Original Article

Analyzing the Carbon Footprint of an Intravitreal
Injection

Barry Power, MB, BCh, BAO, MRCOphth, MS; Robert Brady, MB, BCh, BAO, MRCOphth; Paul Connell, MB, BCh,
BAO, MD, HDIPHQM, FRCSI (Ophth), FRANZCO

Vitreoretinal Department, Mater Misericordiae University Hospital, Dublin, Ireland

ORCID:
Barry Power: http://orcid.org/0000-0002-7045-0264

Abstract
Purpose: To estimate the carbon footprint of a single intravitreal injection in a hospital-
based intravitreal service.
Methods: Greenhouse gas emissions attributable to the delivery of an intravitreal
injection were calculated using a hybrid lifecycle analysis technique. Data were collected
regarding procurement of materials, patient travel, and building energy use.
Results: Carbon emissions associated with a single intravitreal injection, excluding the
anti-VEGF agent, were 13.68 kg CO2eq. This equates to 82,100 kg CO2eq annually for our
service. Patient travel accounted for the majority of emissions at 77%, with procurement
accounting 19% for and building energy usage for 4% of total emissions. The omission of
items considered dispensable from injection packs would reduce carbon emissions by
an estimated 0.56 kg per injection – an annual saving of 3,360 kg CO2eq for our service.
Similar savings, if extrapolated to a country the size of the United Kingdom, could yield
annual carbon savings of 450,000 kg CO2eq. For context, a single one-way economy
transatlantic flight produces 480 kg CO2eq per person.
Conclusion: Wasteful practice in healthcare increases greenhouse gas production
and drives climate change. The healthcare sector should be a leader in sustainable
practice promotion and changes to high volume procedures have the largest impact
on emissions. Long-acting agents offer the greatest future potential for meaningful
reductions.

Keywords: Anti-VEGF; Climate Change; Medical Retina; Sustainability

J Ophthalmic Vis Res 2021; 16 (3): 367–376

INTRODUCTION

Climate change is a serious global threat and
the healthcare industry is a large net contributor.

Correspondence to:

Barry Power, MB, BCh, BAO, MS. Ophthalmology
Department, Mater Misericordiae University Hospital,
Eccles Street, Dublin 3, Ireland.
E-mail: barry.power.1@ucdconnect.ie
Received: 18-11-2020 Accepted: 03-02-2021

Access this article online

Website: https://knepublishing.com/index.php/JOVR

DOI: 10.18502/jovr.v16i3.9433

The climate of the earth has changed throughout
history but the changes over the last 50 years
are unprecedented for millennia. The National
Aeronautics and Space Administration (NASA)
states that this change is highly likely (>95%
probability) to be attributable to human activity and
this is supported by multiple studies with the wider

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How to cite this article: Power B, Brady R, Connell P. Analyzing the Carbon
Footprint of an Intravitreal Injection. J Ophthalmic Vis Res 2021;16:367–376.

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Carbon Footprint of Intravitreal Injections; Power et al

scientific community in agreement.[1–4] This change
is rapid with the current rate of warming 10 times
faster than similar historical periods.[5] Climate
change will disproportionately affect developing
countries.[6]

Greenhouse gases (GHGs) are those considered
to be causative of global warming and carbon
footprinting is the commonly accepted scientific
methodology for quantifying the volume of
GHGs a product or activity produces. Carbon
footprints typically break a process down
into components, which are felt to contribute
significantly to GHG production. The footprint
puts particular emphasis on the emissions that
are felt to drive climate change. Four gases
(carbon dioxide, methane, nitrous oxide, and
Sulphur hexafluoride) and two groups of gases
(hydrofluorocarbons and perfluorocarbons) are
described in the Kyoto protocol as contributing
to global warming. Carbon dioxide (CO2) is used
as the reference gas with the total emissions
expressed in units called carbon dioxide
equivalents (CO2eq).

[7]

In the United Kingdom (UK) and the United
States of America (USA), healthcare is responsible
for 4% and 10% annual emissions respectively.[8, 9]
Amongst the public sector in the UK, healthcare is
estimated to account for 25% of total emissions.[10]
Limited studies to date have described the carbon
footprint of various healthcare processes.[11–13] In
the ophthalmic literature, the carbon footprint
of the cataract surgery pathway in a unit
in the UK has been estimated to be 181 kg
CO2eq.

