Use of Oral Tetracyclines in the Treatment of Adult Patients with Community-Acquired Bacterial Pneumonia: A Literature Review on the Often-Overlooked Antibiotic Class
Abstract
:1. Introduction
2. Methods
3. Mechanisms of Action and Resistance
4. In Vitro Activity
5. S. pneumoniae
6. Haemophilus spp., M. catarrhalis, and Atypical Pathogens
7. Pharmacokinetics
8. PK/PD Infection Model Studies
9. Clinical Studies
10. Safety
11. Discussion
Author Contributions
Funding
Conflicts of Interest
References
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Pathogen | Tetracycline MIC50/MIC90/%NS | Doxycycline MIC50/MIC90/%NS | Minocycline MIC50/MIC90/%NS | Omadacycline MIC50/MIC90/%NS | Reference (Geographic Location, Years Obtained) |
---|---|---|---|---|---|
S.pneumoniae | 0.5/≥32/15.6% (n = 1817) | Doern 2005 (US; 2002–2003) [10] | |||
≤4/>8/14.2% (n = 2110) | Pottumarthy 2005 (North America; 2002–2003) [11] | ||||
-/>8/14.4% (n = 9296) | Sahm 2008 (USA; 2001–2005) [12] | ||||
-/-/17% (n = 75) | Desai 2010 (US; 1994–2004) [35] | ||||
≤4/>8/19.5% (n = 246) | Hoban 2003 (US and Canada; 2000) [36] | ||||
0.25/≥8/14.6–15.9% (n = 39,495) | Jenkins 2008 (USA; 2000–2004) [37] | ||||
-/16/14.9% (n = 1300) | Melo Cristino 2013 (Portugal; 2003–2004) [38] | ||||
0.5/>4/30.2% (n = 1736) | Sader 2018 (Europe, Asia, Latin America; 2015–2017) [39] | ||||
0.5/>8/26.7% (n = 2313) | 0.25/8/26.8% (n = 2313) | Jones 2013 (North America, Europe, Latin America, Asia-Pacific; 2010) [34] | |||
2/>8/23.8% (n = 1443) | 0.5/>4/23.1% (n = 1443) | Jones 2004 (USA; 1999–2002) [40] | |||
16/32/- (n = 41) | 2/4/- (n = 41) | 2/8/- (n = 41) | ≤0.06/0.125/- (n = 41) | Macone 2014 (USA) [41] | |
0.5/>8/23.1% (n = 1179) | 0.25/8/23.6% (n = 1179) | 0.06/0.06/- | Pfaller 2018 (USA and Europe; 2014) [42] | ||
-/-/41% (n = 29) | Lederman 2003 (USA; 2001–2002) [43] | ||||
0.06/0.12/1.1% (n = 3153) | Pfaller 2020 (USA and Europe; 2016–2018) [13] | ||||
0.06/0.12/0.3% (n = 1314) | Pfaller 2018 (USA and Europe; 2016) [42] | ||||
0.06/0.12/1.4% (n = 968) | Huband 2019 (USA and Europe; 2017) [44] | ||||
0.06/0.06/1.8% (n = 6253) | Pfaller 2017 (North America, Europe, Asia-Pacific, Latin America; 2010–2011) [45] | ||||
Penicillin-resistant S.pneumoniae | -/-/44.3% (n = 348) | Pottumarthy 2005 (North America; 2002–2003) [11] | |||
>4/>4/95.2% (n = 455) | Sader 2018 (Europe, Asia, Latin America; 2015–2017) [39] | ||||
-/-/43–60% (n = 15) | Lederman 2003 (USA; 2001–2002) [43] | ||||
2/>8/60.8% (n = 240) | 4/>4/–60.4% (n = 240) | Jones 2004 (US; 1999–2002) [40] | |||
>8/>8/63.8% (n = 260) | 4/8/64.2% (n = 260) | 0.06/0.12/- (n = 260) | Pfaller 2017 (USA and Europe; 2014) [45] | ||
0.06/0.12/9.1% (n = 366) ^^ | Pfaller 2020 (USA and Europe; 2016–2018) [13] | ||||
0.06/0.12/0% (n = 152) + | Pfaller 2018 (USA and Europe; 2016) [42] | ||||
0.06/0.12/1.8% (n = 112) * | Huband 2019 (USA and Europe; 2017) [44] | ||||
0.06/0.12/2.9% (n = 1466) | Pfaller 2017 (North America, Europe, Asia-Pacific, Latin America; 2010–2011) [45] | ||||
H.influenzae | ≤4/≤4/0% (n = 199) | Doern 2005 (USA; years 2002–2003) [10] | |||
-/-/1.4% (n = 829) | Melo Cristino 2013 (Portugal; 2003–2004) [38] | ||||
0.5/1/1.4% (n = 1172) | Sader 2018 (Europe, Asia, Latin America; 2015–2017) [39] | ||||
2/32/- (n = 53) | 0.5/4/- (n = 53) | 1/2/- (n = 53) | Macone 2014 (USA) [41] | ||
0.5/1/0.4% (n = 1886) ^ | Pfaller 2020 (USA and Europe; 2016–2018) [13] | ||||
0.5/1/0.2% (n = 556) ** | Huband 2019 (USA and Europe; 2017) [44] | ||||
