4节)。
b。不良反应列表
成人和小儿患者的临床试验和上市后的不良反应:
以下事件已被确认为不良反应。频率类别包括所有报告的中度到严重强度的事件,而不论个人因果关系评估如何。不良反应按系统器官分类显示。在每个频率组中,不良影响的严重程度从高到低依次为:非常常见(≥1/ 10),常见(≥1/100至<1/10),罕见(≥1/1000至<1/100)和稀有(≥1/ 10,000至<1/1000)。
成人患者在临床研究和上市后的不良影响
系统器官类别频率不良反应
感染和感染非常常见的上呼吸道感染
常见的下呼吸道感染,包括蜂窝织炎,毛囊炎和fur的皮肤感染
血液和淋巴系统疾病常见贫血,白细胞减少症,中性粒细胞减少症,淋巴结病
免疫系统疾病常见的超敏反应,包括荨麻疹和血管性水肿
罕见的免疫重建炎症综合征
内分泌失调罕见的性腺机能减退
代谢和营养失调常见的血糖失调包括糖尿病,高甘油三酯血症,高胆固醇血症,体重下降,食欲下降
体重异常增加,食欲增加
精神疾病常见焦虑症
罕见的异常梦,性欲下降
神经系统疾病常见头痛(包括偏头痛),神经病(包括周围神经病),头晕,失眠
罕见的脑血管意外,抽搐,消化不良,听觉异常,震颤
眼部疾病罕见的视力障碍
耳朵和迷路疾病罕见的耳鸣,眩晕
心脏疾病罕见的动脉粥样硬化,例如心肌梗塞1,房室传导阻滞,三尖瓣功能不全
血管疾病常见高血压
罕见的深静脉血栓形成
胃肠道疾病非常常见的腹泻,恶心
常见的胰腺炎1,呕吐,胃食管反流病,胃肠炎和结肠炎,腹痛(上下),腹胀,消化不良,痔疮,肠胃气胀
不常见的胃肠道出血,包括胃肠道溃疡,十二指肠炎,胃炎和直肠出血,口腔炎和口腔溃疡,大便失禁,便秘,口干
肝胆疾病常见的肝炎,包括AST,ALT和GGT升高
黄疸型肝脂肪变性,肝肿大,胆管炎,高胆红素血症不常见
皮肤和皮下组织疾病常见皮疹,包括斑丘疹,皮炎/皮疹,包括湿疹和脂溢性皮炎,盗汗,瘙痒
罕见的脱发,毛细血管炎,血管炎
罕见的史蒂文·约翰逊综合征,多形性红斑
肌肉骨骼和结缔组织疾病常见的肌痛,肌肉骨骼疼痛(包括关节痛和背痛),肌肉疾病(例如无力和痉挛)
罕见的横纹肌溶解,骨坏死
肾脏和泌尿系统疾病罕见的肌酐清除率降低,肾炎,血尿
生殖系统和乳房疾病常见的勃起功能障碍,月经失调-闭经,月经过多
一般疾病和给药部位疾病乏力等常见疲劳
1参见第4.4节:胰腺炎和脂质
C。所选不良反应的描述
据报道,接受利托那韦并吸入或经鼻给予丙酸氟替卡松的患者有库欣综合征。通过P450 3A途径代谢的其他皮质类固醇也可能发生这种情况,例如布地奈德(参见第4.4和4.5节)。
据报道,蛋白酶抑制剂,尤其是与核苷逆转录酶抑制剂联合使用时,肌酸磷酸激酶(CPK)增加,肌痛,肌炎,并且很少发生横纹肌溶解。
代谢参数
抗逆转录病毒治疗期间体重,血脂和葡萄糖水平可能会增加(请参阅第4.4节)。
在开始联合抗逆转录病毒疗法(CART)时,HIV感染的严重免疫缺陷患者可能会出现无症状或机会性感染的炎症反应。自身免疫性疾病(如格雷夫斯氏病和自身免疫性肝炎)也有报道。但是,报道的发病时间变化更大,并且可能在开始治疗后数月发生(请参阅第4.4节)。
已有骨坏死病例的报道,特别是在具有普遍公认的危险因素,晚期HIV疾病或长期接受联合抗逆转录病毒疗法(CART)的患者中。其频率未知(请参阅第4.4节)。
d。小儿人群
在14天及以上的儿童中,安全性的性质与成人相似(请参阅b节中的表)。
报告疑似不良反应
重要的是在药物授权后报告可疑的不良反应。它允许继续监视药品的利益/风险平衡。要求医疗保健专业人员通过黄卡计划报告任何可疑的不良反应:
网站:www.mhra.gov.uk/yellowcard或在Google Play或Apple App Store中搜索MHRA黄卡。
4.9过量
迄今为止,人们对使用Kaletra服用过量药物的经验有限。
据报道过量使用Kaletra口服溶液(包括致命结局)。据报道,以下事件与早产儿意外过量有关:完全房室传导阻滞,心肌病,乳酸性酸中毒和急性肾衰竭。
在犬中观察到的不良临床体征包括流涎,呕吐和腹泻/大便异常。在小鼠,大鼠或狗中观察到的毒性迹象包括活性降低,共济失调,消瘦,脱水和震颤。
没有针对Kaletra过量服用的解毒剂。用Kaletra治疗药物过量应包括一般支持措施,包括监测生命体征和观察患者的临床状况。如果指示,应通过呕吐或洗胃来消除未吸收的活性物质。活性炭的给药也可用于帮助除去未吸收的活性物质。由于Kaletra是高度蛋白质结合的,透析不太可能显着去除活性物质。
但是,如果过量服用Kaletra口服液,透析可以同时去除酒精和丙二醇。
5.药理特性
5.1药效学性质
药物治疗组:全身使用的抗病毒药,治疗HIV感染的抗病毒药,联合用药,ATC代码:J05AR10
作用机理
洛匹那韦提供了Kaletra的抗病毒活性。洛匹那韦是HIV-1和HIV-2蛋白酶的抑制剂。抑制HIV蛋白酶可防止gag-pol多蛋白的裂解,从而导致产生未感染的非感染性病毒。
对心电图的影响
在39名健康成人中,在一项随机,安慰剂和活性(莫西沙星400 mg每天一次)对照的交叉研究中评估QTcF间隔,在第3天的12小时内进行10次测量。安慰剂分别为每天两次400/100 mg和每天两次的超治疗800/200 mg LPV / r,分别为3.6(6.3)和13.1(15.8)。高剂量洛匹那韦/利托那韦(每天两次800/200 mg)引起的QRS间隔从6毫秒延长至9.5毫秒有助于QT延长。这两种方案在第3天导致的暴露分别比建议的每天一次或每天两次LPV / r稳态剂量建议的暴露量分别高1.5倍和3倍。没有受试者经历过从基线开始的QTcF增加≥60 ms或QTcF间隔超过500 ms的潜在临床相关阈值。
在第3天的同一研究中,接受lopinavir / ritonavir的受试者也注意到PR间隔的适度延长。给药后12小时间隔,PR间隔相对于基线的平均变化范围为11.6 ms至24.4 ms。最大PR间隔为286 ms,未观察到二级或三级心脏传导阻滞(请参阅第4.4节)。
体外抗病毒活性
在急性感染的淋巴细胞细胞系和外周血淋巴细胞中分别评估了洛匹那韦对实验室和临床HIV菌株的体外抗病毒活性。在没有人血清的情况下,洛匹那韦对五种不同HIV-1实验室菌株的平均IC50为19 nM。在不存在和存在50%的人血清的情况下,洛匹那韦在MT4细胞中针对HIV-1IIIB的平均IC50分别为17 nM和102 nM。在没有人血清的情况下,洛匹那韦对几种HIV-1临床分离株的平均IC50为6.5 nM。
抵抗性
在体外选择对洛匹那韦敏感性降低的HIV-1分离株。 HIV-1已通过洛匹那韦单独使用以及洛匹那韦加利托那韦以代表Kaletra治疗期间观察到的血浆浓度比范围的浓度比进行了体外传代。在这些段落中选择的病毒的基因型和表型分析表明,在这些浓度比下,利托那韦的存在不会显着影响耐洛匹那韦的病毒的选择。总体而言,洛匹那韦与其他蛋白酶抑制剂之间的表型交叉耐药性的体外表征表明,对洛匹那韦的敏感性降低与对利托那韦和茚地那韦的敏感性降低密切相关,但与对氨普那韦,沙奎那韦和奈非那韦的敏感性降低没有密切关系。
初次抗逆转录病毒治疗的患者的耐药性分析
在临床研究中,分析的分离物数量有限,在基线时没有明显蛋白酶抑制剂耐药性的未接受过治疗的患者中,未观察到对洛匹那韦的耐药性选择。进一步参见临床研究的详细描述。
有PI经验的患者的耐药性分析
通过分析2项II期和1项III期研究中19名有蛋白酶抑制剂经验的受试者的纵向分离株的特征,对在先蛋白酶抑制剂治疗失败的患者中对洛匹那韦的耐药性进行选择,这些受试者在初次反应后经历了不完全的病毒学抑制或病毒反弹Kaletra的研究,他证明了基线和反弹之间的体外抗药性增加(定义为出现新的突变或对洛匹那韦的表型敏感性增加了2倍)。在基线分离株具有几个蛋白酶抑制剂相关突变的受试者中,增量耐药是最常见的,但基线时对洛匹那韦的敏感性降低<40倍。突变V82A,I54V和M46I最常出现。还观察到突变L33F,I50V和V32I结合I47V / A。与基线分离物相比,这19种分离物的IC50值提高了4.3倍(与野生型病毒相比,从6.2倍增至43倍)。
基因型相关性降低了其他蛋白酶抑制剂选择的病毒对洛匹那韦的表型敏感性。评估了洛匹那韦对112种临床分离株的体外抗病毒活性,这些临床分离株来自用一种或多种蛋白酶抑制剂治疗无效的患者。在此面板中,HIV蛋白酶中的以下突变与洛匹那韦的体外敏感性降低有关:L10F / I / R / V,K20M / R,L24I,M46I / L,F53L,I54L / T / V,L63P,A71I / L / T / V,V82A / F / T,I84V和L90M。洛匹那韦对上述氨基酸位置具有0-3、4-5、6-7和8-10突变的分离株的EC50中值分别比野生型HIV的EC50高0.8、2.7、13.5和44.0倍。显示敏感性变化> 20倍的16种病毒均在第10、54、63、82和/或84位含有突变。此外,它们在第20、24、46、53位氨基酸的突变中位数为3分别是71和90。除了上述突变外,在接受Kaletra治疗的蛋白酶抑制剂患者中,洛匹那韦敏感性降低的反弹菌株中也观察到了突变V32I和I47A,在洛匹那韦降低的反弹菌株中观察到了突变I47A和L76V。接受Kaletra治疗的患者的易感性。
有关特定突变或突变模式相关性的结论可能会因其他数据而有所变化,建议始终咨询当前的解释系统以分析耐药性测试结果。
蛋白酶抑制剂治疗失败的患者中Kaletra的抗病毒活性
通过评估56名先前使用多种蛋白酶抑制剂治疗失败的患者对基线血液基因型和表型的Kaletra治疗的病毒学应答,研究了对洛匹那韦的体外敏感性降低的临床相关性。洛匹那韦对56种基线病毒分离株的EC50比对野生型HIV的EC50高0.6至96倍。用Kaletra,依非韦伦和核苷逆转录酶抑制剂治疗48周后,观察到93%(25/27),73%(11/15)和25%(2/8)的血浆HIV RNA≤400拷贝/ ml基线时,对洛匹那韦的敏感性分别降低了10倍,10到40倍和> 40倍的患者。另外,在上述突变的0-5、6-7和8-10突变的91%(21/23),71%(15/21)和33%(2/6)患者中观察到病毒学应答与蛋白酶蛋白酶减少有关的体外对洛匹那韦的敏感性降低。由于这些患者以前未曾接触过Kaletra或依非韦伦,因此部分反应可能归因于依非韦伦的抗病毒活性,特别是在携带高度洛匹那韦耐药性病毒的患者中。该研究不包含未接受Kaletra的患者的对照组。
交叉电阻
其他蛋白酶抑制剂对经过Kaletra治疗的蛋白酶抑制剂有经验的患者产生对洛匹那韦的耐药性增加的分离株的活性:在18个反弹分离株中分析了对其他蛋白酶抑制剂的交叉耐药性,这些分离物已证明在II期和3期对洛匹那韦具有耐药性的演变。 Kaletra在蛋白酶抑制剂经验丰富的患者中进行的一项III期研究。与野生型病毒相比,这18种分离株的洛匹那韦在基线和反弹时的IC50中位数分别为6.9倍和63倍。通常,反弹分离株要么保留(如果在基线交叉耐药),要么对茚地那韦,沙奎那韦和阿扎那韦产生显着的交叉耐药性。基线和反弹分离株的安普那韦活性适度下降,IC50的中值分别从3.7倍增加到8倍。与野生型病毒相比,分离物保留了对地普那韦的敏感性,基线和反弹分离物的IC50中值分别增加了1.9倍和1.8倍。有关使用替普那韦治疗lopinavir耐药HIV-1感染的详细信息,请参阅Aptivus产品特征摘要,包括使用替普那韦的反应,包括反应的基因型预测因子。
临床结果
在对Kaletra进行的48至360周的对照研究中,已经研究了Kaletra(与其他抗逆转录病毒药物联合使用)对生物学标记(血浆HIV RNA水平和CD4 + T细胞计数)的影响。
成人使用
未经抗逆转录病毒治疗的患者
研究M98-863是一项随机双盲试验,研究了653名初次接受抗逆转录病毒治疗的患者,研究了Kaletra(400/100 mg,每天两次)与奈非那韦(750 mg,每天3次)加司他夫定和拉米夫定的情况。 平均基线CD4 + T细胞计数为259细胞/ mm3(范围:2至949细胞/ mm3),平均基线血浆HIV-1 RNA为4.9 log10拷贝/毫升(范围:2.6至6.8 log10拷贝/毫升)。
*打算在认为值缺失的患者被认为是病毒学衰竭的情况下进行分析
M98-957是一项随机,开放标签的研究,评估了两种剂量水平(400/100 mg和533/133 mg,两者均每天两次)加依非韦伦(每天600 mg一次)和核苷逆转录酶抑制剂在57种多重蛋白酶中的Kaletra治疗 经验丰富的非核苷类逆转录酶抑制剂的初学者。 在第24周到第48周之间,将随机分配为400/100 mg剂量的患者转换为533/133 mg剂量。 基线CD4细胞计数中位数为220细胞/ mm3(范围为13至1030细胞/ mm3)。
Outcomes at Week 48: Study M98-863 |
||
|
Kaletra (N=326) |
Nelfinavir (N=327) |
HIV RNA < 400 copies/ml* |
75% |
63% |
HIV RNA < 50 copies/ml*† |
67% |
52% |
Mean increase from baseline in CD4+ T-cell count (cells/mm3) |
207 |
195 |
*打算在认为值缺失的患者被认为是病毒学崩溃的情况下进行分析
†p <0.001
从第24周到第96周的治疗期间,一百三十三名接受奈非那韦治疗的患者和74名洛匹那韦/利托那韦治疗的患者的HIV RNA均高于400拷贝/ ml 。其中,分离自96例奈非那韦治疗的患者和51洛匹那韦/利托那韦的分离株治疗后的患者可以进行反向性测试。在41/96(43%)患者中观察在0/51(0%)患者中观察到对洛匹那韦的识别性,定义为蛋白酶中存在任何主要或活性位点突变(见上文)。通过表型分析证实对洛匹那韦缺乏抗药性。
在一项小型的II期研究(M97-720)中,经过360周的治疗,还观察到了对Kaletra的持续病毒学应答(与核苷/核苷酸逆转录酶抑制剂联合使用)。最初在研究中用Kaletra治疗了100位患者(其中51位患者每天两次接受400/100 mg,49位患者每天两次接受200/100 mg或每天两次接受400/200 mg)。在第48周至第72位之间,所有患者均以400/100 mg每日两次的剂量转换为开放标签的Kaletra。39位患者(39%)中止了研究,其中16次(16%)因不良事件而中止,六十一名患者完成了研究(在整个研究过程中,三十五名患者接受了建议的400/100 mg每日两次剂量)。
Outcomes at Week 360: Study M97-720 |
|
|
Kaletra (N=100) |
HIV RNA < 400 copies/ml |
61% |
HIV RNA < 50 copies/ml |
59% |
Mean increase from baseline in CD4+ T-cell count (cells/mm3) |
501 |
经过360周的治疗,成功地对28例HIV RNA高于400拷贝/ ml的患者中的19例患者进行了病毒分离株的基因型分析,结果表明蛋白酶中没有初级或活性位点突变(第8、30、32、46位, 47、48、50、82、84和90)或蛋白酶抑制剂的表型抗性。
曾接受过抗逆转录病毒治疗的患者
M97-765是一项随机,双盲试验,在70种单一蛋白酶中以两种剂量水平(400/100 mg和400/200 mg,每天两次)加奈韦拉平(200 mg每天两次)和两种核苷逆转录酶抑制剂评估Kaletra 经验丰富的非核苷类逆转录酶抑制剂的初学者。 基线CD4细胞计数的中位数为349细胞/ mm3(范围为72至807细胞/ mm3),基线血浆HIV-1 RNA的中位数为4.0 log10拷贝/毫升(范围为2.9至5.8 log10拷贝/毫升)。
Outcomes at Week 24: Study M97-765 |
|
|
Kaletra 400/100 mg (N=36) |
HIV RNA < 400 copies/ml (ITT)* |
75% |
HIV RNA < 50 copies/ml (ITT)* |
58% |
Mean increase from baseline in CD4+ T-cell count (cells/mm3) |
174 |
