Inclusion of Safety-Related Issues in Economic Evaluations for Seasonal Influenza Vaccines: A Systematic Review
Abstract
:1. Introduction
2. Materials and Methods
2.1. Eligibility Criteria
2.2. Information Sources and Search Strategy
2.3. Study Selection and Data Collection Process
2.3.1. Study Selection
2.3.2. Data Extraction and Data Items
2.3.3. Outcomes
2.4. Risk of Bias/Quality Assessment
3. Results
3.1. Study Selection
3.2. Study Characteristics
3.2.1. Type of Economic Evaluation and Study Perspective
3.2.2. Compared Vaccine Alternatives and Vaccinated Population
3.2.3. Study Location and Settings
3.2.4. Data Sources and Funding
3.3. AEFI-Related Outcomes
3.3.1. AEFI-Related Costs
- direct AEFI-related unit cost = [(number of health care provider visits for AEFI) × cost of healthcare provider visit) + (number of cases of vaccination-associated GBS)] × cost per case of GBS;
- indirect AEFI-related unit cost = number of work absenteeism days due to AEFI × 8 h/d × hourly wage.
- direct AEFI-related unit cost = payment for one outpatient treatment × rate of AEFI due to vaccination × half of these need outpatient treatment;
- indirect AEFI-related unit cost = rate of AEFI × 1/2 accompanying person × payment for 1/2 outpatient treatment × time lost × productivity loss (cost per hour);
3.3.2. Other AEFI-Related Issues
3.3.3. AEFIs’ Share of the Total Costs Discussed in the Economic Evaluation
3.4. Quality Assessment Using CHEC Extended List
4. Discussion
4.1. Main Findings
4.2. Interpretation
4.3. Strengths and Limitations
4.4. Research Implications
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Appendix A
Study Selection Form | ||||
---|---|---|---|---|
Reviewer: Date: Author: Title: Year: Record Number: | ||||
Yes | No | Unclear | Not Applicable | |
1. Is the article a full economic evaluation study (designs to be considered: CMA, CEA, CBA, or CUA)? | □ | □ | □ | □ |
2. Is the intervention a vaccination? | □ | □ | □ | □ |
3. Is the vaccine used for seasonal influenza? | □ | □ | □ | □ |
4. Are the outcome measures economic parameters? | □ | □ | □ | □ |
5. Does this EE discuses AEFI? * | ||||
* This parameter will be considered only in full text selection/eligibility. If yes or unclear, final eligibility will be performed on the basis of full-text. CEA = cost effectiveness analyses; CBA = cost–benefit analysis; CUA = cost–utility analysis; EE = economic evaluation; AEFI = adverse events following influenza |
Reviewer 1 | Reviewer 2 | ||
---|---|---|---|
Yes | No | Yes | No |
30 | 167 | 27 | 170 |
a | b | c | d |
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PubMed | Embase | Cochane Library | |||||||
Search Line | MeSH Terms | Title/Abstract | Emtree Terms | Title/Abstract | MeSH Terms | Title/Astract/Key words | |||
Influenza | influenza, human | OR | influenza OR flu | influenza, human | OR | influenza OR flu | influenza, human | OR | influenza OR flu |
AND | |||||||||
Vaccine | vaccines OR vaccination | OR | vaccine OR vaccines OR vaccination OR flu shot | vaccines OR vaccination | OR | vaccine OR vaccines OR vaccination OR flu shot | influenza vaccines OR vaccines OR vaccination | OR | vaccine OR vaccines OR vaccination OR flu shot |
AND | |||||||||
Seasonal | seasonal OR epidemic OR annual OR universal | seasonal OR epidemic OR annual OR universal | seasonal OR epidemic OR annual OR universal | ||||||
AND | |||||||||