[14]

The UK National Health Service (NHS) aims to
be a leader among global healthcare providers in
facing up to its responsibilities concerning carbon
emissions. The NHS carbon reduction strategy sets
an ambition for the healthcare sector to drive the
change toward a low carbon society.[15] Taking
2007 levels as the baseline, the strategic goals are
a 34% reduction in carbon production by 2020 and
an 80% reduction by 2050.

Efforts to reduce healthcare-related carbon
emissions are most effective when focused
macroscopically on processes. High volume
procedures, such as intravitreal injections, offer
scope for meaningful net emission reductions with
procedural changes.

With an ageing population, the number of
intravitreal injections performed continues to grow

and an estimated 5.9 million intravitreal injections
were performed in the USA in 2016.[16] In the UK,
injection procedures increased by 215% between
January 2010 and May 2014.[17]

Our aims for this paper are to:

1. estimate the overall carbon emission per
injection;

2. understand where in the process the carbon
is emitted;

3. identified hotspots within this process can
then be targeted to achieve the most effective
reductions.

Our target audience is those working in
the healthcare sector including managers and
clinicians.

METHODS

There are two main methods of carbon footprinting
– lifecycle analysis (LCA) and input–output-based
analysis. A hybrid LCA utilizes both methods in
an attempt to address the inherent limitations
of the two systems. We discuss our rationale
for using this technique at the end of the
section. The study was performed in the Mater
Misericordiae University Hospital Dublin from June
to August in 2018. This study adhered to the
guidelines of the Declaration of Helsinki. All
methods of carbon emission estimation must
have a scope or boundary. For this study, we
calculated emissions from three main components
of the intravitreal injection process: (1) procurement
of the materials utilized; (2) patient travel to
and from the hospital; and (3) building energy
use.

Greenhouse gas (GHG) emissions were
converted to kilograms carbon dioxide equivalent
(kg CO2eq) which is the accepted common unit
for measuring GHG production. This measure is
the amount of carbon dioxide that would have
the same global warming potential as the GHGs
produced by the process measured.

Procurement

Procurement emissions are defined as the
emissions associated with all of the elements
of production, distribution, consumption, and
disposal of an item.

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Carbon Footprint of Intravitreal Injections; Power et al

Production, Distribution, and Consumption of
Materials

Carbon emissions associated with production,
distribution, and consumption were calculated
using an input–output model. The input–output
method is used when a lifecycle-based assessment
is impractical due to difficulty in assigning
boundaries to complex processes with many direct
and indirect components. This form of carbon
estimation uses the monetary cost of a product or
process to estimate carbon emissions. Different
conversion factors exist for different industries;
a conversion factor specific to the medical
industry was used for the injection pack and a
pharmaceutical conversion factor for comparison
of the different agents. These carbon emission
conversion factors were obtained from the 2011
UK Department of Environment and Rural Affairs
(DEFRA) emission modelling documents, using the
2018 price estimates.[19] The cost of the injection
pack utilized was €10 (£9.10). The local costs
of Bevacizumab, Ranibizumab, and Aflibercept
were €44, €820, and €1100, respectively – each
purchased in prefilled syringes. These syringes
are single dose units and come separately from
the injection packs.

Waste Disposal

The carbon emissions associated with waste
disposal were calculated using a lifecycle-
based analysis. This type of analysis collects
all of the materials utilized in a process and
estimates emissions attributable to each item. The
calculations were performed using the 2018 UK
government GHG conversion publication.[20] The
calculation is weight-based. Each separate product
used for delivering an intravitreal injection was
weighed and its composition classified according
to the document. Conversion factors were used to
convert this data into kg CO2eq. The conversion
factors consider the composition of the product
disposed of and the method of disposal (clinical
incineration or landfill). The conversion factor for
incineration of clinical/hazardous waste (which
is undertaken at higher heat and without energy
extraction) was taken to be 1,833 in accordance
with previous studies.[14] Each healthcare provider
performing injections in the service was surveyed
(n = 6) and asked to document which waste
disposal bin each item was placed in after use. The

method of disposal was taken to be the majority
result. The contents of the pack are summarized in
Table 3 in the Results section.