*打算在认为值缺失的患者被认为是病毒学衰竭的情况下进行分析
M98-957是一项随机,开放标签的研究,评估了两种剂量水平(400/100 mg和533/133 mg,两者均每天两次)加依非韦伦(每天600 mg一次)和核苷逆转录酶抑制剂在57种多重蛋白酶中的Kaletra治疗 经验丰富的非核苷类逆转录酶抑制剂的初学者。 在第24周到第48周之间,将随机分配为400/100 mg剂量的患者转换为533/133 mg剂量。 基线CD4细胞计数中位数为220细胞/ mm3(范围为13至1030细胞/ mm3)。
表4
第48周的结果:研究M98-957
Kaletra 400/100毫克(N = 57)
HIV RNA <400拷贝/毫升* 65%
CD4 + T细胞计数相对于基线的平均增加(cells / mm3)94
*打算在认为值缺失的患者被认为是病毒学衰竭的情况下进行分析
小儿用药
M98-940是一项针对100例初次接受抗逆转录病毒治疗(44%)和经验丰富(56%)的小儿患者的Kaletra液体制剂的开放标签研究。所有患者均为非核苷类逆转录酶抑制剂。患者被随机分配至每平方米230 mg洛匹那韦/57.5 mg利托那韦或每平方米300 mg洛匹那韦/ 75 mg利托那韦。初次接受治疗的患者还接受了核苷逆转录酶抑制剂。经验丰富的患者接受奈韦拉平加最多两种核苷逆转录酶抑制剂。在每位患者治疗3周后,评估了两种剂量方案的安全性,疗效和药代动力学特征。随后,所有患者继续以每平方米300/75 mg的剂量服用。患者的平均年龄为5岁(6个月至12岁),其中14岁以下的患者小于2岁,6岁以下的患者为1岁以下。平均基线CD4 + T细胞计数为838细胞/ mm3,平均基线血浆HIV-1 RNA为4.7 log10拷贝/毫升。
表5
第48周的结果:研究M98-940 *
单纯抗逆转录病毒(N = 44)经历过抗逆转录病毒(N = 56)
HIV RNA <400拷贝/毫升84%75%
CD4 + T细胞计数相对于基线的平均增加量(cells / mm3)404284
*打算在认为值缺失的患者被认为是病毒学衰竭的情况下进行分析
研究P1030是一项开放性的剂量寻找试验,评估了在300毫克洛匹那韦/ 75毫克利托那韦/平方米的剂量下,每天两次两次对HIV-1感染婴儿的Kaletra口服溶液的药代动力学特征,耐受性,安全性和有效性,评估了Kaletra口服溶液≥14天且<6个月大。进入时,HIV-1 RNA的中位数(范围)为6.0(4.7-7.2)log10个拷贝/ ml,CD4 + T细胞百分比(范围)的中位数为41(16-59)。
表6
第24周的结果:研究P1030
年龄:≥14天且<6周
(N = 10)年龄:≥6周且<6个月
(N = 21)
HIV RNA <400拷贝/毫升* 70%48%
CD4 + T细胞计数(细胞/ mm3)与基线相比的中位数变化-1%(95%CI:-10,18)(n = 6)+ 4%(95%CI:-1,9)(n = 19 )
* HIV-1 <400拷贝/毫升并继续接受研究治疗的受试者比例
研究P1060是一项以奈韦拉平与洛匹那韦/利托那韦为基础的疗法的随机对照试验,研究对象为年龄在2至36个月的HIV-1感染者(队列I)和没有(队列II)在怀孕期间暴露于奈韦拉平以预防艾滋病毒母婴传播。对于2个月至<6个月的受试者,每天两次以16/4 mg / kg服用洛平那韦/利托那韦;对于≥6个月的受试者,每天12/3 mg / kg给药;对于<6 kg的受试者,<15 kg,10 / 2.5 mg / kg每天给药两次≥15 kg至<40 kg,或对于≥40 kg的受试者为400/100 mg。基于奈韦拉平的治疗方案是每天一次160-200 mg / m2,持续14天,然后每12小时160-200 mg / m2。两个治疗组均每12小时服用齐多夫定180 mg / m2,每12小时服用拉米夫定4 mg / kg。队列I的中位随访时间为48周,队列II的中位随访时间为72周。入院时,中位年龄为0.7岁,中位CD4 T细胞计数为1147细胞/ mm3,中位CD4 T细胞率为19%,中位HIV-1 RNA> 750,000拷贝/ ml。在洛匹那韦/利托那韦组的13例病毒衰竭患者中,有可用的耐药性数据,未发现对洛匹那韦/利托那韦具有耐药性。
表7
第24周的结果:研究P1060
第一代第二代
洛匹那韦/利托那韦
(N = 82)奈韦拉平
(N = 82)洛匹那韦/利托那韦
(N = 140)奈韦拉平
(N = 147)
病毒学衰竭* 21.7%39.6%19.3%40.8%
*定义为在24周后确诊的血浆HIV-1 RNA水平> 400拷贝/ ml或在第24周后病毒反弹> 4000拷贝/ ml。总体失败率结合各个年龄层的治疗差异,并按每次评估的准确性进行加权年龄阶层
p = 0.015(同类群组I); p <0.001(同类群组II)
CHER研究是一项随机,开放标签的研究,比较了围生期获得性HIV-1感染儿童的3种治疗策略(延期治疗,40周早期治疗或96周早期治疗)。治疗方案为齐多夫定加拉米夫定加300 mg洛匹那韦/ 75 mg利托那韦/天,每天两次,直到6个月大,然后是230 mg洛匹那韦/57.5 mg利托那韦/米,每天两次。没有因治疗限制毒性而导致失败的报道。
表8
相对于延误治疗的一线治疗死亡或失败的危险比:CHER研究
40周(N = 13)96周(N = 13)
死亡或治疗失败的危险比* 0.319 0.332
*失败定义为临床,免疫疾病进展,病毒学失败或限制ART毒性的方案
p = 0.0005(40周臂); p <0.0008(96周臂)
5.2药代动力学性质
已经在健康的成人志愿者和HIV感染的患者中评估了洛匹那韦与利托那韦合用的药代动力学特性。两组之间没有观察到实质性差异。 Lopinavir基本上被CYP3A代谢。利托那韦抑制洛匹那韦的代谢,从而增加洛匹那韦的血浆水平。在所有研究中,每天两次给予Kaletra 400/100 mg的剂量,在感染HIV的患者中,稳态lopinavir血浆浓度比ritonavir高15至20倍。利托那韦的血浆水平少于每天两次600 mg利托那韦剂量后获得的血浆水平的7%。洛匹那韦的体外抗病毒EC50比利托那韦低约10倍。因此,Kaletra的抗病毒活性归因于洛匹那韦。
吸收性
每天两次使用400/100 mg Kaletra连续2周进行多次给药,无进餐限制,可在给药后约4小时出现平均±SD洛匹那韦峰值血浆浓度(Cmax)为12.3±5.4μg/ ml。早晨剂量之前的平均稳态谷浓度为8.1±5.7μg/ ml。罗宾那韦AUC在12小时的给药间隔内平均为113.2±60.5μg•h / ml。与利托那韦共同配制的洛匹那韦在人体内的绝对生物利用度尚未确定。
食物对口服吸收的影响
Kaletra软胶囊和液体在非禁食条件下(中等脂肪餐)已显示出生物等效性。单次服用400/100 mg的Kaletra软胶囊和适量的脂肪餐(500 – 682 kcal,脂肪的22.7 – 25.1%)分别与洛匹那韦AUC和Cmax的平均分别增加48%和23% ,相对于禁食。对于Kaletra口服溶液,洛匹那韦AUC和Cmax的相应增加分别为80%和54%。高脂餐(872大卡,脂肪中55.8%)对Kaletra的管理,软胶囊洛匹那韦的AUC和Cmax分别增加96%和43%,口服溶液分别增加130%和56%。为了提高生物利用度并最大程度减少变异性,Kaletra将与食物一起服用。
分配
在稳态下,洛匹那韦与血清蛋白的结合率约为98-99%。洛匹那韦同时与α-1-酸糖蛋白(AAG)和白蛋白结合,但是它对AAG的亲和力更高。在稳定状态下,每日两次400/100 mg Kaletra后,lopinavir蛋白结合在观察到的浓度范围内保持恒定,并且在健康志愿者和HIV阳性患者之间相似。
生物转化
人肝微粒体的体外实验表明,洛匹那韦主要经历氧化代谢。洛匹那韦被肝细胞色素P450系统广泛代谢,几乎仅被同工酶CYP3A代谢。利托那韦是一种有效的CYP3A抑制剂,可抑制洛匹那韦的代谢并因此增加洛匹那韦的血浆水平。一项针对14C-lopinavir的人体研究表明,单次服用400/100 mg Kaletra剂量后,血浆放射性的89%归因于母体活性物质。人体中至少鉴定出13种lopinavir氧化代谢产物。 4-氧代和4-羟基代谢物差向异构体对是具有抗病毒活性的主要代谢产物,但仅占总血浆放射性的微量。已显示利托那韦可诱导代谢酶,从而诱导其自身的代谢,并可能诱导洛匹那韦的代谢。剂量前的洛匹那韦浓度在多次给药过程中随时间下降,在约10天至2周后稳定。
消除
在400/100 mg 14C-洛匹那韦/利托那韦剂量后,尿液和粪便中约占14C-洛匹那韦给药剂量的约10.4±2.3%和82.6±2.5%。不变的洛匹那韦在尿液和粪便中分别约占给药剂量的2.2%和19.8%。多次给药后,少于3%的lopinavir剂量原样排入尿液。洛匹那韦在12小时给药间隔内的有效(峰谷)半衰期平均为5-6小时,洛匹那韦的表观口服清除率(CL / F)为6至7 l / h。
特殊人群
儿科
来自2岁以下儿童的临床试验数据包括Kaletra 300/75 mg / m2的药代动力学,该药代动力学每天在总共31名儿科患者中进行两次研究,年龄从14天到6个月不等。在53名年龄在6个月至12岁的儿科患者中,研究了Kaletra 300/75 mg / m2每天两次与奈韦拉平和230 / 57.5 mg / m2每天单独两次的药代动力学。下表中列出了研究的平均值(SD)。不使用奈韦拉平的每日两次230 / 57.5 mg / m2方案和使用奈韦拉平的每日两次300/75 mg / m2方案提供的洛匹那韦血浆浓度与接受不使用奈韦拉平的每日两次400/100 mg的成年患者所获得的血浆血浆浓度相似。
Cmax(μg/ ml)Cmin(μg/ ml)AUC12(μg•h / ml)
年龄≥14天到<6周队列(N = 9):
5.17(1.84)1.40(0.48)43.39(14.80)
年龄≥6周至<6个月队列(N = 18):
9.39(4.91)1.95(1.80)74.50(37.87)
年龄≥6个月至<12岁队列(N = 53):
8.2(2.9)a 3.4(2.1)a 72.6(31.1)a
10.0(3.3)b 3.6(3.5)b 85.8(36.9)b
成人
12.3(5.4)8.1(5.7)113.2(60.5)
一种。 Kaletra口服溶液230 / 57.5 mg / m2每天两次,无奈韦拉平
b。 Kaletra口服溶液300/75 mg / m2每天两次使用奈韦拉平
C。 Kaletra薄膜衣片400/100毫克,每天两次,稳定状态
性别,种族和年龄
尚未在老年人中研究过Kaletra的药代动力学。在成年患者中未观察到年龄或性别相关的药代动力学差异。由于种族引起的药代动力学差异尚未确定。
肾功能不全
对于肾功能不全的患者,尚未研究Kaletra药代动力学。但是,由于洛匹那韦的肾脏清除率可以忽略不计,因此预期肾功能不全患者的全身清除率不会降低。
肝功能不全
在每天两次两次使用lopinavir / ritonavir 400/100 mg进行的多剂量研究中,将洛匹那韦在轻度至中度肝功能不全的HIV感染患者中的稳态药代动力学参数与肝功能正常的HIV感染患者的稳态药物动力学参数进行了比较。已观察到洛匹那韦的总浓度有有限的增加,大约增加了30%,这与临床无关(见4.2节)。
5.3临床前安全数据
在啮齿动物和狗中进行的重复剂量毒性研究确定了主要的靶器官为肝,肾,甲状腺,脾脏和循环中的红细胞。肝脏变化表明细胞肿胀伴局灶性变性。虽然引起这些变化的暴露量与人类临床暴露量相当或低于人类临床暴露量,但动物中的剂量是推荐临床剂量的6倍以上。轻度肾小管变性仅限于暴露于建议人类暴露量至少两倍的小鼠。肾脏在大鼠和狗中均未受影响。血清甲状腺素降低导致大鼠甲状腺中TSH释放增加,并导致卵泡细胞肥大。撤回活性物质后这些变化是可逆的,而在小鼠和狗中则不存在。在大鼠中观察到了库姆氏阴性的异细胞增多和单核细胞增多,但在小鼠或狗中却没有。在大鼠中发现脾脏肿大并伴有组织细胞增多,但未见其他物种。啮齿动物的血清胆固醇升高,但狗没有升高,而甘油三酸酯仅在小鼠中升高。
在体外研究期间,在测试的洛匹那韦/利托那韦的最高浓度下,克隆的人心脏钾通道(HERG)被抑制30%,相当于洛匹那韦暴露于人体在7倍的总血浆总水平和7倍的自由峰水平。推荐的最大治疗剂量。相反,相似浓度的洛匹那韦/利托那韦在犬心脏浦肯野纤维中无复极化延迟。较低的洛匹那韦/利托那韦浓度未产生明显的钾(HERG)电流阻滞作用。在大鼠中进行的组织分布研究并未显示出该活性物质在心脏上的明显滞留。心脏中的72小时AUC约为所测血浆AUC的50%。因此,可以合理预期心脏洛匹那韦水平不会明显高于血浆水平。
在犬中,观察到心电图上显着的U波与延长的PR间隔和心动过缓有关。假定这些影响是由电解质干扰引起的。
这些临床前数据的临床相关性尚不清楚,但是,不能排除该产品对人类的潜在心脏效应(另请参见第4.4和4.8节)。
在大鼠中,在母体毒性剂量下,观察到了胚叶毒性(怀孕损失,胎儿生存力降低,胎儿体重降低,骨骼变异频率增加)和产后发育毒性(幼崽存活率降低)。母体和发育毒性剂量的洛匹那韦/利托那韦的全身暴露低于人体预期的治疗暴露。
洛匹那韦/利托那韦在小鼠中的长期致癌性研究表明,肝肿瘤具有非遗传毒性,促有丝分裂诱导作用,通常认为与人类风险无关。大鼠的致癌性研究未发现致瘤性的发现。在一系列体外和体内试验(包括Ames细菌反向突变试验,小鼠淋巴瘤试验,小鼠微核试验和人淋巴细胞中的染色体畸变试验)中,未发现洛匹那韦/利托那韦具有致突变性或致死性。
6.药物特性
6.1辅料清单
口服溶液包含:
酒精(42.4%v / v),
高果糖玉米糖浆,
丙二醇(15.3%w / v),
净化水,
甘油
聚维酮
magnasweet-110风味剂(甘草酸一铵和甘油的混合物),
香草味(含有对羟基苯甲酸,对羟基苯甲醛,香草酸,香草醛,促肾上腺素,乙基香草醛),
聚氧乙烯40氢化蓖麻油,
棉花糖调味剂(包含乙基麦芽酚,乙基香兰素,乙酰丙酮,二氢香豆素,丙二醇),
乙磺胺钾,
糖精钠
氯化钠,
薄荷油,
柠檬酸钠,
柠檬酸,
左脑薄荷醇。
6.2不兼容
不适用。
6.3保质期
2年
6.4特殊的储存注意事项
存放在冰箱(2°C-8°C)中。
在使用中的存储:如果保存在冰箱外面,请不要在25°C以上的温度下存储,并在42天(6周)后丢弃所有未使用的物品。建议在包装上写明从冰箱取出的日期。
6.5容器的性质和内容
Kaletra口服溶液以60毫升大小的琥珀色多剂量聚对苯二甲酸乙二醇酯(PET)瓶提供。
Kaletra口服液有两种包装规格:
-120毫升(2瓶x 60毫升)和2个2毫升注射器(0.1毫升刻度)
容量最大为2 ml。对于较大的数量,可以使用备用包装。
-300毫升(5瓶x 60毫升)和5 x 5毫升注射器,0.1毫升刻度
对于大于2 ml的体积。对于较小的体积,可以使用备用包装。
6.6处置和其他处置的特殊预防措施
无特殊要求。
7.营销授权持有人
艾伯维德国有限公司
诺尔大街
67061路德维希港
德国
8.营销授权号
欧盟/ 1/01/172/003
欧盟/ 1/01/172/009
9.首次授权日期/授权续期
首次授权日期:2001年3月20日
最新续订日期:2011年3月20日
10.文本的修订日期
2019年10月31日
有关该产品的详细信息,请访问欧洲药品管理局的网站http://www.ema.europa.eu
公司联系方式
艾伯维有限公司
地址
英国,伯克希尔,梅登黑德,凡华路,凡华商业园AbbVie House,SL6 4UB,英国
AbbVie Ltd contact details
Active ingredient
ritonavir
lopinavir
1. Name of the medicinal product
Kaletra (80 mg + 20 mg) / ml oral solution
2. Qualitative and quantitative composition
Each 1 ml of Kaletra oral solution contains 80 mg of lopinavir co-formulated with 20 mg of ritonavir as a pharmacokinetic enhancer.
