Caffeine Citrate in Neonatal Intensive Care Unit
Korraa, A. (2023). Caffeine Citrate in Neonatal Intensive Care Unit. EKB Journal Management System, 5(2), 7-18. doi: 10.21608/anj.2023.223483.1069
Afaf A. Korraa. "Caffeine Citrate in Neonatal Intensive Care Unit". EKB Journal Management System, 5, 2, 2023, 7-18. doi: 10.21608/anj.2023.223483.1069
Korraa, A. (2023). 'Caffeine Citrate in Neonatal Intensive Care Unit', EKB Journal Management System, 5(2), pp. 7-18. doi: 10.21608/anj.2023.223483.1069
Korraa, A. Caffeine Citrate in Neonatal Intensive Care Unit. EKB Journal Management System, 2023; 5(2): 7-18. doi: 10.21608/anj.2023.223483.1069

Caffeine Citrate in Neonatal Intensive Care Unit

Annals of Neonatology
Article 2, Volume 5, Issue 2, July 2023, Page 7-18  XML PDF (511.48 K)
Document Type: Review Article
DOI: 10.21608/anj.2023.223483.1069
View on SCiNiTO View on SCiNiTO
Author
Afaf A. Korraa email
Pediatric Department, Faculty of Medicine, Al-Azhar University, Egypt
Abstract
Apnea is a common condition in premature infants due to the immaturity of respiratory control mechanisms. Incidence increases with younger gestational age and lower birth weight, afflicting 25% of infants under 2500 g and 80% under 1000 g . Recurrent apnea can lead to respiratory failure, pulmonary hemorrhage , abnormal lung function, intracranial hemorrhage, abnormal neurodevelopment and even sudden death.
Caffeine is the most frequently used medication in the neonatal intensive care unit. It is used for the prevention and treatment of apnea, although this drug has been associated with lower incidence of bronchopulmonary dysplasia (BPD) and patent ductus arteriosus as well as intact survival at 18-21 months of life. The mechanism of action of caffeine on prevention of apnea and activation of breathing seems to be through central inhibition of adenosine receptors.
Caffeine has a long half-life of around 100 hours, thus it can be safely given once daily and has less toxicity than the other methyl xanthines. It has a wider therapeutic to toxic ratio and has reliable enteral absorption

Highlights

Conflict of interest

The author had no conflict of interests to declare.

Funding

This study received no special funding

Author's details

Pediatric Department, Faculty of Medicine for girls , Al-Azhar University, Egypt

Date received: 18th June 2023, accepted 28rd July 2023

Keywords
Caffeine citrate; NICU; Apnea of prematurity; bronchopulmonary dysplasia
Full Text

Introduction

Caffeine citrate is a drug that is frequently used in the neonatal intensive care unit (NICU) to treat premature infants with apnea.  It decreases the frequency of apneic episodes, thus reducing the need for mechanical ventilation [1].

The pharmacokinetic profile of caffeine in preterm infants, proof of its protection and efficacy of various doses of caffeine is a matter of debate. Polymorphisms in pharmacodynamics-associated genes have a huge effect at the interindividual variability in the clinical response to caffeine therapy [2, 3].

Therapeutic effect of caffeine

Apnea of prematurity

Apnea of prematurity is a developmental disorder caused by immaturity of the respiratory control mechanisms, and consequently exhibited a widely variable. It was predicted to occur in almost all infants born at less than 28 wk gestation or extremely low birth weight infants ( less than 1000 g). [4]

In the CAP trial , the reviewers concluded that caffeine to be the (desired drug ) for the treatment of apnea of prematurity. Besides apnea of prematurity, caffeine became additionally obsereved to be powerful in different causes of apnea like post-operarive apnea, anesthesia - associated apnea and viral infection-associated apneas, and apneas related to obvious life-threatening events.

Ventilation

In a subsequent report of the CAP trial, the researchers observe a reduction of duration of mechanical ventilation in those who received caffeine in the first 3 d of life [5, 6].

Bronchopulmonary dysplasia

Bronchopulmonary dysplasia (BPD) is a well-known problem in preterm infants, which can be related to significant mortality, using early caffeine citrate within the first 3 days of life is related to a decrease occurrence of BPD compared with later use [7].

Prevention of extubation failure

Several trials proof that high dose caffeine in the periextubation period decreased extubation failure in addition to the mechanical ventilation duration. [8]

Caffeine might enhance breathing mechanics via enhancing breathing muscle strength, inducing diuresis and subsequently enhancing lung compliance [9].

Bronchiolitis-related apnea

Premature infants are more vulnerable to bronchiolitis-related apnea. Randomised-controlled trils have shown the efficacy and safety of caffeine as a treatment of bronchiolitis-related apnea [10].