Travel

Emission production attributable to patient travel to
and from the hospital was calculated based on the
distance travelled (hospital to home address) and
the mode of transport. Patients were consented
for participation. Google maps distance was used
to calculate the distance travelled by the patient
(www.googlemaps.ie). One hundred sequential
patients were surveyed to document mode of travel
and journeys were taken to be round-trips. The
2018 UK government GHG conversion publication
was used to convert this data into kg CO2eq per km
travelled.[20]

Energy Usage

Data pertaining to energy usage in the study
hospital was not available so Moorfield’s Eye
Hospital was used as a representative substitute.
The building energy use was estimated in a similar
manner to previous studies.[14] Energy use per
m2 of floor space was estimated using the UK
2017 National Estates Return Information Collection
database.[21] This data was then converted to kg
CO2 eq per kW using the carbon conversion
factor. The 100m2 floor space utilized by the
intravitreal injection service was defined as the
check-in/waiting room and a two-bed laminar
airflow injection suite. Energy usage was taken to
be that of standard clinical floor space. The waiting
room is used for a variety of different purposes, so
its contribution was adjusted accordingly. Energy
use per injection was calculated by estimating the
proportional energy use of the floor space when
utilized by the injection service and dividing it
by the total number of injections performed per
annum (6,000). The injection suite is not used for
other purposes. This data is summarized in Table 1.

Clinicians perform intravitreal injections with a
surgical scrub to the elbow before an injection list.
One facemask is used for a list. Attire is typically
office attire with one plastic apron per list. Hands
are sterilized between cases with a betadine scrub
or alcohol hand gel. All clinicians use separate
sterile gloves and an individual intraocular injection
pack for each patient. The contents of the injection

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www.googlemaps.ie


Carbon Footprint of Intravitreal Injections; Power et al

Table 1. Emissions factors

Procurement Emission Factor (kg CO2eq per £££)
Pharmaceutical 0.43

Medical 0.28

Waste Disposal Emission Factor Range (kg CO2eq per ton)

Landfill 9-445

Incineration 1833

Travel Method Emission Factor (kg CO2eq per Km)

Car 0.178

Bus 0.101

Train 0.044

Walk/Cycle 0

Energy Use Emission Factor (kg CO2eq per KWh)

Electricity 0.59

Kg CO2eq, kilograms of carbon dioxide equivalents; Km, kilometer; KWh, kilowatt hour

Table 2. Patient travel emissions

Car Bus Train Walk/cycle

Conversion Factor 0.1778 0.11 0.044 0
Average Distance (km) 33 51 42 NA
Patients 64 29 3 4

Km, kilometers

pack and their associated data are summarized in
the Results section in Table 3. Only items used
for each separate injection were considered for
analysis (facemask and apron used for the whole
list, therefore not included).

Inclusions

Travel of patients to and from the hospital was
included in the study. This maintains consistency
with previous studies.[11–14] Although it does not
follow the PAS 2050 guidelines, we believe
that inclusion transport in this hybrid LCA is
appropriate. Patient travel is essential to the
procedure and represents a large component of
the carbon production. Due to the frequent and
recurrent nature of intravitreal injections, travel is
an important source of emissions.

Exclusions

Excluded components include but are not limited
to: items deemed negligible to overall emissions

score (e.g., ink, medical record documents),
procurement of items used over the medium to
long-term (computers, injection beds, diagnostic
tools, e.g., OCT, etc.), human inputs into the system,
building/construction costs, food and drink, staff
training, and research.

Methodology Discussion

We utilized a hybrid LCA for the calculation
of this carbon footprint. The main advantage
of this methodology is that it provides a
more comprehensive analysis than other
techniques.[22, 23] It helps to reduce the impact
of truncation error, which can be caused by
the boundary placement required in PAS 2050
adhering LCAs. The disadvantage with this
methodology is it can be less reproducible –
particularly when the methodology is poorly
defined. This can be problematic in formal industry
assessments as it can make a direct comparison
between processes more difficult. This study aimed

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Table 3. Intravitreal injection pack contents and waste disposal emission data