Excipients with known effect:
Each 1 ml contains 356.3 mg of alcohol (42.4% v/v), 168.6 mg of high fructose corn syrup, 152.7 mg of propylene glycol (15.3% w/v) (see section 4.3), 10.2 mg of polyoxyl 40 hydrogenated castor oil and 4.1 mg of acesulfame potassium (see section 4.4).
For the full list of excipients, see section 6.1.
3. Pharmaceutical form
Oral solution
The solution is light yellow to orange.
4. Clinical particulars
4.1 Therapeutic indications
Kaletra is indicated in combination with other antiretroviral medicinal products for the treatment of human immunodeficiency virus (HIV-1) infected adults, adolescents and children aged from 14 days and older.
The choice of Kaletra to treat protease inhibitor experienced HIV-1 infected patients should be based on individual viral resistance testing and treatment history of patients (see sections 4.4 and 5.1).
4.2 Posology and method of administration
Kaletra should be prescribed by physicians who are experienced in the treatment of HIV infection.
Posology
Adults and adolescents
The recommended dosage of Kaletra is 5 ml of oral solution (400/100 mg) twice daily taken with food.
Paediatric population aged from 14 days and older
The oral solution formulation is the recommended option for the most accurate dosing in children based on body surface area or body weight. However, if it is judged necessary to resort to solid oral dosage form for children weighing less than 40 kg or with a BSA between 0.5 and 1.4 m2and able to swallow tablets, Kaletra 100 mg/25 mg tablets may be used. The adult dose of Kaletra tablets (400/100 mg twice daily) may be used in children 40 kg or greater or with a Body Surface Area (BSA)* greater than 1.4 m2. Kaletra tablets are administered orally and must be swallowed whole and not chewed, broken or crushed. Please refer to the Kaletra 100 mg/25 mg film-coated tablets Summary of Product Characteristics.
Total amounts of alcohol and propylene glycol from all medicines, including Kaletra oral solution, that are to be given to infants should be taken into account in order to avoid toxicity from these excipients (see section 4.4).
Dosage recommendation for paediatric patients aged from 14 days to 6 months
Paediatric dosing guidelines 2 weeks to 6 months |
||
Based on weight (mg/kg) |
Based on BSA (mg/m2)* |
Frequency |
16/4 mg/kg (corresponding to 0.2 ml/kg) |
300/75 mg/m2 (corresponding to 3.75 ml/m2) |
Given twice daily with food |
*Body surface area can be calculated with the following equation
BSA (m2) = √ (Height (cm) X Weight (kg) / 3600)
It is recommended that Kaletra not be administered in combination with efavirenz or nevirapine in patients less than 6 months of age.
Dosage recommendation for paediatric patients older than 6 months to less than 18 years
Without Concomitant Efavirenz or Nevirapine
The following tables contain dosing guidelines for Kaletra oral solution based on body weight and BSA.
Paediatric dosing guidelines based on body weight* > 6 months to 18 years |
||
Body weight (kg) |
Twice daily oral solution dose (dose in mg/kg) |
Volume of oral solution twice daily taken with food (80 mg lopinavir/20 mg ritonavir per ml)** |
7 to < 15 kg 7 to 10 kg > 10 to < 15 kg |
12/3 mg/kg |
1.25 ml 1.75 ml |
≥ 15 to 40 kg 15 to 20 kg > 20 to 25 kg > 25 to 30 kg > 30 to 35 kg > 35 to 40 kg |
10/2.5 mg/kg |
2.25 ml 2.75 ml 3.50 ml 4.00 ml 4.75 ml |
≥ 40 kg |
See adult dosage recommendation |
*weight based dosing recommendations are based on limited data
** the volume (ml) of oral solution represents the average dose for the weight range
Paediatric dosing guidelines for the dose 230/57.5 mg/m2 > 6 months to < 18 years |
|
Body Surface Area* (m2) |
Twice daily oral solution dose (dose in mg) |
0.25 |
0.7 ml (57.5/14.4 mg) |
0.40 |
1.2 ml (96/24 mg) |
0.50 |
1.4 ml (115/28.8 mg) |
0.75 |
2.2 ml (172.5/43.1 mg) |
0.80 |
2.3 ml (184/46 mg) |
1.00 |
2.9 ml (230/57.5 mg) |
1.25 |
3.6 ml (287.5/71.9 mg) |
1.3 |
3.7 ml (299/74.8 mg) |
1.4 |
4.0 ml (322/80.5 mg) |
1.5 |
4.3 ml (345/86.3 mg) |
1.7 |
5 ml (402.5/100.6 mg) |
*Body surface area can be calculated with the following equation
BSA (m2) = √ (Height (cm) X Weight (kg) / 3600)
Concomitant Therapy: Efavirenz or Nevirapine
The 230/57.5 mg/m2 dosage might be insufficient in some children when co-administered with nevirapine or efavirenz. An increase of the dose of Kaletra to 300/75 mg/m2 is needed in these patients. The recommended dose of 533/133 mg or 6.5 ml twice daily should not be exceeded.
Children less than 14 days of age and premature neonates
Kaletra oral solution should not be administered to neonates before a postmenstrual age (first day of the mother's last menstrual period to birth plus the time elapsed after birth) of 42 weeks and a postnatal age of at least 14 days has been reached (see section 4.4).
Hepatic impairment
In HIV-infected patients with mild to moderate hepatic impairment, an increase of approximately 30% in lopinavir exposure has been observed but is not expected to be of clinical relevance (see section 5.2). No data are available in patients with severe hepatic impairment. Kaletra must not be given to these patients (see section 4.3).
Renal impairment
Since the renal clearance of lopinavir and ritonavir is negligible, increased plasma concentrations are not expected in patients with renal impairment. Because lopinavir and ritonavir are highly protein bound, it is unlikely that they will be significantly removed by haemodialysis or peritoneal dialysis.
Method of administration
Kaletra is administered orally and should always be taken with food (see section 5.2). The dose should be administered using a calibrated 2 ml or 5 ml oral dosing syringe best corresponding to the volume prescribed.
4.3 Contraindications
Hypersensitivity to the active substances or to any of the excipients.
Severe hepatic insufficiency.
Kaletra contains lopinavir and ritonavir, both of which are inhibitors of the P450 isoform CYP3A. Kaletra should not be co-administered with medicinal products that are highly dependent on CYP3A for clearance and for which elevated plasma concentrations are associated with serious and/or life threatening events. These medicinal products include:
Medicinal product class |
Medicinal products within class |
Rationale |
Concomitant medicinal product levels increased |
||
Alpha1-adrenoreceptor antagonist |
Alfuzosin |
Increased plasma concentrations of alfuzosin which may lead to severe hypotension. The concomitant administration with alfuzosin is contraindicated (see section 4.5). |
Antianginal |
Ranolazine |
Increased plasma concentrations of ranolazine which may increase the potential for serious and/or life-threatening reactions (see section 4.5). |
Antiarrhythmics |
Amiodarone, dronedarone |
Increased plasma concentrations of amiodarone and dronedarone. Thereby, increasing the risk of arrhythmias or other serious adverse reactions (see section 4.5). |
Antibiotic |
Fusidic Acid |
Increased plasma concentrations of fusidic acid. The concomitant administration with fusidic acid is contraindicated in dermatological infections (see section 4.5). |
Anticancer |
Neratinib |
Increased plasma concentrations of neratinib which may increase the potential for serious and/or life-threatening reactions (see section 4.5). |
|
Venetoclax |
Increased plasma concentrations of venetoclax. Increased risk of tumor lysis syndrome at the dose initiation and during the ramp-up phase (see section 4.5). |
Anti-gout |
Colchicine |
Increased plasma concentrations of colchicine. Potential for serious and/or life-threatening reactions in patients with renal and/or hepatic impairment (see sections 4.4 and 4.5). |
Antihistamines |
Astemizole, terfenadine |
Increased plasma concentrations of astemizole and terfenadine. Thereby, increasing the risk of serious arrhythmias from these agents (see section 4.5). |
Antipsychotics/ Neuroleptics |
Lurasidone |
Increased plasma concentrations of lurasidone which may increase the potential for serious and/or life-threatening reactions (see section 4.5). |
Pimozide |
Increased plasma concentrations of pimozide. Thereby, increasing the risk of serious haematologic abnormalities, or other serious adverse effects from this agent (see section 4.5). |
|
Quetiapine |
Increased plasma concentrations of quetiapine which may lead to coma. The concomitant administration with quetiapine is contraindicated (see section 4.5). |
|
Ergot alkaloids |
Dihydroergotamine, ergonovine, ergotamine, methylergonovine |
Increased plasma concentrations of ergot derivatives leading to acute ergot toxicity, including vasospasm and ischaemia (see section 4.5). |
GI motility agent |
Cisapride |
Increased plasma concentrations of cisapride. Thereby, increasing the risk of serious arrhythmias from this agent (see section 4.5). |
Hepatitis C virus direct acting antivirals |
Elbasvir/grazoprevir |
Increased risk of alanine transaminase (ALT) elevations (see section 4.5). |
Ombitasvir/paritaprevir/ritonavir with or without dasabuvir |
Increased plasma concentrations of paritaprevir; thereby, increasing the risk of alanine transaminase (ALT) elevations (see section 4.5). |
|
Lipid-modifying agents HMG Co-A Reductase Inhibitors |
Lovastatin, simvastatin |
Increased plasma concentrations of lovastatin and simvastatin; thereby, increasing the risk of myopathy including rhabdomyolysis (see section 4.5). |
Microsomal triglyceride transfer protein (MTTP) inhibitor |
Lomitapide |
Increased plasma concentrations of lomitapide (see section 4.5). |
Phosphodiesterase (PDE5) inhibitors |
Avanafil |
Increased plasma concentrations of avanafil (see sections 4.4 and 4.5). |
Sildenafil |
Contraindicated when used for the treatment of pulmonary arterial hypertension (PAH) only. Increased plasma concentrations of sildenafil. Thereby, increasing the potential for sildenafil-associated adverse events (which include hypotension and syncope). See section 4.4 and section 4.5 for co-administration of sildenafil in patients with erectile dysfunction. |
|
Vardenafil |
Increased plasma concentrations of vardenafil (see sections 4.4 and 4.5) |
|
Sedatives/hypnotics |
Oral midazolam, triazolam |
Increased plasma concentrations of oral midazolam and triazolam. Thereby, increasing the risk of extreme sedation and respiratory depression from these agents. For caution on parenterally administered midazolam, see section 4.5. |
Lopinavir/ritonavir medicinal product level decreased |
||
Herbal products |
St. John's wort |
Herbal preparations containing St John's wort (Hypericum perforatum) due to the risk of decreased plasma concentrations and reduced clinical effects of lopinavir and ritonavir (see section 4.5). |
Kaletra oral solution is contraindicated in children below the age of 14 days, pregnant women, patients with hepatic or renal failure and patients treated with disulfiram or metronidazole due to the potential risk of toxicity from the excipient propylene glycol (see section 4.4).
4.4 Special warnings and precautions for use
Patients with coexisting conditions
Hepatic impairment
The safety and efficacy of Kaletra has not been established in patients with significant underlying liver disorders. Kaletra is contraindicated in patients with severe liver impairment (see section 4.3). Patients with chronic hepatitis B or C and treated with combination antiretroviral therapy are at an increased risk for severe and potentially fatal hepatic adverse reactions. In case of concomitant antiviral therapy for hepatitis B or C, please refer to the relevant product information for these medicinal products.
Patients with pre-existing liver dysfunction including chronic hepatitis have an increased frequency of liver function abnormalities during combination antiretroviral therapy and should be monitored according to standard practice. If there is evidence of worsening liver disease in such patients, interruption or discontinuation of treatment should be considered.
Elevated transaminases with or without elevated bilirubin levels have been reported in HIV-1 mono-infected and in individuals treated for post-exposure prophylaxis as early as 7 days after the initiation of lopinavir/ritonavir in conjunction with other antiretroviral agents. In some cases the hepatic dysfunction was serious.
Appropriate laboratory testing should be conducted prior to initiating therapy with lopinavir/ritonavir and close monitoring should be performed during treatment.
Renal impairment
Since the renal clearance of lopinavir and ritonavir is negligible, increased plasma concentrations are not expected in patients with renal impairment. Because lopinavir and ritonavir are highly protein bound, it is unlikely that they will be significantly removed by haemodialysis or peritoneal dialysis.
Haemophilia
There have been reports of increased bleeding, including spontaneous skin haematomas and haemarthrosis in patients with haemophilia type A and B treated with protease inhibitors. In some patients additional factor VIII was given. In more than half of the reported cases, treatment with protease inhibitors was continued or reintroduced if treatment had been discontinued. A causal relationship had been evoked, although the mechanism of action had not been elucidated. Haemophiliac patients should therefore be made aware of the possibility of increased bleeding.
Pancreatitis
Cases of pancreatitis have been reported in patients receiving Kaletra, including those who developed hypertriglyceridaemia. In most of these cases patients have had a prior history of pancreatitis and/or concurrent therapy with other medicinal products associated with pancreatitis. Marked triglyceride elevation is a risk factor for development of pancreatitis. Patients with advanced HIV disease may be at risk of elevated triglycerides and pancreatitis.
Pancreatitis should be considered if clinical symptoms (nausea, vomiting, abdominal pain) or abnormalities in laboratory values (such as increased serum lipase or amylase values) suggestive of pancreatitis should occur. Patients who exhibit these signs or symptoms should be evaluated and Kaletra therapy should be suspended if a diagnosis of pancreatitis is made (see section 4.8).