1/1/0.7% (n = 3383) ^ | Pfaller 2017 (North America, Europe, Asia-Pacific, Latin America; 2010–2011) [45] | ||||
H. parainfluenzae | 0.5/0.5/4.3% (n = 23) | Sader 2018 (Europe, Asia, Latin America; 2015–2017) [39] | |||
1/2/7.0% (n = 71) ^ | Pfaller 2020 (USA and Europe; 2016–2018) [13] | ||||
1/-/16.7% (n = 6) | Huband 2019 (USA and Europe; 2017) [44] | ||||
M. catarrhalis | -/-/1.0% (n = 303) | Melo Cristino 2013 (Portugal; 2003–2004) [38] | |||
0.25/0.5/0.7% (n = 613) | Sader 2018 (Europe, Asia, Latin America; 2015–2017) [39] | ||||
0.12/0.25/- (n = 984) | Pfaller 2020 (USA and Europe; 2016–2018) [13] | ||||
0.25/0/25/- (n = 408) | Pfaller 2018 (USA and Europe; 2016) [42] | ||||
≤0.12/0.25/- (n = 313) | Huband 2019 (USA and Europe; 2017) [44] | ||||
0.12/0.25/- (n = 1226) | Pfaller 2017 (North America, Europe, Asia-Pacific, Latin America; 2010–2011) [45] | ||||
Other Moraxella species | 0.5/1/- (n = 9) | Pfaller 2020 (USA and Europe; 2016–2018) [13] | |||
0.25/-/- (n = 3) | Huband 2019 (USA and Europe; 2017) [44] | ||||
C. pneumoniae | 0.125/0.125/- (n = 15) | 0.06/0.25/- (n = 15) | Karlowsky 2019 [46] | ||
M. pneumoniae | 0.5/0.5/- (n = 20) | 0.25/0.5/- (n = 20) | 0.125/0.25/- (n = 20) | Waites 2016 (USA and China) [47] | |
0.5/1/- (n = 50) ++ | 0.12/0.25/- (n = 10) ++ | Waites 2017 (USA, Europe and China) [48] | |||
L. pneumophila | 1/1/- (n = 100) | 0.25/0.25/- (n = 100) | Dubois 2020 (Canada; years 1995–2004) [49] |
Antibiotic | Administration Route Loading Dose | Administration Route: Maintenance Dose | Special Consideration |
---|---|---|---|
Doxycycline [53] | 200 mg PO on day 1 | 100 mg PO every 12 h [7] | Absorption is impaired by antacids containing aluminum, calcium, or magnesium, bismuth subsalicylate, zinc, and iron-containing preparations Patients who are on anticoagulant therapy may require downward adjustment of their anticoagulant dosage May render oral contraceptives less effective Barbiturates, carbamazepine and phenytoin decrease the half-life of doxycycline |
Minocycline [54] | 200 mg PO on day 1 | 100 mg PO every 12 h or 50 mg PO 4 times a day | Absorption is impaired by antacids containing aluminum, calcium, or magnesium, bismuth subsalicylate, zinc, and iron-containing preparations Patients who are on anticoagulant therapy may require downward adjustment of their anticoagulant dosage May render oral contraceptives less effective Current data are insufficient to determine if a dosage adjustment is warranted in patients with renal impairment (creatinine clearance < 80 mL/min) |
Omadacycline [8] | Day 1: 200 mg by intravenous infusion over 60 min OR 100 mg by intravenous infusion over 30 min twice | 100 mg by intravenous infusion over 30 min once daily OR 300 mg PO once daily | Patients are required to fast for at least 4 h and then take omadacycline tablets with water. After oral dosing, no food or drink (except water) is to be consumed for 2 h and no dairy products, antacids, or multivitamins for 4 h Patients who are on anticoagulant therapy may require downward adjustment of their anticoagulant dosage |
Drug | Dose & Route of Administration | Cmax (mg/L) | tmaxa (h) | AUC∝ (mg∙h/L) | CL or CL/F (L/h) | CLR (L/h) | V or V/F (L) | t½ (h) | Protein Binding (%) |
---|---|---|---|---|---|---|---|---|---|
Doxycycline | 100 mg IV | 2.80 | 1 | NR | NR | NR | NR | NR | NR |
200 mg IV | 4.30–9.30 | 1 | 89.8–206 b | 2.24–2.32 | 0.85–0.98 | 50.5–52.6 | 13.8–16.2 | NR | |