Economics | “costs and cost analysis” OR “quality-adjusted life years” OR “economics” [subheading] | OR | cost OR costs OR economic evaluation OR economic analysis OR qaly OR qalys ORquality-adjusted-life-year OR quality-adjusted-life-years OR hye OR healthy years equivalent OR daly OR disability-adjusted life years OR icer OR icur OR work productivity OR absenteeism | “cost”/exp OR “quality adjusted life year”/exp | OR | cost OR costs OR “economic evaluation” OR “economic analysis” OR qaly OR qalys OR “quality-adjusted-life-year” OR “quality-adjusted-life-years” OR hye OR “healthy years equivalent” OR daly OR “disability adjusted life years” OR icer OR icur OR “work productivity” OR absenteeism | [cost and cost analysis] OR [quality-adjusted life years] OR any MeSH descriptor with qualifier(s): [economics-EC] | OR | cost OR costs OR economic evaluation OR economic analysis OR qaly OR qalys OR quality-adjusted life year OR quality-adjusted life years OR hye OR healthy years equivalent OR daly OR disability-adjusted life years OR icer OR icur OR work productivity OR absenteeism |
Study Characteristic | Study Characteristic in the Reviewed Article | Percentage of Studies |
---|---|---|
Type of EE | CBA | 21% |
CEA | 21% | |
CUA | 38% | |
CMA | 0 | |
combining more than one type | 19% | |
Study perspective | societal | 35% |
combining more than one perspective | 29% | |
healthcare provider | 12% | |
employer | 4% | |
family | 2% | |
medical insurance | 2% | |
school | 2% | |
patient | 2% | |
net monetary benefit | 2% | |
not specified | 12% | |
Vaccine type | LAIV vs. no vaccination or alternative vaccine | 15% |
IIV vs. no vaccination or alternative vaccine | 85% | |
Population characteristics | general population | 4% |
HIV population | 2% | |
haemophilysis population—adults | 2% | |
pregnant/pospartum woman and infant | 13% | |
children | 35% | |
adults 18–49 y standard risk | 2% | |
adults 50 y | 2% | |
adults healthy 50–64 y | 2% | |
adults 18–65+ y | 2% | |
working adults age/employees elderly 65+ y | 13% 23% | |
Location | USA | 56% |
China | 6% | |
Thailand | 2% | |
Taiwan | 4% | |
Gemany | 2% | |
Argentina | 4% | |
Canada | 8% | |
UK | 4% | |
Netherlands | 4% | |
Spain | 4% | |
Italy | 8% | |
Settings | model-based | 62% |
study-based (trial/observational/survey) | 38% | |
Funding | no information regarding funding | 31% |
not funded funded not specified | 6% 63% 4% | |
research/training fund or grant | 6% | |
National Institute/fund/Ministry | 27% | |
CDC | 9% | |
WHO pharmaceutical company/vaccine manufacturer | 2% 15% | |
Type of AEFI | severe AEFI (GBS, anaphylaxis, and MSW) | 33% |
minor/mild AEFI (local and systemic) | 46% | |
AEFI not specified | 40% | |
AEFI inclusion | direct costs of AEFIs | 90% |
indirect costs of AEFIs | 27% | |
disutility/QALY-loss due to AEFIs | 37% | |
duration of AEFIs | 21% | |
probability/frequency of occurrence of the AEFIs | 54% |
Vaccine Type | Studio Vaccine | Comparator | AEFI-Related Costs | Other Forms of AEFI Inclusion in the EE | Study Identifica-tion |
---|---|---|---|---|---|
inactivated influenza vaccines | QIV | TIV |
|
| Brogan et al., 2017 [73] |
seasonal vaccination | no vaccination |
|
| Xu et al., 2016 [74] | |
IIV administrated intradermally | IIV administrated intramuscularly |
|
| Leung et al., 2016 [75] | |
TIV | trivalent LAIV |
|
| Meeyai et al., 2015 [47] | |
TIV injectable | LAIVnasal spray |
|
| Damm et al., 2015 [27] | |
seasonal vaccine | no vaccination |
|
| Giglio et al., 2012 [28] | |
TIV injectable | no vaccination |
|
| Ding et al., 2012 [59] | |
universal vaccine | no vaccination |
|
| Skedgel et al., 2011 [29] | |
universalvaccine | standard annualvaccine |
|
| Lee et al., 2012 [30] | |
TIV | LAIV |
|
| Lee et al., 2011, Vaccine, [51] | |
seasonal vaccine | no vaccination |
|
| Jit et al., 2011 [31] | |
seasonal vaccine | no vaccination |
|
| Beigi et al., 2009 [32] | |
subunit vaccine | no vaccination |
| NA | Salleras et al., 2009 [69] | |