Intermittent hypoxemia

Intermittent hypoxemia (IH) is described as brief, repetitive episodes of reduced hemoglobin oxygen saturation from a normoxic baseline followed by reoxygenation. Caffeine use in late preterm infants (35–36 weeks) may reduce episodes of intermittent hypoxaemia and improve long-term outcomes for these infants [11, 12].

Patent ductus arteriosus

Caffeine use has been related to PDA closure . Other researches additionally confirmed that early caffeine use ,within  three days, was associated with less intervention for PDA in comparison to later caffeine use. The useful impact of caffeine on PDA can be correlated with its diuretic and anti-prostaglandin effects. [13]

Neurodevelopmental outcome

Prolonged caffeine consumption might also have a neuroprotective effect, possibly via up regulating adenosine A1 receptors. The CAP trial confirmed decreased probability of death, and neurocognitive impairment at 18 months post menstrual age  in  babies  weighing less than 1250 g. Follow up of CAP trial at 5 years, did not show any distinction in the final results of death or intense impairment. The actual mechanism may be related to the ability of caffeine to lessen intermittent hypoxia and possibly to its direct neuroprotective effect [14, 15].

Renal

Caffeine exerts a diuretic effect via increasing creatinine clearance, as a hallmark of GFR, within 12 h of administration. caffeine has no effect on serum calcium, phosphorus, sodium, or potassium concentrations [16].

Retinopathy of Prematurity (ROP)

The CAP trial showed reduced incidence of severe retinopathy of prematurity in caffeine group when compared to placebo (5.1% vs. 7.9% with adjusted odds ratio 0.61). This effect would perhaps be explained by reduced oxygen and ventilation days and reduced incidence of intermittent hypoxia with caffeine group [17].

Gastrointestinal 

Mehtylxanthines might also worsen reflux through delayed gastric emptying and reducing tone of lower oesophageal sphincter, in addition they increase gastrin secretion. Researches did not prove  increase of gasrtro esophageal reflux   symptoms in preterm infants treated by caffeine [18,19].

Caffeine citrate administration  in a single loading dose  20 mg/kg intravenous did not cause significant modification in mesenteric blood flow velocities, whereas at a higher dose (25 to 50 mg/kg) had been reported to be associated with a reduction of mesenteric blood flow velocities [20,21].

Inflammatory effect

Caffeine has an immunomodulatory effects which may be related to blocking of adenosine receptors located on the surface of immune. Chavez Valdez et al [22]. Results revealed that caffeine levels within (10-20 mg/L) were associated with a decrease in pro-inflammatory cytokines (interleukin-6, TNFα) levels, and an increase in anti-inflammatory cytokine (interleukin) levels. However, caffeine levels outside the therapeutic range have been related to a proinflammatory profile [23].

Anti-in Growth

The CAP trial found out that infants under the caffeine therapy gained less weight than those in the control group during the first 3 wk after treatment [5].

Indications to start Caffeine

Ensure that there is no other attributable cause for apnea (i.e., infection, seizure, CNS abnormality).

Less than 30 weeks gestation: birthweight less than1250 g

Administer caffeine for prophylaxis in the non-mechanically ventilated infant

Administer caffeine to infants demonstrating apnea

Administer caffeine to infants to be extubated in the first 10 postnatal days

Avoid routine use of caffeine in preterm infants likely to remain mechanically ventilated beyond 10 postnatal days (Amaro et al) because of non-statistically significant increase in mortality

Equal or More than 30 weeks gestation:

- Administer caffeine if apnea persists after initiating respiratory support (e.g., on CPAP)

Facilitate extubation from mechanical ventilation: For all infants, regardless of gestational age or postnatal age, consider caffeine load prior to extubation [25].

Administration

Loading dose: 20 mg/kg

Maintenance dose: Initial maintenance dose suggested- 5 mg/kg every 24 hours

Maintenance dosing range 5-10 mg/kg

Monitoring: Clinical response; consider holding dose if HR >180

Adverse Effects: Tachycardia, restlessness, vomiting, decreased seizure threshold [26]

Higher maintenance doses of caffeine citrate (10-20mg /kg/day) mg was more effective and safer than low maintenance doses (5mg-10mg /kg/day) for treatment of premature apnea, despite a higher incidence of tachycardia [27].

Discontinuing Caffeine therapy

Infants who have been treated with caffeine must complete an apnea free countdown prior to discharge.

The countdown may begin once at least 3 days have passed since the child's last caffeine dose, the patient is off positive pressure support, or the child is 36 weeks gestational age, whichever comes first. [26]

Patient should demonstrate at least 8 days without experiencing any apnea prior to discharge. Document this in the chart as day 1 of 8 day apnea free countdown, day 2 of 8 apnea free countdown, etc.