100 mg oral | 1.70–5.10 | 1–4 | 37.4–75.7 | 2.92–3.16 | 1.86–2.1 | 64.8–92.0 | 13.6–15.4 | NR | |
200 mg oral | 2.61–5.92 | 2.6–4.3 | 85.0–108 | 1.74–2.90 | 1.1–3.6 | 52.6–124 | 8.8–26.2 | 82–93 | |
Minocycline | 200 mg IV | 1.89 | NR | 25.9 | 8.21 | NR | 148 | 13.7 | NR |
150 mg oral | 2.10–2.19 | 2–4 | NR | NR | NR | NR | 16 | 76 | |
200 mg oral | 3.10–3.60 | 2–4 | 68.6–71.3 | 4.40 | 0.5 | 84 | 12.9–17.0 | NR | |
Omadacycline | 100 mg IV | 1.51 | 0.55 | 9.36 b | 11.2 | 2.4–3.3 | 256 | 16.2 | 21 |
300 mg oral | 0.55 | 2.5 | 9.40 b | 34.6 | NR | 794 | 15.0 | NR | |
450 mg oral | 0.87 | 2.5 | 8.98 b | NR | NR | NR | 13.5 | NR |
Reference | Study Design and Population | Key Baseline Characteristics | Comparators | Key Primary Clinical Outcomes | Major Findings | Other Findings and Comments |
---|---|---|---|---|---|---|
Harazim, 1987 [92] | Double-blind, randomized trial of adult patients with lower respiratory tract infections (n = 230) | Of the 230 patients, 219 were assessed for effectiveness: 131 had CAP and 88 had exacerbations of chronic obstructive pulmonary disease (COPD) | Doxycycline 100 mg PO twice daily for 10 days vs. ofloxacin 200 mg or 400 mg PO twice daily for 10 days | Clinical response (cure or improvement) in CAP, defined as disappearance of cough and sputum production | Satisfactory response in CAP patients was 90.0% in the doxycycline group vs. 96.8% in the ofloxacin group 7 patients with CAP in the doxycycline group failed to respond vs. 2 patients with CAP in the ofloxacin group | Overall, 7 patients in the doxycycline group withdrew due to adverse events (gastrointestinal side effects and allergy) vs. 1 patient in the ofloxacin group No p values provided |
Biermann, 1988 [93] | Double-blind, randomized trial of adult patients with CAP and acute exacerbations of chronic bronchitis (n = 221) | Of the 221 enrolled patients, 191 were evaluated (104 with CAP and 87 with exacerbations of COPD) | Doxycycline 200 mg PO daily for 1 day, then 100 mg PO daily for 8 days vs. spiramycin 1000 mg PO three times daily for 1 day, then 1000 mg tablets PO twice daily for 4.5 days | Clinical cure 10–14 days after the start of treatment | In the CAP group, the clinical cure rate was 84.0% with 20% side effects; there was no difference between treatment groups Clinical cure rates for each treatment group with CAP were not specified | Side effects occurred in 21.4% of patients in the doxycycline group vs. 22.5% of patients in the spiramycin group. Most side effects in each group were gastrointestinal 1 patient in the doxycycline group withdrew because of side effects (feeling unwell and blurred vision). 1 CAP patient in the spiramycin group withdrew due to lack of efficacy |
Wiesner, 1993 [94] | Double-blind trial of patients with ambulatory respiratory tract infections (n = 297) | Bronchitis (n = 243), CAP (n = 25) and other (n = 29)) | Doxycycline 100 mg PO once daily vs. erythromycin acistrate 400 mg PO twice daily. The duration of treatment varied from 7 to 14 days depending on severity of infection | Clinical response | Overall, 97.2% of the doxycycline-treated patients improved vs. 96.6% of the erythromycin-treated patients Of the 13 doxycycline-treated patients with CAP, 12 were deemed cured. Of the 11 erythromycin-treated patients with CAP, 9 were deemed cures (p values not provided) | Side effects were reported in 16 doxycycline vs. 20 erythromycin patients that were predominantly gastrointestinal in nature Drug discontinuation occurred in 5 doxycycline patients and 3 erythromycin patients |