seasonal vaccine | no vaccination |
|
| Gao et al., 2008 [61] | |
virosomal subunit vaccine | no vaccination |
|
| Navas et al., 2007 [56] | |
virosomal adjuvanted vaccine | current immunization (TIV and LAIV) |
|
| Marchetti et al., 2007 [33] | |
TIV | no vaccination |
|
| Roberts et al., 2006 [34] | |
TIV (2 doses), virosome-formulated subunit vaccine | no vaccination |
|
| Esposito et al., 2006 [52] | |
universal vaccine | no vaccination |
| NA | Wang et al., 2005 [53] | |
annual vaccine | no vaccination |
| NA | Meltzer et al., 2005 [67] | |
influenza vaccine | no vaccination |
|
| Gasparini et al., 2002, [62] | |
influenza vaccine | no vaccination |
|
| Nichol, K.L., 2001 [63] | |
influenza vaccine | no vaccination (placebo vaccination) |
|
| Nichol et al., 1995 [64] | |
annual influenza vaccine | no vaccination |
|
| Riddiough et al., 1983 [54] | |
annual vaccine | no vaccination |
| NA | Helliwell et al., 1988 [58] | |
influenza vaccine | no vaccination |
|
| Weaver et al., 2001 [35] | |
adjuvanted vaccine | non adjuvanted vaccine |
|
| Lee et al., 2011, Am J Kidney Dis. [36] | |
influenza vaccine | adjuvated influenza vaccine |
|
| Lee et al., 2009, Vaccine (adjuvated) [39] | |
influenza vaccine | no vaccination |
|
| Michaelidis et al., 2011 [40] | |
TIV | no vaccination |
|
| Myers et al., 2011 [41] | |
(1) traditional physician office (2) mass vaccination (3) pharmacy setting | no vaccination |
|
| Prosser et al., 2008 [43] | |
influenza vaccine | no vaccination |
| NA | Teufel et al., 2008 [48] | |
TIV non-adjuvated seasonal influenza vaccine | the vaccine is compared in different periods |
| NA | Werker et al., 2014 [71] | |
(1) IV (annually) + PCV (on 5 y)(2) IV annually (3) no vaccination | comparing the outcomes of the three strategies |
|
| You et al., 2009 [72] | |
seasonal vaccine | no vaccination |
| NA | Colombo et al., 2006 [65] | |
influenza vaccination | no vaccination (placebo) |
|
| Turner et al., 2006 [44] | |
influenza vaccine | no vaccination |
|
| Dayan et al., 2001 [49] | |
influenza vaccine | no vaccination |
| NA | Postma et al., 1999 [50] | |
pneumococcal polysaccharide vaccine and influenza vaccination strategies | current CDC recommendations (influenza vaccination for all, PPV when comorbid conditions are present) | NA |
| Smith et al., 2010 [45] | |
influenza vaccine | no vaccination |
|
| France et al., 2018 [46] | |
influenza vaccine | no vaccination |
|
| Yang et al., 2018 [57] | |
influenza vaccine | no vaccination |
|
| Meijboom et al., 2018 [68] | |
influenza vaccine | (1) vaccination timing model- intake of vaccine at different months for estimating the timing (2) comparing monthly vaccination with no vaccination of 65+ population |
|
| Lee et al., 2009, Vaccine [38] | |
TIV LAIV | (1) children’s vaccination timing model and (2) children’s monthly influenza vaccination decision model |
|
| Lee et al., 2010, Am J Manag Care. [37] | |
live attenuated influenza vaccine | LAIV | TIV |
|
| Lee et al., 2010, Vaccine [60] |
LAIV intranasal | no vaccination |
| NA | Schmier et al., 2008 [70] | |
LAIV | IIV |
|
| Prosser et al., 2006 [76] | |
LAIV | TIV |
|
| Luce et al., 2008 [55] | |
LAIV | TIV and no vaccination |
|
| Prosser et al., 2011 [42] | |
LAIV | TIV |
|
| Tarride et al., 2012 [77] | |
trivalent, intranasal, (LAIV) | no vaccination (placebo) |
|
| Nichol et al., 2003 [66] | |
LAIV trivalent (nasal spray) | no vaccination (placebo) |
|
| Hibbert et al., 2007 [78] |
Study Identification | Location | The Way GBS Cost Was Included | Costs |
---|---|---|---|
Brogan et al., 2017 [73] | USA | unit cost per vaccine | 69,222 |
Xu et al., 2016 [74] | USA | unit cost per event | 51,814 |