Immune Reconstitution Inflammatory Syndrome
In HIV-infected patients with severe immune deficiency at the time of institution of combination antiretroviral therapy (CART), an inflammatory reaction to asymtomatic or residual opportunistic pathogens may arise and cause serious clinical conditions, or aggravation of symptoms. Typically, such reactions have been observed within the first few weeks or months of initiation of CART. Relevant examples are cytomegalovirus retinitis, generalised and/or focal mycobacterial infections, andPneumocystis jiroveci pneumonia. Any inflammatory symptoms should be evaluated and treatment instituted when necessary.
Autoimmune disorders (such as Graves' disease and autoimmune hepatitis) have also been reported to occur in the setting of immune reconstitution; however, the reported time to onset is more variable and can occur many months after initiation of treatment.
Osteonecrosis
Although the etiology is considered to be multifactorial (including corticosteroid use, alcohol consumption, severe immunosuppression, higher body mass index), cases of osteonecrosis have been reported particularly in patients with advanced HIV-disease and/or long-term exposure to combination antiretroviral therapy (CART). Patients should be advised to seek medical advice if they experience joint aches and pain, joint stiffness or difficulty in movement.
PR interval prolongation
Lopinavir/ritonavir has been shown to cause modest asymptomatic prolongation of the PR interval in some healthy adult subjects. Rare reports of 2nd or 3rd degree atroventricular block in patients with underlying structural heart disease and pre-existing conduction system abnormalities or in patients receiving drugs known to prolong the PR interval (such as verapamil or atazanavir) have been reported in patients receiving lopinavir/ritonavir. Kaletra should be used with caution in such patients (see section 5.1).
Weight and metabolic parameters
An increase in weight and in levels of blood lipids and glucose may occur during antiretroviral therapy. Such changes may in part be linked to disease control and life style. For lipids, there is in some cases evidence for a treatment effect, while for weight gain there is no strong evidence relating this to any particular treatment. For monitoring of blood lipids and glucose, reference is made to established HIV treatment guidelines. Lipid disorders should be managed as clinically appropriate.
Interactions with medicinal products
Kaletra contains lopinavir and ritonavir, both of which are inhibitors of the P450 isoform CYP3A. Kaletra is likely to increase plasma concentrations of medicinal products that are primarily metabolised by CYP3A. These increases of plasma concentrations of co-administered medicinal products could increase or prolong their therapeutic effect and adverse events (see sections 4.3 and 4.5).
Strong CYP3A4 inhibitors such as protease inhibitors may increase bedaquiline exposure which could potentially increase the risk of bedaquiline-related adverse reactions. Therefore, combination of bedaquiline with lopinavir/ritonavir should be avoided. However, if the benefit outweighs the risk, co-administration of bedaquiline with lopinavir/ritonavir must be done with caution. More frequent electrocardiogram monitoring and monitoring of transaminases is recommended (see section 4.5 and refer to the bedaquiline SmPC).
Co-administration of delamanid with a strong inhibitor of CYP3A (as lopinavir/ritonavir) may increase exposure to delamanid metabolite, which has been associated with QTc prolongation. Therefore, if co-administration of delamanid with lopinavir/ritonavir is considered necessary, very frequent ECG monitoring throughout the full delamanid treatment period is recommended (see section 4.5 and refer to the delamanid SmPC).
Life-threatening and fatal drug interactions have been reported in patients treated with colchicine and strong inhibitors of CYP3A like ritonavir. Concomitant administration with colchicine is contraindicated in patients with renal and/or hepatic impairment (see sections 4.3 and 4.5).
The combination of Kaletra with:
- tadalafil, indicated for the treatment of pulmonary arterial hypertension, is not recommended (see section 4.5);
- riociguat is not recommended (see section 4.5);
- vorapaxar is not recommended (see section 4.5);
- fusidic acid in osteo-articular infections is not recommended (see section 4.5);
- salmeterol is not recommended (see section 4.5);
- rivaroxaban is not recommended (see section 4.5).
The combination of Kaletra with atorvastatin is not recommended. If the use of atorvastatin is considered strictly necessary, the lowest possible dose of atorvastatin should be administered with careful safety monitoring. Caution must also be exercised and reduced doses should be considered if Kaletra is used concurrently with rosuvastatin. If treatment with an HMG-CoA reductase inhibitor is indicated, pravastatin or fluvastatin is recommended (see section 4.5).
PDE5 inhibitors
Particular caution should be used when prescribing sildenafil or tadalafil for the treatment of erectile dysfunction in patients receiving Kaletra. Co-administration of Kaletra with these medicinal products is expected to substantially increase their concentrations and may result in associated adverse events such as hypotension, syncope, visual changes and prolonged erection (see section 4.5). Concomitant use of avanafil or vardenafil and lopinavir/ritonavir is contraindicated (see section 4.3). Concomitant use of sildenafil prescribed for the treatment of pulmonary arterial hypertension with Kaletra is contraindicated (see section 4.3).
Particular caution must be used when prescribing Kaletra and medicinal products known to induce QT interval prolongation such as: chlorpheniramine, quinidine, erythromycin, clarithromycin. Indeed, Kaletra could increase concentrations of the co-administered medicinal products and this may result in an increase of their associated cardiac adverse reactions. Cardiac events have been reported with Kaletra in preclinical studies; therefore, the potential cardiac effects of Kaletra cannot be currently ruled out (see sections 4.8 and 5.3).
Co-administration of Kaletra with rifampicin is not recommended. Rifampicin in combination with Kaletra causes large decreases in lopinavir concentrations which may in turn significantly decrease the lopinavir therapeutic effect. Adequate exposure to lopinavir/ritonavir may be achieved when a higher dose of Kaletra is used but this is associated with a higher risk of liver and gastrointestinal toxicity. Therefore, this co-administration should be avoided unless judged strictly necessary (see section 4.5).
Concomitant use of Kaletra and fluticasone or other glucocorticoids that are metabolised by CYP3A4, such as budesonide and triamcinolone, is not recommended unless the potential benefit of treatment outweighs the risk of systemic corticosteroid effects, including Cushing's syndrome and adrenal suppression (see section 4.5).
Other
Patients taking the oral solution, particularly those with renal impairment or with decreased ability to metabolise propylene glycol (e.g. those of Asian origin), should be monitored for adverse reactions potentially related to propylene glycol toxicity (i.e. seizures, stupor, tachycardia, hyperosmolarity, lactic acidosis, renal toxicity, haemolysis) (see section 4.3).
Kaletra is not a cure for HIV infection or AIDS. While effective viral suppression with antiretroviral therapy has been proven to substantially reduce the risk of sexual transmission, a residual risk cannot be excluded. Precautions to prevent transmission should be taken in accordance with national guidelines. People taking Kaletra may still develop infections or other illnesses associated with HIV disease and AIDS.
Besides propylene glycol as described above, Kaletra oral solution contains alcohol (42% v/v) which is potentially harmful for those suffering from liver disease, alcoholism, epilepsy, brain injury or disease as well as for pregnant women and children. It may modify or increase the effects of other medicines. Kaletra oral solution contains up to 0.8 g of fructose per dose when taken according to the dosage recommendations. This may be unsuitable in hereditary fructose intolerance. Kaletra oral solution contains up to 0.3 g of glycerol per dose. Only at high inadvertent doses, it can cause headache and gastrointestinal upset. Furthermore, polyoxol 40 hydrogenated castor oil and potassium present in Kaletra oral solution may cause only at high inadvertent doses gastrointestinal upset. Patients on a low potassium diet should be cautioned.
Particular risk of toxicity in relation to the amount of alcohol and propylene glycol contained in Kaletra oral solution
Healthcare professionals should be aware that Kaletra oral solution is highly concentrated and contains 42.4% alcohol (v/v) and 15.3% propylene glycol (w/v). Each 1 ml of Kaletra oral solution contains 356.3 mg of alcohol and 152.7 mg of propylene glycol.
Special attention should be given to accurate calculation of the dose of Kaletra, transcription of the medication order, dispensing information and dosing instructions to minimize the risk for medication errors and overdose. This is especially important for infants and young children.
Total amounts of alcohol and propylene glycol from all medicines that are to be given to infants should be taken into account in order to avoid toxicity from these excipients. Infants should be monitored closely for toxicity related to Kaletra oral solution including: hyperosmolality, with or without lactic acidosis, renal toxicity, central nervous system (CNS) depression (including stupor, coma, and apnea), seizures, hypotonia, cardiac arrhythmias and ECG changes, and hemolysis. Postmarketing life-threatening cases of cardiac toxicity (including complete atrioventricular (AV) block, bradycardia, and cardiomyopathy), lactic acidosis, acute renal failure, CNS depression and respiratory complications leading to death have been reported, predominantly in preterm neonates receiving Kaletra oral solution (see sections 4.3 and 4.9).
Based on the findings in a paediatric study (observed exposures were approximately 35% AUC12 and 75% lower Cmin than in adults), young children from 14 days to 3 months could have sub-optimal exposure with a potential risk of inadequate virologic suppression and emergence of resistance (see section 5.2).
Because Kaletra oral solution contains alcohol, it is not recommended for use with polyurethane feeding tubes due to potential incompatibility.
4.5 Interaction with other medicinal products and other forms of interaction
Kaletra contains lopinavir and ritonavir, both of which are inhibitors of the P450 isoform CYP3Ain vitro. Co-administration of Kaletra and medicinal products primarily metabolised by CYP3A may result in increased plasma concentrations of the other medicinal product, which could increase or prolong its therapeutic and adverse reactions. Kaletra does not inhibit CYP2D6, CYP2C9, CYP2C19, CYP2E1, CYP2B6 or CYP1A2 at clinically relevant concentrations (see section 4.3).
Kaletra has been shownin vivo to induce its own metabolism and to increase the biotransformation of some medicinal products metabolised by cytochrome P450 enzymes (including CYP2C9 and CYP2C19) and by glucuronidation. This may result in lowered plasma concentrations and potential decrease of efficacy of co-administered medicinal products.
Medicinal products that are contraindicated specifically due to the expected magnitude of interaction and potential for serious adverse events are listed in section 4.3.
Known and theoretical interactions with selected antiretrovirals and non-antiretroviral medicinal products are listed in the table below. This list is not intended to be inclusive or comprehensive. Individual SmPCs should be consulted.
Interaction table
Interactions between Kaletra and co-administered medicinal products are listed in the table below (increase is indicated as “↑”, decrease as “↓”, no change as “↔”,once daily as “QD”, twice daily as “BID” and three times daily as "TID").
Unless otherwise stated, studies detailed below have been performed with the recommended dosage of lopinavir/ritonavir (i.e. 400/100 mg twice daily).
Co-administered drug by therapeutic area |
Effects on drug levels Geometric Mean Change (%) in AUC, Cmax, Cmin Mechanism of interaction |
Clinical recommendation concerning co-administration with Kaletra |
|
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Antiretroviral Agents |
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Nucleoside/Nucleotide reverse transcriptase inhibitors (NRTIs) |
|
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Stavudine, Lamivudine |
Lopinavir: ↔ |
No dose adjustment necessary. |
|
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Abacavir, Zidovudine |
Abacavir, Zidovudine: Concentrations may be reduced due to increased glucuronidation by lopinavir/ritonavir. |
The clinical significance of reduced abacavir and zidovudine concentrations is unknown. |
|
||||
Tenofovir disoproxil fumarate (DF), 300 mg QD (equivalent to 245 mg tenofovir disoproxil) |
Tenofovir: AUC: ↑ 32% Cmax: ↔ Cmin: ↑ 51% Lopinavir: ↔ |
No dose adjustment necessary. Higher tenofovir concentrations could potentiate tenofovir associated adverse events, including renal disorders. |
|
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Non-nucleoside reverse transcriptase inhibitors (NNRTIs) |
|
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Efavirenz, 600 mg QD |
Lopinavir: AUC: ↓ 20% Cmax: ↓ 13% Cmin: ↓ 42% |
The Kaletra tablets dosage should be increased to 500/125 mg twice daily when co-administered with efavirenz. |
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Efavirenz, 600 mg QD (Lopinavir/ritonavir 500/125 mg BID) |
Lopinavir: ↔ (Relative to 400/100 mg BID administered alone) |
||||||
Nevirapine, 200 mg BID |
Lopinavir: AUC: ↓ 27% Cmax: ↓ 19% Cmin: ↓ 51% |
The Kaletra tablets dosage should be increased to 500/125 mg twice daily when co-administered with nevirapine. |
|
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|
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Etravirine (Lopinavir/ritonavir tablet 400/100 mg BID) |
Etravirine: AUC: ↓ 35% Cmin: ↓ 45% Cmax: ↓ 30% Lopinavir: AUC: ↔ Cmin: ↓ 20% Cmax: ↔ |
No dose adjustment necessary |
|
|
|
|
|
Rilpivirine (Lopinavir/ritonavir capsule 400/100 mg BID) |
Rilpivirine: AUC: ↑ 52% Cmin: ↑ 74% Cmax: ↑ 29% Lopinavir: AUC: ↔ Cmin: ↓ 11% Cmax: ↔ (inhibition of CYP3A enzymes) |
Concomitant use of Kaletra with rilpivirine causes an increase in the plasma concentrations of rilpivirine, but no dose adjustment is required. |
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HIV CCR5 – antagonist |
|
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Maraviroc |
Maraviroc: AUC: ↑ 295% Cmax: ↑ 97% Due to CYP3A inhibition by lopinavir/ritonavir. |
The dose of maraviroc should be decreased to 150 mg twice daily during co-administration with Kaletra 400/100 mg twice daily. |
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Integrase inhibitor |
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Raltegravir |
Raltegravir: AUC: ↔ Cmax: ↔ C12: ↓ 30% Lopinavir: ↔ |
No dose adjustment necessary |
|
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|
|
Co-administration with other HIV protease inhibitors (PIs) According to current treatment guidelines, dual therapy with protease inhibitors is generally not recommended. |
|
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Fosamprenavir/ ritonavir (700/100 mg BID) (Lopinavir/ritonavir 400/100 mg BID) or Fosamprenavir (1400 mg BID) (Lopinavir/ritonavir 533/133 mg BID) |
Fosamprenavir: Amprenavir concentrations are significantly reduced. |
Co-administration of increased doses of fosamprenavir (1400 mg BID) with Kaletra (533/133 mg BID) to protease inhibitor-experienced patients resulted in a higher incidence of gastrointestinal adverse events and elevations in triglycerides with the combination regimen without increases in virological efficacy, when compared with standard doses of fosamprenavir/ritonavir. Concomitant administration of these medicinal products is not recommended. |
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Indinavir, 600 mg BID |
Indinavir: AUC: ↔ Cmin: ↑ 3.5-fold Cmax: ↓ (relative to indinavir 800 mg TID alone) Lopinavir: ↔ (relative to historical comparison) |
The appropriate doses for this combination, with respect to efficacy and safety, have not been established. |
|
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Saquinavir 1000 mg BID |
Saquinavir: ↔ |
No dose adjustment necessary. |
|
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Tipranavir/ritonavir (500/100 mg BID) |
Lopinavir: AUC: ↓ 55% Cmin: ↓ 70% Cmax: ↓ 47% |
Concomitant administration of these medicinal products is not recommended. |
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Acid reducing agents |
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Omeprazole (40 mg QD) |
Omeprazole: ↔ Lopinavir: ↔ |
No dose adjustment necessary |
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Ranitidine (150 mg single dose) |
Ranitidine: ↔ |
No dose adjustment necessary |
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Alpha1 adrenoreceptor antagonist |
|
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|
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Alfuzosin |
Alfuzosin: Due to CYP3A inhibition by lopinavir/ritonavir, concentrations of alfuzosin are expected to increase. |
Concomitant administration of Kaletra and alfuzosin is contra-indicated (see section 4.3) as alfuzosin-related toxicity, including hypotension, may be increased. |
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Analgesics |
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Fentanyl |
Fentanyl: Increased risk of side-effects (respiratory depression, sedation) due to higher plasma concentrations because of CYP3A4 inhibition by lopinavir/ritonavir. |
Careful monitoring of adverse effects (notably respiratory depression but also sedation) is recommended when fentanyl is concomitantly administered with Kaletra. |
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Antianginal |
|
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|
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Ranolazine |
Due to CYP3A inhibition by lopinavir/ritonavir, concentrations of ranolazine are expected to increase. |
The concomitant administration of Kaletra and ranolazine is contraindicated (see section 4.3). |
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Antiarrhythmics |
|
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|
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Amiodarone, Dronedarone |
Amiodarone, Dronedarone: Concentrations may be increased due to CYP3A4 inhibition by lopinavir/ritonavir. |