Norrby, 1997 [95] | Double-blind trial of adult inpatients and outpatients with CAP (n = 411) | An etiology was confirmed in 270 (66%) cases: 93 had mixed etiology, 133 had by Mycoplasma spp., Chlamydia spp. or Legionella spp., 35 had S. pneumoniae, and 30 had a viral infection | Doxycycline 100 mg PO twice daily for 10 days vs. fleroxacin 400 mg PO once daily for 10 days | Clinical response at 2–8 days after end of treatment (first follow up visit) and 3–5 weeks after end of treatment (second follow up visit) in intention-to treat population Clinical response at second follow up visit in per-protocol population | In intention-to treat analyses, clinical response rates in doxycycline- vs. fleroxacin-treated patients were 93% (177/191) vs. 86% (157/182) at first follow up visit and 85% (162/190) vs. 75% (137/182; difference 10%, lower bound for one-sided 95% confidence interval-17.3%) at second follow up visit In the per-protocol analysis, clinical response rates in doxycycline- vs. fleroxacin-treated patients were 92% (162/190 vs. 84% (137/182; difference 7.6%, lower bound for one-sided 95% confidence interval −17.8%) at second follow up visit Null hypothesis that fleroxacin at worst was 15% inferior to doxycycline was rejected for the second follow up visit | Among all pathogens with S. pneumoniae, 88% (15/17) of doxycycline-treated patients and 61% (11/18) of fleroxacin-treated patients had clinical success at second follow up visit 12/56 (21%) patients in with Mycoplasma etiology in the fleroxacin group vs. 3/42 (7%) in the doxycycline group were failures at second follow up visit Drug-related adverse events were reported in 39% of 204 fleroxacin patients and in 34% of 207 doxycycline patients (p > 0.05) Photosensitivity was the most frequently reported side effect in the doxycycline arm, but no cases resulted in discontinuation of therapy p values not provided |
Ailani, 1999 [96] | Unblinded, randomized trial of adult hospitalized patients with mild to moderately severe CAP (n = 87) | S. pneumoniae was the most frequently isolated (8 in doxycycline group vs. 9 in the control group) 3 doxycycline patients and 3 in control group had S. pneumoniae bloodstream infection | Doxycycline IV twice daily vs. other undefined antibiotics chosen at the discretion of the admitting physician (control group) | Time to clinical response and hospital length of stay | Median time to clinical response in doxycycline group vs. the control group was 2 days vs. 4 days; p = 0.001 Median hospital length of stay in doxycycline group vs. the control group was 4 days vs. 6 days; p = 0.04 | Three patients in the doxycycline group required a change in treatment because of lack of response vs. 5 patients in control group All patients with pneumococcal bacteremia recovered 6 doxycycline patients vs. 11 patients in control group had adverse events |
Mokabberi, 2010 [97] | Randomized, double-blind trial of adults hospitalized patients with CAP (n = 66) | Baseline pathogen etiology not reported | Doxycycline 100 mg IV/PO twice daily vs. levofloxacin 500 mg IV/PO once daily; first dose was IV | Hospital length of stay Time to change from IV to PO | The mean hospital length of stay was 4 days for doxycycline and 6 days for levofloxacin (p < 0.0012) The mean time to change from IV to PO was 2.88 days for doxycycline and 2.73 for levofloxacin | Treatment efficacy not significantly different (p = 0.844) 1 failure resulting in antibiotic change in doxycycline group vs. 2 failures in levofloxacin group No side effects were observed in doxycycline group vs. 2 in levofloxacin group |
