Prediction of C-reactive protein dynamics during meropenem treatment in very-low-birth-weight neonates with late-onset sepsis or pneumonia

Hiie Soeorg (1), Helgi Padari (2), Mari-Liis Ilmoja (3), Koit Herodes (1), Karin Kipper (1), Irja Lutsar (1), Tuuli Metsvaht (1, 2)

(1) University of Tartu, Estonia, (2) Tartu University Hospital, Estonia, (3) Tallinn Children’s Hospital, Estonia

Objectives. Sepsis is major cause of mortality in neonates. Blood cultures are often negative, antibiotic (AB) dosing cannot be always based on minimum inhibitory concentration (MIC) of pathogen. C-reactive protein (CRP) guided treatment has been proposed as this is a routinely measured biomarker. CRP pharmacokinetic-pharmacodynamic (PKPD) models of glycopeptides [1] or beta-lactams in adults [2] have shown that the ratio of area under the curve of AB (AUC) to AB concentration inducing half maximum AB effect (EC₅₀) is correlated with CRP decline. Thus, individualized dosing based on such PKPD index could lead to earlier resolution of infection.

We aimed to describe CRP dynamics in neonates receiving meropenem (MER) in joint PKPD model and relationship between CRP concentration during treatment and the ratio of MER AUC, MER peak or MER trough concentration to EC₅₀ and time of MER concentration above EC₅₀.

Methods. Daily CRP concentrations were collected from very-low-birth-weight (gestational age <32 weeks, birth weight <1200 g) neonates receiving MER 20 mg/kg every 12 h for late-onset sepsis or pneumonia. Previously developed one-compartment MER pharmacokinetic model [3] was used to derive empirical Bayes estimates from fixed population parameters based on MER concentrations measured in each neonate immediately before and 0.5, 1.5, 4, 8, and 12 h after one of the 4th to 7th dose of MER [3]. After fixing individual pharmacokinetic parameter estimates, PD model of CRP concentrations was estimated: K_CRPprod*C_CRP*(1- C_CRP/POP_max)-(K_CRPinh* C_CRP *(C_MER)**H/(EC₅₀**H+(C_MER)**H)) (C_CRP – CRP concentration (mg/L); C_MER – MER concentration (mg/L); K_CRPprod – maximum rate of CRP production (mg*h/L); POP_max – maximum value of CRP (mg/L); K_CRPinh – maximum rate of CRP inhibition (mg*h/L); H – slope function for CRP inhibition; EC₅₀ – MER concentration (mg/L) that produces half maximum CRP inhibition) [1]. Relationship of PKPD indices daily average MER AUC to EC₅₀ ratio (AUC₂₄:EC₅₀), percentage of time of MER concentration above EC₅₀ (T_EC50), mean ratio of MER peak concentration to EC₅₀ (C_max:EC₅₀), mean ratio of MER trough concentration to EC₅₀ (C_min:EC₅₀) with inhibition of CRP synthesis at various time periods (ratio of CRP concentration within time periods 72-96, 96-120 or 120-144 h to CRP concentration within 0-24 h after start of treatment) at log10-log10 scale was described by linear regression. Regression tree was used to find PKPD index value above which patients achieve significantly smaller CRP ratio for a given time interval.

Results. From 18 neonates (mean (range) gestational age 26.6 (24.6-30.1) w; postnatal age 16 (2-31) d; 15 (83.3%) had sepsis, 3 (16.7%) pneumonia) 180 CRP concentrations were collected. Mean (range) CRP 0-24, 72-96, 96-120 or 120-144 h after start of treatment was 67 (4-193), 36 (2-186), 25 (4-153) and 11 (5-32) mg/L, respectively.

PD model parameter estimates (standard errors) were K_CRPprod 0.046 (0.0548) mg*h/L, K_CRPinh 0.124 (0.0036) mg*h/L, EC₅₀ 24.5 (0.184) mg/L, H 14.7 (0.23). POP_max was fixed to maximum CRP value in the dataset (305 mg/L). Interindividual variability was retained only in K_CRPprod (85.6%) and EC₅₀ (96.7%). Proportional residual variability was 47.9%.

Relationship between PKPD indices and inhibition of CRP synthesis at 72-96, 96-120 and 120-144 h was linear at log10-log10 scale and strongest (in terms of coefficient of determination) at 96-120 h compared with other times after start of treatment. At 96-120 h after start of treatment median (range) AUC₂₄:EC₅₀ was 22 (11-316), T_EC50 37% (10-100%), C_max:EC₅₀ 1.9 (1.2-44.1), C_min:EC₅₀ 0.2 (0.04-1.3), coefficients of determination (p-value of linear regression coefficient) with inhibition of CRP synthesis at 96-120 h 0.55 (0.002), 0.73 (<0.001), 0.23 (0.09), 0.55 (0.002), respectively. According to regression tree T_EC50 >32.3% was associated with smaller inhibition of CRP synthesis at 96-120 h compared with T_EC50 <32.3% (ratio of CRP concentration within 96-120 h to 0-24 h after start of treatment 0.22 vs 0.92).

Conclusions. Use of PKPD indices based on CRP dynamics early in the treatment, particularly T_EC50, can predict MER treatment response (CRP decline) in neonates with late-onset sepsis or pneumonia. Such indices could guide AB treatment through individualized dosing based on routinely collected clinical data. This approach may have potential to overcome the lack of pathogen MIC, but warrants further larger and prospective studies.

References:
[1] V. Ramos-Martin, M. N. Neely, P. McGowan, S. Siner, K. Padmore, M. Peak, M. W. Beresford, M. A. Turner, S. Paulus & W. W. Hope (2016) Population pharmacokinetics and pharmacodynamics of teicoplanin in neonates: making better use of C-reactive protein to deliver individualized therapy. J Antimicrob Chemother, 71, 3168-3178.
[2] R. Wilson, A. Farkas, T. M. Rawson, J. Roberts, M. Gilchrist, W. Hope & A. H. Holmes (2019) O0825: A prospective study investigating the prediction of beta-lactam pharmacodynamics using AUC:EC50. The 29th ECCMID (Amsterdam, Netherlands, 13-16 April 2019)
[3] Padari, H., T. Metsvaht, L. T. Kõrgvee, E. Germovsek, M. L. Ilmoja, K. Kipper, K. Herodes, J. F. Standing, K. Oselin & I. Lutsar (2012) Short versus long infusion of meropenem in very-low-birth-weight neonates. Antimicrob Agents Chemother, 56, 4760-4. 

Reference: PAGE 29 (2021) Abstr 9602 [www.page-meeting.org/?abstract=9602]

Poster: Drug/Disease Modelling - Infection