Concomitant administration of Kaletra and amiodarone or dronedarone is contraindicated (see section 4.3) as the risk of arrhythmias or other serious adverse reactions may be increased. |
|
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|
|
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Digoxin |
Digoxin: Plasma concentrations may be increased due to P-glycoprotein inhibition by lopinavir/ritonavir. The increased digoxin level may lessen over time as P-gp induction develops. |
Caution is warranted and therapeutic drug monitoring of digoxin concentrations, if available, is recommended in case of co-administration of Kaletra and digoxin. Particular caution should be used when prescribing Kaletra in patients taking digoxin as the acute inhibitory effect of ritonavir on P-gp is expected to significantly increase digoxin levels. Initiation of digoxin in patients already taking Kaletra is likely to result in lower than expected increases of digoxin concentrations. |
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Bepridil, Systemic Lidocaine, and Quinidine |
Bepridil, Systemic Lidocaine, Quinidine: Concentrations may be increased when co-administered with lopinavir/ritonavir. |
Caution is warranted and therapeutic drug concentration monitoring is recommended when available. |
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Antibiotics |
|
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|
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Clarithromycin |
Clarithromycin: Moderate increases in clarithromycin AUC are expected due to CYP3A inhibition by lopinavir/ritonavir. |
For patients with renal impairment (CrCL < 30 ml/min) dose reduction of clarithromycin should be considered (see section 4.4). Caution should be exercised in administering clarithromycin with Kaletra to patients with impaired hepatic or renal function. |
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Anticancer agents |
|
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|
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Abemaciclib |
Serum concentrations may be increased due to CYP3A inhibition by ritonavir. |
Co-administration of abemaciclib and Kaletra should be avoided. If this co-administration is judged unavoidable, refer to the abemaciclib SmPC for dosage adjustment recommendations. Monitor for ADRs related to abemaciclib. |
|
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Apalutamide |
Apalutamide is a moderate to strong CYP3A4 inducer and this may lead to a decreased exposure of lopinavir/ritonavir. Serum concentrations of apalutamide may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
Decreased exposure of Kaletra may result in potential loss of virological response. In addition, co-administration of apalutamide and Kaletra may lead to serious adverse events including seizure due to higher apalutamide levels. Concomitant use of Kaletra with apalutamide is not recommended. |
|
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Afatinib (Ritonavir 200 mg twice daily) |
Afatinib: AUC: ↑ Cmax: ↑ The extent of increase depends on the timing of ritonavir administration. Due to BCRP (breast cancer resistance protein/ABCG2) and acute P-gp inhibition by lopinavir/ritonavir. |
Caution should be exercised in administering afatinib with Kaletra. Refer to the afatinib SmPC for dosage adjustment recommendations. Monitor for ADRs related to afatinib. |
|
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Ceritinib |
Serum concentrations may be increased due to CYP3A and P-gp inhibition by lopinavir/ritonavir. |
Caution should be exercised in administering ceritinib with Kaletra. Refer to the ceritinib SmPC for dosage adjustment recommendations. Monitor for ADRs related to ceritinib. |
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Most tyrosine kinase inhibitors such as dasatinib and nilotinib, vincristine, vinblastine |
Most tyrosine kinase inhibitors such as dasatinib and nilotinib, also vincristine and vinblastine: Risk of increased adverse events due to higher serum concentrations because of CYP3A4 inhibition by lopinavir/ritonavir. |
Careful monitoring of the tolerance of these anticancer agents. |
|
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|
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Encorafenib |
Serum concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
Co-administration of encorafenib with Kaletra may increase encorafenib exposure which may increase the risk of toxicity, including the risk of serious adverse events such as QT interval prolongation. Co-administration of encorafenib and Kaletra should be avoided. If the benefit is considered to outweigh the risk and Kaletra must be used, patients should be carefully monitored for safety. |
|
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|
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Ibrutinib |
Serum concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
Co-administration of ibrutinib and Kaletra may increase ibrutinib exposure which may increase the risk of toxicity including risk of tumor lysis syndrome. Co-administration of ibrutinib and Kaletra should be avoided. If the benefit is considered to outweigh the risk and Kaletra must be used, reduce the ibrutinib dose to 140 mg and monitor patient closely for toxicity. |
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Neratinib |
Serum concentrations may be increased due to CYP3A inhibition by ritonavir. |
Concomitant use of neratinib with Kaletra is contraindicated due to serious and/or life-threatening potential reactions including hepatotoxicity (see section 4.3). |
|
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Venetoclax |
Due to CYP3A inhibition by lopinavir/ritonavir. |
Serum concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir, resulting in increased risk of tumor lysis syndrome at the dose initiation and during the ramp-up phase (see section 4.3 and refer to the venetoclax SmPC). For patients who have completed the ramp-up phase and are on a steady daily dose of venetoclax, reduce the venetoclax dose by at least 75% when used with strong CYP3A inhibitors (refer to the venetoclax SmPC for dosing instructions). Patients should be closely monitored for signs related to venetoclax toxicities. |
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Anticoagulants |
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Warfarin |
Warfarin: Concentrations may be affected when co-administered with lopinavir/ritonavir due to CYP2C9 induction. |
It is recommended that INR (international normalised ratio) be monitored. |
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Rivaroxaban (Ritonavir 600 mg twice daily) |
Rivaroxaban: AUC: ↑ 153% Cmax: ↑ 55% Due to CYP3A and P-gp inhibition by lopinavir/ritonavir. |
Co-administration of rivaroxaban and Kaletra may increase rivaroxaban exposure which may increase the risk of bleeding. The use of rivaroxaban is not recommended in patients receiving concomitant treatment with Kaletra (see section 4.4). |
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Vorapaxar |
Serum concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
The co-administration of vorapaxar with Kaletra is not recommended (see section 4.4 and refer to the vorapaxar SmPC). |
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Anticonvulsants |
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Phenytoin |
Phenytoin: Steady-state concentrations was moderately decreased due to CYP2C9 and CYP2C19 induction by lopinavir/ritonavir. Lopinavir: Concentrations are decreased due to CYP3A induction by phenytoin. |
Caution should be exercised in administering phenytoin with Kaletra. Phenytoin levels should be monitored when co-administering with Kaletra. When co-administered with phenytoin, an increase of Kaletra dosage may be envisaged. Dose adjustment has not been evaluated in clinical practice. |
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Carbamazepine and Phenobarbital |
Carbamazepine: Serum concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. Lopinavir: Concentrations may be decreased due to CYP3A induction by carbamazepine and phenobarbital. |
Caution should be exercised in administering carbamazepine or phenobarbital with Kaletra. Carbamazepine and phenobarbital levels should be monitored when co-administering with Kaletra. When co-administered with carbamazepine or phenobarbital, an increase of Kaletra dosage may be envisaged. Dose adjustment has not been evaluated in clinical practice |
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Lamotrigine and Valproate |
Lamotrigine: AUC: ↓ 50% Cmax: ↓ 46% Cmin: ↓ 56% Due to induction of lamotrigine glucuronidation Valproate: ↓ |
Patients should be monitored closely for a decreased VPA effect when Kaletra and valproic acid or valproate are given concomitantly. In patients starting or stopping Kaletra while currently taking maintenance dose of lamotrigine: lamotrigine dose may need to be increased if Kaletra is added, or decreased if Kaletra is discontinued; therefore plasma lamotrigine monitoring should be conducted, particularly before and during 2 weeks after starting or stopping Kaletra, in order to see if lamotrigine dose adjustment is needed. In patients currently taking Kaletra and starting lamotrigine: no dose adjustments to the recommended dose escalation of lamotrigine should be necessary. |
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Antidepressants and Anxiolytics |
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Trazodone single dose (Ritonavir, 200 mg BID) |
Trazodone: AUC: ↑ 2.4-fold Adverse events of nausea, dizziness, hypotension and syncope were observed following co-administration of trazodone and ritonavir. |
It is unknown whether the combination of Kaletra causes a similar increase in trazodone exposure. The combination should be used with caution and a lower dose of trazodone should be considered. |
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Antifungals |
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Ketoconazole and Itraconazole |
Ketoconazole, Itraconazole: Serum concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
High doses of ketoconazole and itraconazole (> 200 mg/day) are not recommended. |
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Voriconazole |
Voriconazole: Concentrations may be decreased. |
Co-administration of voriconazole and low dose ritonavir (100 mg BID) as contained in Kaletra should be avoided unless an assessment of the benefit/risk to patient justifies the use of voriconazole. |
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Anti-gout agents |
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Colchicine single dose (Ritonavir 200 mg twice daily) |
Colchicine: AUC: ↑ 3-fold Cmax: ↑ 1.8-fold Due to P-gp and/or CYP3A4 inhibition by ritonavir. |
Concomitant administration of Kaletra with colchicine in patients with renal and/or hepatic impairment is contraindicated due to a potential increase of colchicine-related serious and/or life-threatening reactions such as neuromuscular toxicity (including rhabdomyolysis) (see sections 4.3 and 4.4). A reduction in colchicine dosage or an interruption of colchicine treatment is recommended in patients with normal renal or hepatic function if treatment with Kaletra is required. Refer to colchicine prescribing information. |
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Antihistamines |
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Astemizole Terfenadine |
Serum concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
Concomitant administration of Kaletra and astemizole and terfenadine is contraindicated as it may increase the risk of serious arrhythmias from these agents (see section 4.3). |
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Anti-infectives |
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Fusidic acid |
Fusidic acid: Concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
Concomitant administration of Kaletra with fusidic acid is contra-indicated in dermatological indications due to the increased risk of adverse events related to fusidic acid, notably rhabdomyolysis (see section 4.3). When used for osteo-articular infections, where the co-administration is unavoidable, close clinical monitoring for muscular adverse events is strongly recommended (see section 4.4). |
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Antimycobacterials |
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Bedaquiline (single dose) (Lopinavir/ritonavir 400/100 mg BID, multiple dose) |
Bedaquiline: AUC: ↑ 22% Cmax: ↔ A more pronounced effect on bedaquiline plasma exposures may be observed during prolonged co-administration with lopinavir/ritonavir. CYP3A4 inhibition likely due to lopinavir/ritonavir. |
Due to the risk of bedaquiline related adverse events, the combination of bedaquiline and Kaletra should be avoided. If the benefit outweighs the risk, co-administration of bedaquiline with Kaletra must be done with caution. More frequent electrocardiogram monitoring and monitoring of transaminases is recommended (see section 4.4 and refer to the bedaquiline SmPC). |
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Delamanid (100 mg BID) (Lopinavir/ritonavir 400/100 mg BID) |
Delamanid: AUC: ↑ 22% DM-6705 (delamanid active metabolite): AUC: ↑ 30% A more pronounced effect on DM-6705 exposure may be observed during prolonged co-administration with lopinavir/ritonavir. |
Due to the risk of QTc prolongation associated with DM-6705, if co-administration of delamanid with Kaletra is considered necessary, very frequent ECG monitoring throughout the full delamanid treatment period is recommended (see section 4.4 and refer to the delamanid SmPC). |
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Rifabutin, 150 mg QD |
Rifabutin (parent drug and active 25-O-desacetyl metabolite): AUC: ↑ 5.7-fold Cmax: ↑ 3.5-fold |
When given with Kaletra the recommended dose of rifabutin is 150 mg 3 times per week on set days (for example Monday-Wednesday-Friday). Increased monitoring for rifabutin-associated adverse reactions including neutropenia and uveitis is warranted due to an expected increase in exposure to rifabutin. Further dosage reduction of rifabutin to 150 mg twice weekly on set days is recommended for patients in whom the 150 mg dose 3 times per week is not tolerated. It should be kept in mind that the twice weekly dosage of 150 mg may not provide an optimal exposure to rifabutin thus leading to a risk of rifamycin resistance and a treatment failure. No dose adjustment is needed for Kaletra. |
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Rifampicin |
Lopinavir: Large decreases in lopinavir concentrations may be observed due to CYP3A induction by rifampicin. |
Co-administration of Kaletra with rifampicin is not recommended as the decrease in lopinavir concentrations may in turn significantly decrease the lopinavir therapeutic effect. A dose adjustment of Kaletra 400 mg/400 mg (i.e. Kaletra 400/100 mg + ritonavir 300 mg) twice daily has allowed compensating for the CYP 3A4 inducer effect of rifampicin. However, such a dose adjustment might be associated with ALT/AST elevations and with increase in gastrointestinal disorders. Therefore, this co-administration should be avoided unless judged strictly necessary. If this co-administration is judged unavoidable, increased dose of Kaletra at 400 mg/400 mg twice daily may be administered with rifampicin under close safety and therapeutic drug monitoring. The Kaletra dose should be titrated upward only after rifampicin has been initiated (see section 4.4). |
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Antipsychotics |
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Lurasidone |
Due to CYP3A inhibition by lopinavir/ritonavir, concentrations of lurasidone are expected to increase. |
The concomitant administration with lurasidone is contraindicated (see section 4.3). |
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Pimozide |
Due to CYP3A inhibition by lopinavir/ritonavir, concentrations of pimozide are expected to increase. |
Concomitant administration of Kaletra and pimozide is contraindicated as it may increase the risk of serious haematologic abnormalities or other serious adverse effects from this agent (see section 4.3) |
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Quetiapine |
Due to CYP3A inhibition by lopinavir/ritonavir, concentrations of quetiapine are expected to increase. |
Concomitant administration of Kaletra and quetiapine is contraindicated as it may increase quetiapine-related toxicity. |
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Benzodiazepines |
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Midazolam |
Oral Midazolam: AUC: ↑ 13-fold Parenteral Midazolam: AUC: ↑ 4-fold Due to CYP3A inhibition by lopinavir/ritonavir |
Kaletra must not be co-administered with oral midazolam (see section 4.3), whereas caution should be used with co-administration of Kaletra and parenteral midazolam. If Kaletra is co-administered with parenteral midazolam, it should be done in an intensive care unit (ICU) or similar setting which ensures close clinical monitoring and appropriate medical management in case of respiratory depression and/or prolonged sedation. Dosage adjustment for midazolam should be considered especially if more than a single dose of midazolam is administered. |
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Beta2-adrenoceptor agonist (long acting) |
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Salmeterol |
Salmeterol: Concentrations are expected to increase due to CYP3A inhibition by lopinavir/ritonavir. |
The combination may result in increased risk of cardiovascular adverse events associated with salmeterol, including QT prolongation, palpitations and sinus tachycardia. Therefore, concomitant administration of Kaletra with salmeterol is not recommended (see section 4.4). |
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Calcium channel blockers |
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Felodipine, Nifedipine, and Nicardipine |
Felodipine, Nifedipine, Nicardipine: Concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
Clinical monitoring of therapeutic and adverse effects is recommended when these medicines are concomitantly administered with Kaletra. |
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Corticosteroids |
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Dexamethasone |
Lopinavir: Concentrations may be decreased due to CYP3A induction by dexamethasone. |
Clinical monitoring of antiviral efficacy is recommended when these medicines are concomitantly administered with Kaletra. |
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Inhaled, injectable or intranasal fluticasone propionate, budesonide, triamcinolone |
Fluticasone propionate, 50 µg intranasal 4 times daily: Plasma concentrations ↑ Cortisol levels ↓ 86% |