However, caffeine may not reach sub-therapeutic levels until 11-12 days post-cessation [28].

The degree of respiratory stability and signs of caffeine-induced toxicity can both influence a clinician's decision to discontinue caffeine therapy [29].

Contraindications

Simultaneous administration of other xanthine preparations .

gastriintastinal bleeding, liver or renal dysfunction

Heart rate greater than180 beats per minute.

Approximate time to reach steady state blood levels is 5–6 days (i.e. apnoea may occur until steady state is reached, despite loading dose) [29]

Practical points

European Consensus Guidelines on the Management of Respiratory Distress Syndrome: Caffeine should be used to facilitate weaning from MV (High quality; Strong recommendation for using intervention) [30]

Early caffeine should be considered for babies at high risk of needing MV such as those on non-invasive respiratory support (Low quality; Strong recommendation for using intervention).

AAP Committee on fetus and newborn: Caffeine citrate is a safe and effective treatment of apnea of prematurity when administered at a 20-mg/kg loading dose and 5 to 10 mg/kg per day maintenance [31]

Impact

Extremely premature neonates with a lower birth weight may require higher weight-based caffeine dosing due to their higher weight-adjusted clearance and shorter half-lives.

Higher caffeine citrate dosing (e.g. 10 mg/kg/day maintenance dose) than the standard dose (5 mg/kg/day maintenance dose ) may be needed to further prevent bronchopulmonary dysplasia. [26]

Conclusions

Caffeine citrate is not only considered as the preferred drug for treatment and prevention of apnea of prematurity, it also used in treatment of other types of apnea. It may be used as a therapeutic drug in NICU for reduction in chronic lung disease, improvement in extubation failure within 7 days, prevention of postoperative apnea and its diuretic effect.