Stets, 2019 [98] | Phase 3 multinational, double-blind, double-dummy non-inferiority trial of adult patients with CABP (n = 774) | Adults with CABP and Pneumonia Severity Index risk classes II-–IV CAP pathogens were identified in 49.9% of patients in the intention-to-treat population; M. pneumoniae (33%), S. pneumoniae (20%), L. pneumophila (19%), C. pneumoniae (15%), and H. influenzae (12%) | Omadacycline 100 mg IV every 12 h for two doses, then 100 mg IV every 24 h vs. moxifloxacin 400 mg IV every 24 h A transition to oral omadacycline 300 PO mg every 24 h or moxifloxacin 400 PO mg every 24 h was allowed after 3 days Total treatment duration was 7 to 14 days | Early clinical response, defined as survival with improvement in two of the four primary pneumonia symptoms (cough, sputum production, pleuritic chest pain, and dyspnea) with no worsening in symptoms at 72–120 h after initial dose Investigator-assessed clinical response at the post-treatment evaluation (5 to 10 days after the last dose), defined as survival with resolution or improvement in signs and symptoms of infection to the extent that further antibacterial therapy was unnecessary | In the intention-to-treat population, omadacycline was noninferior to moxifloxacin with regard to early clinical response (81.1% and 82.7%, respectively; difference, −1.6 percentage points, 95% confidence interval −7.1 to 3.8) Investigator-assessed clinical response rates at the post-treatment evaluation were 87.6% for omadacycline and 85.1% for moxifloxacin (87.6% and 85.1%, respectively; difference, 2.5 percentage points; 95% confidence interval −2.4 to 7.4) | Adverse events occurred in 41.1% of omadacycline-treated patients vs. 48.5% of moxifloxacin-treated patients The most frequent events were gastrointestinal (10.2% and 18.0%, respectively) Clostridioides difficile infections occurred in no patients who received omadacycline versus 8 patients (2%) who received moxifloxacin 8 deaths (2%) occurred in the omadacycline group vs. 4 (1%) in the moxifloxacin group |
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Bidell, M.R.; Pai, M.P.; Lodise, T.P. Use of Oral Tetracyclines in the Treatment of Adult Patients with Community-Acquired Bacterial Pneumonia: A Literature Review on the Often-Overlooked Antibiotic Class. Antibiotics 2020, 9, 905. https://doi.org/10.3390/antibiotics9120905
Bidell MR, Pai MP, Lodise TP. Use of Oral Tetracyclines in the Treatment of Adult Patients with Community-Acquired Bacterial Pneumonia: A Literature Review on the Often-Overlooked Antibiotic Class. Antibiotics. 2020; 9(12):905. https://doi.org/10.3390/antibiotics9120905
Chicago/Turabian StyleBidell, Monique R., Manjunath (Amit) P. Pai, and Thomas P. Lodise. 2020. "Use of Oral Tetracyclines in the Treatment of Adult Patients with Community-Acquired Bacterial Pneumonia: A Literature Review on the Often-Overlooked Antibiotic Class" Antibiotics 9, no. 12: 905. https://doi.org/10.3390/antibiotics9120905
APA StyleBidell, M. R., Pai, M. P., & Lodise, T. P. (2020). Use of Oral Tetracyclines in the Treatment of Adult Patients with Community-Acquired Bacterial Pneumonia: A Literature Review on the Often-Overlooked Antibiotic Class. Antibiotics, 9(12), 905. https://doi.org/10.3390/antibiotics9120905