Greater effects may be expected when fluticasone propionate is inhaled. Systemic corticosteroid effects including Cushing's syndrome and adrenal suppression have been reported in patients receiving ritonavir and inhaled or intranasally administered fluticasone propionate; this could also occur with other corticosteroids metabolised via the P450 3A pathway e.g. budesonide and triamcinolone. Consequently, concomitant administration of Kaletra and these glucocorticoids is not recommended unless the potential benefit of treatment outweighs the risk of systemic corticosteroid effects (see section 4.4). A dose reduction of the glucocorticoid should be considered with close monitoring of local and systemic effects or a switch to a glucocorticoid, which is not a substrate for CYP3A4 (e.g. beclomethasone). Moreover, in case of withdrawal of glucocorticoids progressive dose reduction may have to be performed over a longer period. |
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Phosphodiesterase(PDE5) inhibitors |
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Avanafil (ritonavir 600 mg BID) |
Avanafil: AUC: ↑ 13-fold Due to CYP3A inhibition by lopinavir/ritonavir. |
The use of avanafil with Kaletra is contraindicated (see section 4.3). |
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Tadalafil |
Tadalafil: AUC: ↑ 2-fold Due to CYP3A4 inhibition by lopinavir/ritonavir. |
For the treatment of pulmonary arterial hypertension: Co-administration of Kaletra with sildenafil is contraindicated (see section 4.3). Co-administration of Kaletra with tadalafil is not recommended. For erectile dysfunction: Particular caution must be used when prescribing sildenafil or tadalafil in patients receiving Kaletra with increased monitoring for adverse events including hypotension, syncope, visual changes and prolonged erection (see section 4.4). When co-administered with Kaletra, sildenafil doses must not exceed 25 mg in 48 hours and tadalafil doses must not exceed 10 mg every 72 hours |
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Sildenafil |
Sildenafil: AUC: ↑ 11-fold Due to CYP3A inhibition by lopinavir/ritonavir. |
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Vardenafil |
Vardenafil: AUC: ↑ 49-fold Due to CYP3A inhibition by lopinavir/ritonavir. |
The use of vardenafil with Kaletra is contraindicated (see section 4.3). |
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Ergot alkaloids |
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Dihydroergotamine, ergonovine, ergotamine, methylergonovine |
Serum concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
Concomitant administration of Kaletra and ergot alkaloids are contraindicated as it may lead to acute ergot toxicity, including vasospasm and ischaemia (see section 4.3). |
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GI motility agent |
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Cisapride |
Serum concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
Concomitant administration of Kaletra and cisapride is contraindicated as it may increase the risk of serious arrhythmias from this agent (see section 4.3). |
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HCV direct acting antivirals |
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Elbasvir/grazoprevir (50/200 mg QD) |
Elbasvir: AUC: ↑ 2.71-fold Cmax: ↑ 1.87-fold C24: ↑ 3.58-fold Grazoprevir: AUC: ↑ 11.86-fold Cmax: ↑ 6.31-fold C24: ↑ 20.70-fold (combinations of mechanisms including CYP3A inhibition) Lopinavir: ↔ |
Concomitant administration of elbasvir/grazoprevir with Kaletra is contraindicated (see section 4.3). |
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Glecaprevir/pibrentasvir |
Serum concentrations may be increased due to P-glycoprotein, BCRP and OATP1B inhibition by lopinavir/ritonavir. |
Concomitant administration of glecaprevir/pibrentasvir and Kaletra is not recommended due to an increased risk of ALT elevations associated with increased glecaprevir exposure. |
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Ombitasvir/paritaprevir/ritonavir + dasabuvir (25/150/100 mg QD + 400 mg BID) Lopinavir/ritonavir 400/100 mg BID |
Ombitasvir: ↔ Paritaprevir: AUC: ↑ 2.17-fold Cmax: ↑ 2.04-fold Ctrough: ↑ 2.36-fold (inhibition of CYP3A/efflux transporters) Dasabuvir: ↔ Lopinavir: ↔ |
Co-administration is contraindicated. Lopinavir/ritonavir 800/200 mg QD was administered with ombitasvir/paritaprevir/ritonavir with or without dasabuvir. The effect on DAAs and lopinavir was similar to that observed when lopinavir/ritonavir 400/100 mg BID was administered (see section 4.3). |
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Ombitasvir/paritaprevir/ ritonavir (25/150/100 mg QD) Lopinavir/ritonavir 400/100 mg BID |
Ombitasvir: ↔ Paritaprevir: AUC: ↑ 6.10-fold Cmax: ↑ 4.76-fold Ctrough: ↑ 12.33-fold (inhibition of CYP3A/efflux transporters) Lopinavir: ↔ |
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Sofosbuvir/velpatasvir/ voxilaprevir |
Serum concentrations of sofosbuvir, velpatasvir and voxilaprevir may be increased due to P-glycoprotein, BCRP and OATP1B1/3 inhibition by lopinavir/ritonavir. However, only the increase in voxilaprevir exposure is considered clinically relevant. |
It is not recommended to co-administer Kaletra and sofosbuvir/velpatasvir/ voxilaprevir. |
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HCV protease inhibitors |
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Simeprevir 200 mg daily (ritonavir 100 mg BID) |
Simeprevir: AUC: ↑ 7.2-fold Cmax: ↑ 4.7-fold Cmin: ↑ 14.4-fold |
It is not recommended to co-administer Kaletra and simeprevir. |
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Herbal products |
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St John's wort (Hypericum perforatum) |
Lopinavir: Concentrations may be reduced due to induction of CYP3A by the herbal preparation St John's wort. |
Herbal preparations containing St John's wort must not be combined with lopinavir and ritonavir. If a patient is already taking St John's wort, stop St John's wort and if possible check viral levels. Lopinavir and ritonavir levels may increase on stopping St John's wort. The dose of Kaletra may need adjusting. The inducing effect may persist for at least 2 weeks after cessation of treatment with St John's wort (see section 4.3). Therefore, Kaletra can be started safely 2 weeks after cessation of St John's wort. |
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Immunosuppressants |
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Cyclosporin, Sirolimus (rapamycin), and Tacrolimus |
Cyclosporin, Sirolimus (rapamycin), Tacrolimus: Concentrations may be increased due to CYP3A inhibition by lopinavir/ritonavir. |
More frequent therapeutic concentration monitoring is recommended until plasma levels of these products have been stabilised. |
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Lipid lowering agents |
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Lovastatin and Simvastatin |
Lovastatin, Simvastatin: Markedly increased plasma concentrations due to CYP3A inhibition by lopinavir/ritonavir. |
Since increased concentrations of HMG-CoA reductase inhibitors may cause myopathy, including rhabdomyolysis, the combination of these agents with Kaletra is contraindicated (see section 4.3). |
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Lipid-modifying agents |
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Lomitapide |
CYP3A4 inhibitors increase the exposure of lomitapide, with strong inhibitors increasing exposure approximately 27-fold. Due to CYP3A inhibition by lopinavir/ritonavir, concentrations of lomitapide are expected to increase. |
Concomitant use of Kaletra with lomitapide is contraindicated (see prescribing information for lomitapide) (see section 4.3). |
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Atorvastatin |
Atorvastatin: AUC: ↑ 5.9-fold Cmax: ↑ 4.7-fold Due to CYP3A inhibition by lopinavir/ritonavir. |
The combination of Kaletra with atorvastatin is not recommended. If the use of atorvastatin is considered strictly necessary, the lowest possible dose of atorvastatin should be administered with careful safety monitoring (see section 4.4). |
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Rosuvastatin, 20 mg QD |
Rosuvastatin: AUC: ↑ 2-fold Cmax: ↑ 5-fold While rosuvastatin is poorly metabolised by CYP3A4, an increase of its plasma concentrations was observed. The mechanism of this interaction may result from inhibition of transport proteins. |
Caution should be exercised and reduced doses should be considered when Kaletra is co-administered with rosuvastatin (see section 4.4). |
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Fluvastatin or Pravastatin |
Fluvastatin, Pravastatin: No clinical relevant interaction expected. Pravastatin is not metabolised by CYP450. Fluvastatin is partially metabolised by CYP2C9. |
If treatment with an HMG-CoA reductase inhibitor is indicated, fluvastatin or pravastatin is recommended. |
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Opioids |
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Buprenorphine, 16 mg QD |
Buprenorphine: ↔ |
No dose adjustment necessary. |
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Methadone |
Methadone: ↓ |
Monitoring plasma concentrations of methadone is recommended. |
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Oral contraceptives |
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Ethinyl Oestradiol |
Ethinyl Oestradiol: ↓ |
In case of co-administration of Kaletra with contraceptives containing ethinyl oestradiol (whatever the contraceptive formulation e.g. oral or patch), additional methods of contraception must be used. |
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Smoking cessation aids |
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Bupropion |
Buproprion and its active metabolite, hydroxybupropion: AUC and Cmax ↓ ~50% This effect may be due to induction of bupropion metabolism. |
If the co-administration of Kaletra with bupropion is judged unavoidable, this should be done under close clinical monitoring for bupropion efficacy, without exceeding the recommended dosage, despite the observed induction. |
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Thyroid hormone replacement therapy |
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Levothyroxine |
Post-marketing cases have been reported indicating a potential interaction between ritonavir containing products and levothyroxine. |
Thyroid-stimulating hormone (TSH) should be monitored in patients treated with levothyroxine at least the first month after starting and/or ending lopinavir/ritonavir treatment. |
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Vasodilating agents |
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Bosentan |
Lopinavir - ritonavir: Lopinavir/ritonavir plasma concentrations may decrease due to CYP3A4 induction by bosentan. Bosentan: AUC: ↑ 5-fold Cmax: ↑ 6-fold Initially, bosentan Cmin: ↑ by approximately 48-fold. Due to CYP3A4 inhibition by lopinavir/ritonavir. |
Caution should be exercised in administering Kaletra with bosentan. When Kaletra is administered concomitantly with bosentan, the efficacy of the HIV therapy should be monitored and patients should be closely observed for bosentan toxicity, especially during the first week of co-administration. |
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Riociguat |
Serum concentrations may be increased due to CYP3A and P-gp inhibition by lopinavir/ritonavir. |
The co-administration of riociguat with Kaletra is not recommended (see section 4.4 and refer to riociguat SmPC). |
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Other medicinal products |
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Based on known metabolic profiles, clinically significant interactions are not expected between Kaletra and dapsone, trimethoprim/sulfamethoxazole, azithromycin or fluconazole. |
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4.6 Fertility, pregnancy and lactation
Pregnancy
As a general rule, when deciding to use antiretroviral agents for the treatment of HIV infection in pregnant women and consequently for reducing the risk of HIV vertical transmission to the newborn, the animal data as well as the clinical experience in pregnant women should be taken into account in order to characterise the safety for the foetus.
Lopinavir/ritonavir has been evaluated in over 3000 women during pregnancy, including over 1000 during the first trimester.
In post-marketing surveillance through the Antiretroviral Pregnancy Registry, established since January 1989, an increased risk of birth defects exposures with Kaletra has not been reported among over 1000 women exposed during the first trimester. The prevalence of birth defects after any trimester exposure to lopinavir is comparable to the prevalence observed in the general population. No pattern of birth defects suggestive of a common etiology was seen. Studies in animals have shown reproductive toxicity (see section 5.3). Based on the data mentioned, the malformative risk is unlikely in humans. Lopinavir can be used during pregnancy if clinically needed.
Breastfeeding
Studies in rats revealed that lopinavir is excreted in the milk. It is not known whether this medicinal product is excreted in human milk. As a general rule, it is recommended that mothers infected by HIV do not breastfeed their babies under any circumstances in order to avoid transmission of HIV.
Fertility
Animal studies have shown no effects on fertility. No human data on the effect of lopinavir/ritonavir on fertility are available.
4.7 Effects on ability to drive and use machines
No studies on the effects on the ability to drive and use machines have been performed. Patients should be informed that nausea has been reported during treatment with Kaletra (see section 4.8).
Kaletra oral solution contains approximately 42% v/v alcohol.
4.8 Undesirable effects
a. Summary of the safety profile
The safety of Kaletra has been investigated in over 2600 patients in Phase II-IV clinical trials, of which over 700 have received a dose of 800/200 mg (6 capsules or 4 tablets) once daily. Along with nucleoside reverse transcriptase inhibitors (NRTIs), in some studies, Kaletra was used in combination with efavirenz or nevirapine.
The most common adverse reactions related to Kaletra therapy during clinical trials were diarrhoea, nausea, vomiting, hypertriglyceridaemia and hypercholesterolemia. Diarrhoea, nausea and vomiting may occur at the beginning of the treatment while hypertriglyceridaemia and hypercholesterolemia may occur later. Treatment emergent adverse events led to premature study discontinuation for 7% of subjects from Phase II-IV studies.
It is important to note that cases of pancreatitis have been reported in patients receiving Kaletra, including those who developed hypertriglyceridaemia. Furthermore, rare increases in PR interval have been reported during Kaletra therapy (see section 4.4).
b. Tabulated list of adverse reactions
Adverse reactions from clinical trials and post-marketing experience in adult and paediatric patients:
The following events have been identified as adverse reactions. The frequency category includes all reported events of moderate to severe intensity, regardless of the individual causality assessment. The adverse reactions are displayed by system organ class. Within each frequency grouping, undesirable effects are presented in order of decreasing seriousness: very common (≥1/10), common (≥ 1/100 to < 1/10), uncommon (≥ 1/1000 to < 1/100) and rare (≥1/10,000 to <1/1000).
Undesirable effects in clinical studies and post-marketing in adult patients |
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System organ class |
Frequency |
Adverse reaction |
Infections and infestations |
Very common |
Upper respiratory tract infection |
Common |
Lower respiratory tract infection, skin infections including cellulitis, folliculitis and furuncle |
|
Blood and lymphatic system disorders |
Common |
Anaemia, leucopenia, neutropenia, lymphadenopathy |
Immune system disorders |
Common |
Hypersensitivity including urticaria and angioedema |
Uncommon |
Immune reconstitution inflammatory syndrome |
|
Endocrine disorders |
Uncommon |
Hypogonadism |
Metabolism and nutrition disorders |
Common |
Blood glucose disorders including diabetes mellitus, hypertriglyceridaemia, hypercholesterolemia, weight decreased, decreased appetite |
Uncommon |
Weight increased, increased appetite |
|
Psychiatric disorders |
Common |
Anxiety |
Uncommon |
Abnormal dreams, libido decreased |
|
Nervous system disorders |
Common |
Headache (including migraine), neuropathy (including peripheral neuropathy), dizziness, insomnia |
Uncommon |
Cerebrovascular accident, convulsion, dysgeusia, ageusia, tremor |
|
Eye disorders |
Uncommon |
Visual impairment |
Ear and labyrinth disorders |
Uncommon |
Tinnitus, vertigo |
Cardiac disorders |
Uncommon |
Atherosclerosis such as myocardial infarction1, atrioventricular block, tricuspid valve incompetence |
Vascular disorders |
Common |
Hypertension |
Uncommon |
Deep vein thrombosis |
|
Gastrointestinal disorders |
Very common |
Diarrhoea, nausea |
Common |
Pancreatitis1, vomiting, gastrooesophageal reflux disease, gastroenteritis and colitis, abdominal pain (upper and lower), abdominal distension, dyspepsia, haemorrhoids, flatulence |
|
Uncommon |
Gastrointestinal haemorrhage including gastrointestinal ulcer, duodenitis, gastritis and rectal haemorrhage, stomatitis and oral ulcers, faecal incontinence, constipation, dry mouth |
|
Hepatobiliary disorders |
Common |
Hepatitis including AST, ALT and GGT increases |
Uncommon |
Jaundice hepatic steatosis, hepatomegaly, cholangitis, hyperbilirubinemia |
|
Skin and subcutaneous tissue disorders |
Common |
Rash including maculopapular rash, dermatitis/rash including eczema and seborrheic dermatitis, night sweats, pruritus |
Uncommon |
Alopecia, capillaritis, vasculitis |
|
Rare |
Steven-Johnson syndrome, erythema multiforme |
|
Musculoskeletal and connective tissue disorders |
Common |
Myalgia, musculoskeletal pain including arthralgia and back pain, muscle disorders such as weakness and spasms |
Uncommon |
Rhabdomyolysis, osteonecrosis |
|
Renal and urinary disorders |
Uncommon |
Creatinine clearance decreased, nephritis, haematuria |
Reproductive system and breast disorders |
Common |
Erectile dysfunction, menstrual disorders - amenorrhoea, menorrhagia |
General disorders and administration site conditions |
Common |
Fatigue including asthenia |
1 See section 4.4: pancreatitis and lipids
c. Description of selected adverse reactions
Cushing's syndrome has been reported in patients receiving ritonavir and inhaled or intranasally administered fluticasone propionate; this could also occur with other corticosteroids metabolised via the P450 3A pathway e.g. budesonide (see section 4.4 and 4.5).