References
    1. Hsieh EM, Hornik CP, Clark RH, Laughon MM, Benjamin DK, Smith PB. Medication use in the neonatal intensive care unit. Am J Perinatol. 2014; 31:811–821.
    2. Long J-Y, Guo H-L, He X, Hu Y-H, Xia Y, Cheng R, Ding X-S, et al. Caffeine for the Pharmacological Treatment of Apnea of Prematurity in the NICU: Dose Selection Conundrum, Therapeutic Drug Monitoring and Genetic Factors.  Pharmacol 2021; 12: 681842.doi:10.3389/fphar.2021.6818 42
    3. Katie Farmer, Alison Pike & Mel Guilder: Guideline for Caffeine use in preterm infants, Jan 2016, South West Neonatal Network
    4. Dekker J, Hooper SB, van Vonderen JJ. Caffeine to improve breathing effort of preterm infants at birth: a randomized controlled trial. Pediatr Res2017; 82: 290–296. doi: 10.1038/ pr.2017.45
    5. Schmidt B. Methyl-xanthine therapy for apnea of prematurity: evaluation of treatment benefits and risks at age 5 years in the international Caffeine for Apnea of Prematurity (CAP) trial. Biol Neonate 2005;88:208-213
    6. Schmidt B, Roberts RS, Davis P. Long term effects of Caffeine Therapy for Apnea of Prematurity (CAP trial), N Engl J Med 2007; 357(19): 1893 -1902.
    7. Amaro CM, Bello JA, Jain D, Ranmath A, D’Ugard C, VanbuskirkS, et al. Early Caffeine and Weaning from Mechanical Ventilation in Preterm Infants: A Randomized Placebo-Controlled Trial. J Pediatircs, 2018; 196: 52-57.
    8. Roehr CC, Bohlin K. Neonatal resuscitation and respiratory support in prevention of bronchopulmonary dysplasia. Breathe2011; 8: 14–23. doi: 10.1183/20734735.003811
    9. Steer PA, Flenady VJ, Shearman A. Periextubation caffeine in preterm neonates: a randomized dose response trial. J Paediatr Child Health2003; 39:511–515.doi:10.10 46/ j.1440-1754.2003.00207.x
    10. Steer P, Flenady V, Shearman A. High dose caffeine citrate for extubation of preterm infants: a randomised controlled trial. Arch Dis Child Fetal Neonatal Ed2004; 89: F499–F503. doi: 10.1136/ adc.2002. 023432 
    11. Heuzé N,  Goyer I , Porcheret F ,  DenisM ,  FauconC ,  Jokic M, Brossier  D: Caffeine treatment for bronchiolitis-related apnea in the pediatric intensive care unit. Arch Pediatr, 2020; 27(1):18-23.
    12. Rhein LM, Dobson NR, Darnall RA. Effects of caffeine on intermittent hypoxia in infants born prematurely: a randomized clinical trial. JAMA Pediatr2014; 168: 250–257. doi: 10.1001/ jamapediatrics. 2013.4371
    13. Poets CF, Roberts RS, Schmidt B. Association between intermittent hypoxemia or bradycardia and late death or disability in extremely preterm infants. JAMA2015; 314: 595–603. doi:10.1001/jama.2015. 8841
    14. Patel RM, Leong T, Carlton DP, Vyas-Read S. Early caffeine therapy and clinical outcomes in extremely preterm infants. J Perinatol. 2013; 33:134–140. 
    15. Atik A, Harding R, De Matteo R. Caffeine for apnea of prematurity: effects on the developing brain. Neurotoxicology2017; 58: 94–102. doi: 10.1016/j.neuro.2016.11.012
    16. Parikka V, Beck J, Zhai Q. The effect of caffeine citrate on neural breathing pattern in preterm infants. Early Hum Dev2015; 91: 565–568. doi: 10.1016/j.earlhumdev.2015.06.007.
    17. Gillot I, Gouyon JB, Guignard JP. Renal effects of caffeine in preterm infants. Biol Neonate 1990; 58: 133–136. doi: 10.1159/000243252
    18. Chen JF, Zhang S, Zhou R, Lin Z, Cai X, Lin J, Huo Y, Liu X. Adenosine receptors and caffeine in retinopathy of prematurity. Mol Aspects Med. 2017; 55:118-125.doi:10.1016/j. mam.2017.01.001.Epub 2017 Jan 11.
    19. Barrington KJ, Tan K, Rich W. Apnea at discharge and gastro-esophageal reflux in the preterm infant. J Perinatol. 2002; 22:8–11. 
    20. Di Fiore JM, Arko M, Whitehouse M, Kimball A, Martin RJ. Apnea is not prolonged by acid gastroesophageal reflux in preterm infants.  2005; 116:1059–1063. 
    21. Gounaris A, Kokori P, Varchalama L, Konstandinidi K, Skouroliakou M, Alexiou N, et al. Theophylline and gastric emptying in very low birthweight neonates: a randomised controlled trial. Arch Dis Child Fetal Neonatal Ed. 2004; 89:F297–F299. 
    22. Hoecker C, Nelle M, Poeschl J, Beedgen B, Linderkamp O. Caffeine impairs cerebral and intestinal blood flow velocity in preterm infants. 2002; 109:784–787. 
    23. Chavez-Valdez R, Wills-Karp M, Ahlawat R, Cristofalo EA, Nathan A, Gauda EB. Caffeine modulates TNF-alpha production by cord blood monocytes: the role of adenosine receptors. Pediatr Res. 2009; 65:203–208.
    24. Chavez Valdez R, Ahlawat R, Wills-Karp M, Nathan A, Ezell T, Gauda EB. Correlation between serum caffeine levels and changes in cytokine profile in a cohort of preterm infants. J Pediatr. 2011; 158:57–64
    25. Eichenw ald EC. National and international guidelines for neonatal caffeine use: Are they evidence-based? Semin Fetal Neonatal Med. 2020; 25(6):101177.
    26. Amaro CM, Bello JA, Jain D, Ranmath A, D’Ugard C, Vanbuskirk S, et al. Early Caffeine and Weaning from Mechanical Ventilation in Preterm Infants: A Randomized Placebo-Controlled Trial. J Pediatircs, 2018; 196: 52-57.
    27. Chen J, Jin L, Chen X. Efficacy and safety of different maintenance doses of caffeine citrate for treatment of apnea in premature infants: A systematic review and meta-analysis. BioMed Research International. 2018;2018
    28. Dabin Ji, Brian Smith P , Reese H. C, Kanecia O. Z, Matthew J : Wide variation in caffeine discontinuation timing in premature infants.   2020; 40(2): 288–293.
    29. Doyle J, Davidson D, Katz S, Varela M, Demeglio D, DeCristofaro J. Apnea of prematurity and caffeine pharmacokinetics: Potential impact on hospital discharge. Journal of Perinatology. Caffeine Newborn use only 2020 ANMF consensus group Caffeine Page 5 of 6 2016;36:141-4
    30. Sweet DG, Carnielli V, Greisen G, Hallman M, Ozek E, Te Pas A, Plavka R, Roehr CC, et al. European Consensus Guidelines on the Management of Respiratory Distress Syndrome 2019 Update. Neonatology 2019;115:432-50
    31. Eichenwald EC. Committee on fetus and newborn AAP. Apnea of Prematurity. Pediatrics. 2016; 137: 38-47.
Statistics
Article View: 811
PDF Download: 253