Ding et al., 2012 [59] | USA | unit cost | 93,747 |
Lee et al., 2011, Vaccine [51] | USA | unit cost—hospitalization (insured) | 1866 |
Lee et al., 2011, Vaccine [51] | USA | unit cost—hospitalization (non-insured) | 6298 |
Lee et al., 2011, Vaccine [51] | USA | unit cost—ICU (insured) | 3086 |
Lee et al., 2011, Vaccine [51] | USA | unit cost—ICU (non-insured) | 12,695 |
Prosser et al., 2006 [76] | USA | unit cost | 32,322 |
Roberts et al., 2006 [34] | USA | unit cost for each treatment—probability weighted average | 135,743 |
Meltzer et al., 2005 [67] | USA | unit cost per vaccine | 0.352 |
Nichol, K.L., 2001 [63] | USA | cost per episode per vaccine | 17,767 |
Riddiough et al., 1983 [54] | USA | net cost for medcare program | 0.027 |
Myers et al., 2011 [41] | USA | unit cost | 48,999 |
Prosser et al., 2008 [43] | USA | unit cost | 84,709 |
Hibbert et al., 2007 [78] | USA | unit cost | 33,033 |
Skedgel et al., 2011 [29] | Canada | annual cost | 130,798 |
AEFI | GBS | Anaphylaxis | MSW | Other | |
---|---|---|---|---|---|
Study Identification | Brogan et al., 2017 [73] | QALYs loss per AE = 0.141 | QALYs lossper AE = 0.020 | / | / |
Xu et al., 2016 [74] | health utility index = 0.5 | / | / | health utility index for minor AEFI = 0.99 | |
Leung et al., 2016 [75] | / | / | / | utility loss = 0.05 | |
Meeyai et al., 2015 [47] | DALYs loss per vaccine dose = 3 × 10−8 | / | / | / | |
Skedgel et al., 2011 [29] | relative utility weight = 0.25 | / | / | / | |
Lee et al., 2012 [30] | / | / | / | utilities (QALYs) = 0.95 | |
Beigi et al., 2009 [32] | / | / | / | utilities (QALYs) = 0.95 | |
Lee et al., 2011, Am J Kidney Dis. [36] | / | / | / | utilities (QALYs) = 0.95 | |
Lee et al., 2009, Vaccine (adjuvated) [39] | / | / | / | utilities (QALYs) = 0.80 for systematic AE utilities (QALYs) = 0.95 local vaccine AE | |
Michaelidis et al., 2011 [40] | / | / | / | utility per day (QALY) = 0.95 | |
Myers et al., 2011 [41] | utility = 0.5 | / | / | utility = 0.99 for minor AE | |
Turner et al., 2006 [44] | / | / | / | QALD loss = 0.55 | |
Smith et al., 2010 [45] | / | / | / | utility weights = 0.9 | |
France et al., 2018 [46] | / | / | / | QALY loss = 0.00274 | |
Lee et al., 2009, Vaccine [38] | / | / | / | utility (QALYs) = 0.95 | |
Lee et al., 2010, Am J Manag Care [37] | / | / | / | utility (QALYs) = 0.95 | |
Luce et al., 2008 [55] | / | / | health state utility = 0.085 | / | |
Prosser et al., 2011 [42] | quality adjustments (disutility associated with an event) = 0.141 | quality adjustments (disutility associated with an event) = 0.02 | quality adjustments (disutility associated with an event) = 0.0018 | / |
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Fens, T.; de Boer, P.T.; van Puijenbroek, E.P.; Postma, M.J. Inclusion of Safety-Related Issues in Economic Evaluations for Seasonal Influenza Vaccines: A Systematic Review. Vaccines 2021, 9, 111. https://doi.org/10.3390/vaccines9020111
Fens T, de Boer PT, van Puijenbroek EP, Postma MJ. Inclusion of Safety-Related Issues in Economic Evaluations for Seasonal Influenza Vaccines: A Systematic Review. Vaccines. 2021; 9(2):111. https://doi.org/10.3390/vaccines9020111
Chicago/Turabian StyleFens, Tanja, Pieter T. de Boer, Eugène P. van Puijenbroek, and Maarten J. Postma. 2021. "Inclusion of Safety-Related Issues in Economic Evaluations for Seasonal Influenza Vaccines: A Systematic Review" Vaccines 9, no. 2: 111. https://doi.org/10.3390/vaccines9020111
APA StyleFens, T., de Boer, P. T., van Puijenbroek, E. P., & Postma, M. J. (2021). Inclusion of Safety-Related Issues in Economic Evaluations for Seasonal Influenza Vaccines: A Systematic Review. Vaccines, 9(2), 111. https://doi.org/10.3390/vaccines9020111