Increased creatine phosphokinase (CPK), myalgia, myositis, and rarely, rhabdomyolysis have been reported with protease inhibitors, particularly in combination with nucleoside reverse transcriptase inhibitors.
Metabolic parameters
Weight and levels of blood lipids and glucose may increase during antiretroviral therapy (see section 4.4).
In HIV-infected patients with severe immune deficiency at the time of initiation of combination antiretroviral therapy (CART), an inflammatory reaction to asymptomatic or residual opportunistic infections may arise. Autoimmune disorders (such as Graves' disease and autoimmune hepatitis) have also been reported; however, the reported time to onset is more variable and can occur many months after initiation of treatment (see section 4.4).
Cases of osteonecrosis have been reported, particularly in patients with generally acknowledged risk factors, advanced HIV disease or long-term exposure to combination antiretroviral therapy (CART). The frequency of this is unknown (see section 4.4).
d. Paediatric populations
In children 14 days of age and older, the nature of the safety profile is similar to that seen in adults (see Table in section b).
Reporting of suspected adverse reactions
Reporting suspected adverse reactions after authorisation of the medicinal product is important. It allows continued monitoring of the benefit/risk balance of the medicinal product. Healthcare professionals are asked to report any suspected adverse reactions via the Yellow Card Scheme:
Website: www.mhra.gov.uk/yellowcard or search for MHRA Yellow Card in the Google Play or Apple App Store.
4.9 Overdose
To date, there is limited human experience of acute overdose with Kaletra.
Overdoses with Kaletra oral solution have been reported (including fatal outcome). The following events have been reported in association with unintended overdoses in preterm neonates: complete atrioventricular block, cardiomyopathy, lactic acidosis, and acute renal failure.
The adverse clinical signs observed in dogs included salivation, emesis and diarrhoea/abnormal stool. The signs of toxicity observed in mice, rats or dogs included decreased activity, ataxia, emaciation, dehydration and tremors.
There is no specific antidote for overdose with Kaletra. Treatment of overdose with Kaletra is to consist of general supportive measures including monitoring of vital signs and observation of the clinical status of the patient. If indicated, elimination of unabsorbed active substance is to be achieved by emesis or gastric lavage. Administration of activated charcoal may also be used to aid in removal of unabsorbed active substance. Since Kaletra is highly protein bound, dialysis is unlikely to be beneficial in significant removal of the active substance.
However, dialysis can remove both alcohol and propylene glycol in the case of overdose with Kaletra oral solution.
5. Pharmacological properties
5.1 Pharmacodynamic properties
Pharmaco-therapeutic group: antivirals for systemic use, antivirals for treatment of HIV infections, combinations, ATC code: J05AR10
Mechanism of action
Lopinavir provides the antiviral activity of Kaletra. Lopinavir is an inhibitor of the HIV-1 and HIV-2 proteases. Inhibition of HIV protease prevents cleavage of thegag-pol polyprotein resulting in the production of immature, non-infectious virus.
Effects on the electrocardiogram
QTcF interval was evaluated in a randomised, placebo and active (moxifloxacin 400 mg once daily) controlled crossover study in 39 healthy adults, with 10 measurements over 12 hours on Day 3. The maximum mean (95% upper confidence bound) differences in QTcF from placebo were 3.6 (6.3) and 13.1(15.8) for 400/100 mg twice daily and supratherapeutic 800/200 mg twice daily LPV/r, respectively. The induced QRS interval prolongation from 6 ms to 9.5 ms with high dose lopinavir/ritonavir (800/200 mg twice daily) contributes to QT prolongation. The two regimens resulted in exposures on Day 3 which were approximately 1.5 and 3-fold higher than those observed with recommended once daily or twice daily LPV/r doses at steady state. No subject experienced an increase in QTcF of ≥ 60 ms from baseline or a QTcF interval exceeding the potentially clinically relevant threshold of 500 ms.
Modest prolongation of the PR interval was also noted in subjects receiving lopinavir/ritonavir in the same study on Day 3. The mean changes from baseline in PR interval ranged from 11.6 ms to 24.4 ms in the 12 hour interval post dose. Maximum PR interval was 286 ms and no second or third degree heart block was observed (see section 4.4).
Antiviral activity in vitro
Thein vitroantiviral activity of lopinavir against laboratory and clinical HIV strains was evaluated in acutely infected lymphoblastic cell lines and peripheral blood lymphocytes, respectively. In the absence of human serum, the mean IC50 of lopinavir against five different HIV-1 laboratory strains was 19 nM. In the absence and presence of 50% human serum, the mean IC50 of lopinavir against HIV-1IIIB in MT4 cells was 17 nM and 102 nM, respectively. In the absence of human serum, the mean IC50 of lopinavir was 6.5 nM against several HIV-1 clinical isolates.
Resistance
In vitro selection of resistanceHIV-1 isolates with reduced susceptibility to lopinavir have been selectedin vitro. HIV-1 has been passagedin vitro with lopinavir alone and with lopinavir plus ritonavir at concentration ratios representing the range of plasma concentration ratios observed during Kaletra therapy. Genotypic and phenotypic analysis of viruses selected in these passages suggest that the presence of ritonavir, at these concentration ratios, does not measurably influence the selection of lopinavir-resistant viruses. Overall, thein vitro characterisation of phenotypic cross-resistance between lopinavir and other protease inhibitors suggest that decreased susceptibility to lopinavir correlated closely with decreased susceptibility to ritonavir and indinavir, but did not correlate closely with decreased susceptibility to amprenavir, saquinavir, and nelfinavir.
Analysis of resistance in ARV-naïve patients
In clinical studies with a limited number of isolates analysed, the selection of resistance to lopinavir has not been observed in naïve patients without significant protease inhibitor resistance at baseline. See further the detailed description of the clinical studies.
Analysis of resistance in PI-experienced patients
The selection of resistance to lopinavir in patients having failed prior protease inhibitor therapy was characterised by analysing the longitudinal isolates from 19 protease inhibitor-experienced subjects in 2 Phase II and one Phase III studies who either experienced incomplete virologic suppression or viral rebound subsequent to initial response to Kaletra and who demonstrated incrementalin vitro resistance between baseline and rebound (defined as emergence of new mutations or 2-fold change in phenotypic susceptibility to lopinavir). Incremental resistance was most common in subjects whose baseline isolates had several protease inhibitor-associated mutations, but < 40-fold reduced susceptibility to lopinavir at baseline. Mutations V82A, I54V and M46I emerged most frequently. Mutations L33F, I50V and V32I combined with I47V/A were also observed. The 19 isolates demonstrated a 4.3-fold increase in IC50 compared to baseline isolates (from 6.2- to 43-fold, compared to wild-type virus).
Genotypic correlates of reduced phenotypic susceptibility to lopinavir in viruses selected by other protease inhibitors. Thein vitro antiviral activity of lopinavir against 112 clinical isolates taken from patients failing therapy with one or more protease inhibitors was assessed. Within this panel, the following mutations in HIV protease were associated with reducedin vitro susceptibility to lopinavir: L10F/I/R/V, K20M/R, L24I, M46I/L, F53L, I54L/T/V, L63P, A71I/L/T/V, V82A/F/T, I84V and L90M. The median EC50 of lopinavir against isolates with 0 − 3, 4 − 5, 6 − 7 and 8 − 10 mutations at the above amino acid positions was 0.8, 2.7 13.5 and 44.0-fold higher than the EC50 against wild type HIV, respectively. The 16 viruses that displayed > 20-fold change in susceptibility all contained mutations at positions 10, 54, 63 plus 82 and/or 84. In addition, they contained a median of 3 mutations at amino acid positions 20, 24, 46, 53, 71 and 90. In addition to the mutations described above, mutations V32I and I47A have been observed in rebound isolates with reduced lopinavir susceptibility from protease inhibitor experienced patients receiving Kaletra therapy, and mutations I47A and L76V have been observed in rebound isolates with reduced lopinavir susceptibility from patients receiving Kaletra therapy.
Conclusions regarding the relevance of particular mutations or mutational patterns are subject to change with additional data, and it is recommended to always consult current interpretation systems for analysing resistance test results.
Antiviral activity of Kaletra in patients failing protease inhibitor therapy
The clinical relevance of reducedin vitro susceptibility to lopinavir has been examined by assessing the virologic response to Kaletra therapy, with respect to baseline viral genotype and phenotype, in 56 patients previous failing therapy with multiple protease inhibitors. The EC50 of lopinavir against the 56 baseline viral isolates ranged from 0.6 to 96-fold higher than the EC50 against wild type HIV. After 48 weeks of treatment with Kaletra, efavirenz and nucleoside reverse transcriptase inhibitors, plasma HIV RNA ≤ 400 copies/ml was observed in 93% (25/27), 73% (11/15), and 25% (2/8) of patients with < 10-fold, 10 to 40-fold, and > 40-fold reduced susceptibility to lopinavir at baseline, respectively. In addition, virologic response was observed in 91% (21/23), 71% (15/21) and 33% (2/6) patients with 0 − 5, 6 − 7, and 8 − 10 mutations of the above mutations in HIV protease associated with reducedin vitro susceptibility to lopinavir. Since these patients had not previously been exposed to either Kaletra or efavirenz, part of the response may be attributed to the antiviral activity of efavirenz, particularly in patients harbouring highly lopinavir resistant virus. The study did not contain a control arm of patients not receiving Kaletra.
Cross-resistance
Activity of other protease inhibitors against isolates that developed incremental resistance to lopinavir after Kaletra therapy in protease inhibitor experienced patients: The presence of cross resistance to other protease inhibitors was analysed in 18 rebound isolates that had demonstrated evolution of resistance to lopinavir during 3 Phase II and one Phase III studies of Kaletra in protease inhibitor-experienced patients. The median fold IC50 of lopinavir for these 18 isolates at baseline and rebound was 6.9- and 63-fold, respectively, compared to wild type virus. In general, rebound isolates either retained (if cross-resistant at baseline) or developed significant cross-resistance to indinavir, saquinavir and atazanavir. Modest decreases in amprenavir activity were noted with a median increase of IC50from 3.7- to 8-fold in the baseline and rebound isolates, respectively. Isolates retained susceptibility to tipranavir with a median increase of IC50 in baseline and rebound isolates of 1.9- and 1.8–fold, respectively, compared to wild type virus. Please refer to the Aptivus Summary of Product Characteristics for additional information on the use of tipranavir, including genotypic predictors of response, in treatment of lopinavir-resistant HIV-1 infection.
Clinical results
The effects of Kaletra (in combination with other antiretroviral agents) on biological markers (plasma HIV RNA levels and CD4+ T-cell counts) have been investigated in controlled studies of Kaletra of 48 to 360 weeks duration.
Adult Use
Patients without prior antiretroviral therapy
Study M98-863 was a randomised, double-blind trial of 653 antiretroviral treatment naïve patients investigating Kaletra (400/100 mg twice daily) compared to nelfinavir (750 mg three times daily) plus stavudine and lamivudine. Mean baseline CD4+ T-cell count was 259 cells/mm3 (range: 2 to 949 cells/ mm3) and mean baseline plasma HIV-1 RNA was 4.9 log10copies/ml (range: 2.6 to 6.8 log10copies/ml).
Table 1
Outcomes at Week 48: Study M98-863 |
||
|
Kaletra (N=326) |
Nelfinavir (N=327) |
HIV RNA < 400 copies/ml* |
75% |
63% |
HIV RNA < 50 copies/ml*† |
67% |
52% |
Mean increase from baseline in CD4+ T-cell count (cells/mm3) |
207 |
195 |
* intent to treat analysis where patients with missing values are considered virologic failures
† p < 0.001
One-hundred thirteen nelfinavir-treated patients and 74 lopinavir/ritonavir-treated patients had an HIV RNA above 400 copies/ml while on treatment from Week 24 through Week 96. Of these, isolates from 96 nelfinavir-treated patients and 51 lopinavir/ritonavir-treated patients could be amplified for resistance testing. Resistance to nelfinavir, defined as the presence of the D30N or L90M mutation in protease, was observed in 41/96 (43%) patients. Resistance to lopinavir, defined as the presence of any primary or active site mutations in protease (see above), was observed in 0/51 (0%) patients. Lack of resistance to lopinavir was confirmed by phenotypic analysis.
Sustained virological response to Kaletra (in combination with nucleoside/nucleotide reverse transcriptase inhibitors) has been also observed in a small Phase II study (M97-720) through 360 weeks of treatment. One hundred patients were originally treated with Kaletra in the study (including 51 patients receiving 400/100 mg twice daily and 49 patients at either 200/100 mg twice daily or 400/200 mg twice daily). All patients converted to open-label Kaletra at the 400/100 mg twice daily dose between week 48 and week 72. Thirty-nine patients (39%) discontinued the study, including 16 (16%) discontinuations due to adverse events, one of which was associated with a death. Sixty-one patients completed the study (35 patients received the recommended 400/100 mg twice daily dose throughout the study).
Table 2
Outcomes at Week 360: Study M97-720 |
|
|
Kaletra (N=100) |
HIV RNA < 400 copies/ml |
61% |
HIV RNA < 50 copies/ml |
59% |
Mean increase from baseline in CD4+ T-cell count (cells/mm3) |
501 |
Through 360 weeks of treatment, genotypic analysis of viral isolates was successfully conducted in 19 of 28 patients with confirmed HIV RNA above 400 copies/ml revealed no primary or active site mutations in protease (amino acids at positions 8, 30, 32, 46, 47, 48, 50, 82, 84 and 90) or protease inhibitor phenotypic resistance.
Patients with prior antiretroviral therapy
M97-765 is a randomised, double-blind trial evaluating Kaletra at two dose levels (400/100 mg and 400/200 mg, both twice daily) plus nevirapine (200 mg twice daily) and two nucleoside reverse transcriptase inhibitors in 70 single protease inhibitor experienced, non-nucleoside reverse transcriptase inhibitor naïve patients. Median baseline CD4 cell count was 349 cells/mm3 (range 72 to 807 cells/mm3) and median baseline plasma HIV-1 RNA was 4.0 log10copies/ml (range 2.9 to 5.8 log10 copies/ml).
Table 3
Outcomes at Week 24: Study M97-765 |
|
|
Kaletra 400/100 mg (N=36) |
HIV RNA < 400 copies/ml (ITT)* |
75% |
HIV RNA < 50 copies/ml (ITT)* |
58% |
Mean increase from baseline in CD4+ T-cell count (cells/mm3) |
174 |
* intent to treat analysis where patients with missing values are considered virologic failures
M98-957 is a randomised, open-label study evaluating Kaletra treatment at two dose levels (400/100 mg and 533/133 mg, both twice daily) plus efavirenz (600 mg once daily) and nucleoside reverse transcriptase inhibitors in 57 multiple protease inhibitor experienced, non-nucleoside reverse transcriptase inhibitor naïve patients. Between week 24 and 48, patients randomised to a dose of 400/100 mg were converted to a dose of 533/133 mg. Median baseline CD4 cell count was 220 cells/mm3 (range13 to 1030 cells/mm3).
Table 4
Outcomes at Week 48: Study M98-957 |
|
|
Kaletra 400/100 mg (N=57) |
HIV RNA < 400 copies/ml* |
65% |
Mean increase from baseline in CD4+ T-cell count (cells/mm3) |
94 |
* intent to treat analysis where patients with missing values are considered virologic failures
Paediatric Use
M98-940 was an open-label study of a liquid formulation of Kaletra in 100 antiretroviral naïve (44%) and experienced (56%) paediatric patients. All patients were non-nucleoside reverse transcriptase inhibitor naïve. Patients were randomised to either 230 mg lopinavir/57.5 mg ritonavir per m2 or 300 mg lopinavir/75 mg ritonavir per m2. Naïve patients also received nucleoside reverse transcriptase inhibitors. Experienced patients received nevirapine plus up to two nucleoside reverse transcriptase inhibitors. Safety, efficacy and pharmacokinetic profiles of the two dose regimens were assessed after 3 weeks of therapy in each patient. Subsequently, all patients were continued on the 300/75 mg per m2 dose. Patients had a mean age of 5 years (range 6 months to 12 years) with 14 patients less than 2 years old and 6 patients one year or less. Mean baseline CD4+ T-cell count was 838 cells/mm3 and mean baseline plasma HIV-1 RNA was 4.7 log10copies/ml.
Table 5
Outcomes at Week 48: Study M98-940* |
||
|
Antiretroviral Naïve (N=44) |
Antiretroviral Experienced (N=56) |
HIV RNA < 400 copies/ml |
84% |
75% |
Mean increase from baseline in CD4+ T-cell count (cells/mm3) |
404 |
284 |
* intent to treat analysis where patients with missing values are considered virologic failures
Study P1030 was an open-label, dose-finding trial evaluating the pharmacokinetic profile, tolerability, safety and efficacy of Kaletra oral solution at a dose of 300 mg lopinavir/75 mg ritonavir per m2twice daily plus 2 NRTIs in HIV-1 infected infants ≥ 14 days and < 6 months of age. At entry, median (range) HIV-1 RNA was 6.0 (4.7-7.2) log10 copies/ml and median (range) CD4+T-cell percentage was 41 (16-59).
Table 6
Outcomes at Week 24: Study P1030 |
||
|
Age: ≥ 14 days and < 6 weeks (N=10) |
Age: ≥ 6 weeks and < 6 months (N=21) |
HIV RNA < 400 copies/ml* |
70% |
48% |
Median change from baseline in CD4+ T-cell count (cells/mm3) |
- 1% (95% CI: -10, 18) (n=6) |
+ 4% (95% CI: -1, 9) (n=19) |
*Proportion of subjects who had HIV-1 < 400 copies/ml and had remained on study treatment
Study P1060 was a randomised controlled trial of nevirapine versus lopinavir/ritonavir-based therapy in subjects 2 to 36 months of age infected with HIV-1 who had (Cohort I) and had not (Cohort II) been exposed to nevirapine during pregnancy for prevention of mother-to-child transmission. Lopinavir/ritonavir was administered twice daily at 16/4 mg/kg for subjects 2 months to < 6 months, 12/3 mg/kg for subjects ≥ 6 months and < 15 kg, 10/2.5 mg/kg for subjects ≥ 6 months and ≥ 15 kg to < 40 kg, or 400/100 mg for subjects ≥ 40 kg. The nevirapine-based regimen was 160-200 mg/m2 once daily for 14 days, then 160-200 mg/m2 every 12 hours. Both treatment arms included zidovudine 180 mg/m2 every 12 hours and lamivudine 4 mg/kg every 12 hours. The median follow-up was 48 weeks in Cohort I and 72 weeks in Cohort II. At entry, median age was 0.7 years, median CD4 T-cell count was 1147 cells/mm3, median CD4 T-cell was 19%, and median HIV-1 RNA was > 750,000 copies/ml. Among 13 subjects with viral failure in the lopinavir/ritonavir group with resistance data available no resistance to lopinavir/ritonavir was found.
Table 7
Outcomes at Week 24: Study P1060 |
||||
|
Cohort I |
Cohort II |
||
|
lopinavir/ritonavir (N=82) |
nevirapine (N=82) |
lopinavir/ritonavir (N=140) |
nevirapine (N=147) |
Virologic failure* |
21.7% |
39.6% |
19.3% |
40.8% |
*Defined as confirmed plasma HIV-1 RNA level > 400 copies/ml at 24 weeks or viral rebound > 4000 copies/ml after Week 24. Overall failure rate combining the treatment differences across age strata, weighted by the precision of the estimate within each age stratum
p=0.015 (Cohort I); p< 0.001 (Cohort II)
The CHER study was a randomized, open-label study comparing 3 treatment strategies (deferred treatment, early treatment for 40 weeks, or early treatment for 96 weeks) in children with perinatally acquired HIV-1 infection. The treatment regimen was zidovudine plus lamivudine plus 300 mg lopinavir/75 mg ritonavir per m2 twice daily until 6 months of age, then 230 mg lopinavir/57.5 mg ritonavir per m2 twice daily. There were no reported events of failure attributed to therapy limiting toxicity.
Table 8
Hazard Ratio for Death or Failure of First-line Therapy Relative to ART Deferred Treatment: CHER Study |
||
|
40 week arm (N=13) |
96 week arm (N=13) |
Hazard ratio for death or failure of therapy* |
0.319 |
0.332 |
* Failure defined as clinical, immunological disease progression, virological failure or regimen limiting ART toxicity
p=0.0005 (40 week arm); p< 0.0008 (96 week arm)
5.2 Pharmacokinetic properties
The pharmacokinetic properties of lopinavir co-administered with ritonavir have been evaluated in healthy adult volunteers and in HIV-infected patients; no substantial differences were observed between the two groups. Lopinavir is essentially completely metabolised by CYP3A. Ritonavir inhibits the metabolism of lopinavir, thereby increasing the plasma levels of lopinavir. Across studies, administration of Kaletra 400/100 mg twice daily yields mean steady-state lopinavir plasma concentrations 15 to 20-fold higher than those of ritonavir in HIV-infected patients. The plasma levels of ritonavir are less than 7% of those obtained after the ritonavir dose of 600 mg twice daily. Thein vitro antiviral EC50 of lopinavir is approximately 10-fold lower than that of ritonavir. Therefore, the antiviral activity of Kaletra is due to lopinavir.
Absorption
Multiple dosing with 400/100 mg Kaletra twice daily for 2 weeks and without meal restriction produced a mean ± SD lopinavir peak plasma concentration (Cmax) of 12.3 ± 5.4 μg/ml, occurring approximately 4 hours after administration. The mean steady-state trough concentration prior to the morning dose was 8.1 ± 5.7 μg/ml. Lopinavir AUC over a 12 hour dosing interval averaged 113.2 ± 60.5 μg•h/ml. The absolute bioavailability of lopinavir co-formulated with ritonavir in humans has not been established.
Effects of food on oral absorption
Kaletra soft capsules and liquid have been shown to be bioequivalent under nonfasting conditions (moderate fat meal). Administration of a single 400/100 mg dose of Kaletra soft capsules with a moderate fat meal (500 – 682 kcal, 22.7 –25.1% from fat) was associated with a mean increase of 48% and 23% in lopinavir AUC and Cmax, respectively, relative to fasting. For Kaletra oral solution, the corresponding increases in lopinavir AUC and Cmax were 80% and 54%, respectively. Administration of Kaletra with a high fat meal (872 kcal, 55.8% from fat) increased lopinavir AUC and Cmax by 96% and 43%, respectively, for soft capsules, and 130% and 56%, respectively, for oral solution. To enhance bioavailability and minimise variability Kaletra is to be taken with food.
Distribution
At steady state, lopinavir is approximately 98 − 99% bound to serum proteins. Lopinavir binds to both alpha-1-acid glycoprotein (AAG) and albumin however, it has a higher affinity for AAG. At steady state, lopinavir protein binding remains constant over the range of observed concentrations after 400/100 mg Kaletra twice daily, and is similar between healthy volunteers and HIV-positive patients.
Biotransformation
In vitro experiments with human hepatic microsomes indicate that lopinavir primarily undergoes oxidative metabolism. Lopinavir is extensively metabolised by the hepatic cytochrome P450 system, almost exclusively by isozyme CYP3A. Ritonavir is a potent CYP3A inhibitor which inhibits the metabolism of lopinavir and therefore, increases plasma levels of lopinavir. A14C-lopinavir study in humans showed that 89% of the plasma radioactivity after a single 400/100 mg Kaletra dose was due to parent active substance. At least 13 lopinavir oxidative metabolites have been identified in man. The 4-oxo and 4-hydroxymetabolite epimeric pair are the major metabolites with antiviral activity, but comprise only minute amounts of total plasma radioactivity. Ritonavir has been shown to induce metabolic enzymes, resulting in the induction of its own metabolism, and likely the induction of lopinavir metabolism. Pre-dose lopinavir concentrations decline with time during multiple dosing, stabilising after approximately 10 days to 2 weeks.
Elimination
After a 400/100 mg14C-lopinavir/ritonavir dose, approximately 10.4 ± 2.3% and 82.6 ± 2.5% of an administered dose of14C-lopinavir can be accounted for in urine and faeces, respectively. Unchanged lopinavir accounted for approximately 2.2% and 19.8% of the administered dose in urine and faeces, respectively. After multiple dosing, less than 3% of the lopinavir dose is excreted unchanged in the urine. The effective (peak to trough) half-life of lopinavir over a 12 hour dosing interval averaged 5 − 6 hours, and the apparent oral clearance (CL/F) of lopinavir is 6 to 7 l/h.
Special Populations
Paediatrics
Data from clinical trials in children below 2 years of age include the pharmacokinetics of Kaletra 300/75 mg/m2 twice daily studied in a total of 31 paediatric patients, ranging in age from 14 days to 6 months. The pharmacokinetics of Kaletra 300/75 mg/m2 twice daily with nevirapine and 230/57.5 mg/ m2 twice daily alone have been studied in 53 paediatric patients ranging in age from 6 months to 12 years. The mean (SD) for the studies are reported in the table below. The 230/57.5 mg/m2 twice daily regimen without nevirapine and the 300/75 mg/m2 twice daily regimen with nevirapine provided lopinavir plasma concentrations similar to those obtained in adult patients receiving the 400/100 mg twice daily regimen without nevirapine.
Cmax (μg/ml) |
Cmin (μg/ml) |
AUC12 (μg•h/ml) |
Age ≥ 14 days to < 6 weeks cohort (N = 9): |
||
5.17 (1.84) |
1.40 (0.48) |
43.39 (14.80) |
Age ≥ 6 weeks to < 6 months cohort (N = 18): |
||
9.39 (4.91) |
1.95 (1.80) |
74.50 (37.87) |
Age ≥ 6 months to < 12 years cohort (N = 53): |
||
8.2 (2.9)a |
3.4 (2.1)a |
72.6 (31.1)a |
10.0 (3.3)b |
3.6 (3.5)b |
85.8 (36.9)b |
Adultc |
||
12.3 (5.4) |
8.1 (5.7) |
113.2 (60.5) |
a. Kaletra oral solution 230/57.5 mg/m2 twice daily regimen without nevirapine
b. Kaletra oral solution 300/75 mg/m2 twice daily regimen with nevirapine
c. Kaletra film-coated tablets 400/100 mg twice daily at steady state
Gender, Race and Age
Kaletra pharmacokinetics have not been studied in older people. No age or gender related pharmacokinetic differences have been observed in adult patients. Pharmacokinetic differences due to race have not been identified.
Renal Insufficiency
Kaletra pharmacokinetics have not been studied in patients with renal insufficiency; however, since the renal clearance of lopinavir is negligible, a decrease in total body clearance is not expected in patients with renal insufficiency.
Hepatic Insufficiency
The steady state pharmacokinetic parameters of lopinavir in HIV-infected patients with mild to moderate hepatic impairment were compared with those of HIV-infected patients with normal hepatic function in a multiple dose study with lopinavir/ritonavir 400/100 mg twice daily. A limited increase in total lopinavir concentrations of approximately 30% has been observed which is not expected to be of clinical relevance (see section 4.2).
5.3 Preclinical safety data
Repeat-dose toxicity studies in rodents and dogs identified major target organs as the liver, kidney, thyroid, spleen and circulating red blood cells. Hepatic changes indicated cellular swelling with focal degeneration. While exposure eliciting these changes were comparable to or below human clinical exposure, dosages in animals were over 6-fold the recommended clinical dose. Mild renal tubular degeneration was confined to mice exposed with at least twice the recommended human exposure; the kidney was unaffected in rats and dogs. Reduced serum thyroxin led to an increased release of TSH with resultant follicular cell hypertrophy in the thyroid glands of rats. These changes were reversible with withdrawal of the active substance and were absent in mice and dogs. Coombs-negative anisocytosis and poikilocytosis were observed in rats, but not in mice or dogs. Enlarged spleens with histiocytosis were seen in rats but not other species. Serum cholesterol was elevated in rodents but not dogs, while triglycerides were elevated only in mice.
During in vitro studies, cloned human cardiac potassium channels (HERG) were inhibited by 30% at the highest concentrations of lopinavir/ritonavir tested, corresponding to a lopinavir exposure 7-fold total and 15-fold free peak plasma levels achieved in humans at the maximum recommended therapeutic dose. In contrast, similar concentrations of lopinavir/ritonavir demonstrated no repolarisation delay in the canine cardiac Purkinje fibres. Lower concentrations of lopinavir/ritonavir did not produce significant potassium (HERG) current blockade. Tissue distribution studies conducted in the rat did not suggest significant cardiac retention of the active substance; 72-hour AUC in heart was approximately 50% of measured plasma AUC. Therefore, it is reasonable to expect that cardiac lopinavir levels would not be significantly higher than plasma levels.
In dogs, prominent U waves on the electrocardiogram have been observed associated with prolonged PR interval and bradycardia. These effects have been assumed to be caused by electrolyte disturbance.
The clinical relevance of these preclinical data is unknown, however, the potential cardiac effects of this product in humans cannot be ruled out (see also sections 4.4 and 4.8).
In rats, embryofoetotoxicity (pregnancy loss, decreased foetal viability, decreased foetal body weights, increased frequency of skeletal variations) and postnatal developmental toxicity (decreased survival of pups) was observed at maternally toxic dosages. The systemic exposure to lopinavir/ritonavir at the maternal and developmental toxic dosages was lower than the intended therapeutic exposure in humans.
Long-term carcinogenicity studies of lopinavir/ritonavir in mice revealed a nongenotoxic, mitogenic induction of liver tumours, generally considered to have little relevance to human risk. Carcinogenicity studies in rats revealed no tumourigenic findings. Lopinavir/ritonavir was not found to be mutagenic or clastogenic in a battery ofin vitro andin vivo assays including the Ames bacterial reverse mutation assay, the mouse lymphoma assay, the mouse micronucleus test and chromosomal aberration assays in human lymphocytes.
6. Pharmaceutical particulars
6.1 List of excipients
Oral solution contains:
alcohol (42.4% v/v),
high fructose corn syrup,
propylene glycol (15.3% w/v),
purified water,
glycerol,
povidone,
magnasweet-110 flavour (mixture of monoammonium glycyrrhizinate and glycerol),
vanilla flavour (containing p-hydroxybenzoic acid, p-hydroxybenzaldehyde, vanillic acid, vanillin, heliotropin, ethyl vanillin),
polyoxyl 40 hydrogenated castor oil,
cotton candy flavour (containing ethyl maltol, ethyl vanillin, acetoin, dihydrocoumarin, propylene glycol),
acesulfame potassium,
saccharin sodium,
sodium chloride,
peppermint oil,
sodium citrate,
citric acid,
levomenthol.
6.2 Incompatibilities
Not applicable.
6.3 Shelf life
2 years
6.4 Special precautions for storage
Store in a refrigerator (2°C - 8°C).
In use storage: If kept outside of the refrigerator, do not store above 25°C and discard any unused contents after 42 days (6 weeks). It is advised to write the date of removal from the refrigerator on the package.
6.5 Nature and contents of container
Kaletra oral solution is supplied in amber coloured multiple-dose polyethylene terephthalate (PET) bottles in a 60 ml size.
Two pack sizes are available for Kaletra oral solution:
- 120 ml (2 bottles x 60 ml) with 2 x 2 ml syringes with 0.1 ml graduations
For volumes up to 2 ml. For larger volumes an alternative pack is available.
- 300 ml (5 bottles x 60 ml) with 5 x 5 ml syringes with 0.1 ml graduations
For volumes greater than 2 ml. For smaller volumes an alternative pack is available.
6.6 Special precautions for disposal and other handling
No special requirements.
7. Marketing authorisation holder
AbbVie Deutschland GmbH & Co. KG
Knollstrasse
67061 Ludwigshafen
Germany
8. Marketing authorisation number(s)
EU/1/01/172/003
EU/1/01/172/009
9. Date of first authorisation/renewal of the authorisation
Date of first authorisation: 20 March 2001
Date of latest renewal: 20 March 2011
10. Date of revision of the text
31 October 2019
Detailed information on this product is available on the website of the European Medicines Agency http://www.ema.europa.eu
Company contact details
AbbVie Ltd
Address
AbbVie House, Vanwall Business Park, Vanwall Road, Maidenhead, Berkshire, SL6 4UB, UK