Item Weight (g) Classification Landfill Incineration Conversion Fx kg CO2eq

NaCl 14.68 Plastic rigid 6 0 9 0.0001

Paper Towel 20.84 Cloth 6 0 445 0.009

Sterile Gloves 31.58 Plastic film 6 0 9 0.00003

Drape 19.79 Plastic film 0 0 9 0.0002

Scleral Marker 1.76 Plastic rigid 2 4 1833 0.00004

Speculum 2.8 Metal 1 5 1833 0.00006

Wooden Cotton Buds x 5 4.08 Wood 2 4 1833 0.00009

2 ml syringe 2.72 Plastic rigid 6 0 0 0.00002

Syringe 3.71 Plastic rigid 0 6 1833 0.00008

Bevacizumab Needle 0.59 Metal 0 6 1833 0.00001

Gauze Square x 4 7.77 Cloth 6 0 445 0.004

Plastic Forceps 9.64 Plastic rigid 2 4 1833 0.0002

Iodine minim 1.5 Plastic rigid 6 0 9 0.00001

Plastic container 30 ml 3.31 Plastic rigid 6 0 9 0.00003

Plastic container 30 ml 3.31 Plastic rigid 6 0 9 0.00003

G Proxymetacaine 1.59 Plastic rigid 6 0 9 0.00001

G Chloromycetin 1.59 Plastic rigid 6 0 9 0.00001

Plastic Container Outer 27.85 Plastic rigid 6 0 9 0.00003

Outer Wrapping 37.5 Plastic film 6 0 9 0.0003

Fx, conversion Factor; Gs, weight in grams conversion; Kg CO2eq, kilograms of carbon dioxide equivalents

to make an all-encompassing, accurate estimate
of the component and total carbon production; for
this, we felt the hybrid methodology was the most
robust.

Regarding the use of input–output models to
calculate carbon emissions, values are determined
by the cost of materials. Naturally, high cost
materials will have large carbon estimates. These
values can seemingly overestimate emissions.
However, pharmaceutical agents, for example,
require extensive research and development
before coming to market. Marketing of these
agents, drug representative activities, and
education of clinicians and patients are key
components of the industry. All of these activities
create emissions. Thus, just as the monetary cost
of these critical components of drug development
are embedded in the cost of the product, it can
be argued that the downstream carbon emissions
are also embedded within the cost of the product.
We produced estimates excluding and including
the pharmaceutical agents due to their very
large contribution to emission volumes. We did

not consider potential/debatable differences
in duration of action between agents to be a
significant factor in emissions production.

RESULTS

One intravitreal injection, excluding the anti-VEGF
agent, was calculated to produce 13.68 kg CO2 eq.
The breakdown for the different contributions from
the three main sources is outlined in Figure 1.

The single largest contributor to the carbon
footprint was patient travel at 10.49 kg CO2
eq (77%) per injection. The majority of patients
travelled to and from their appointments by car.
Our service is situated in a tertiary referral center
and our catchment area is the northern half of
the province of Leinster. The average one-way
distance travelled was 38 km. Table 2 outlines
the travel emission conversion factors and the
breakdown of the common modes of transport to
the hospital.

Medical procurement (the injection pack)
accounted for 2.54 kg CO2 eq (19%). Despite

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Carbon Footprint of Intravitreal Injections; Power et al

Figure 1. Proportional carbon emissions. Kg CO2eq, kilograms of carbon dioxide equivalents

Figure 2. Estimated carbon emissions associated with the injection pack, Avastin, Lucentis, and Eylea. Kg CO2eq, kilograms of
carbon dioxide equivalents

a large amount of physical waste generated
per intravitreal injection, the carbon emissions
produced through waste disposal were negligible
– just 0.05 kg CO2 eq per injection or 0.04% of the
total emissions.

The contents of the injection packs, the method
of waste disposal and the emissions data are
summarized in Table 3. Materials deemed to be
surplus to requirements (by >75% of clinicians) are
highlighted in bold italics.

When the different anti-VEGF agents are
included, emission estimates vary widely. Using
input–output analysis, bevacizumab, ranibizumab,
and aflibercept procurement produce an estimated
20, 320, and 423 kg CO2 eq, respectively, per

injection. Figure 2 compares the emissions
estimates of the anti-VEGF agents to those of the
pack.

Opportunities for Carbon Reductions

No immediate or realistic opportunity for carbon
savings related to building energy use was
identified. If the service facilities/logistics allow,
patients can receive injections on the same day
as clinic appointments, reducing overall hospital
attendances and lowering emissions. The use of
bilateral same-day injections is another potential
mitigation strategy. Bilateral same-day injections

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Carbon Footprint of Intravitreal Injections; Power et al

are safe, however, patient safety and medico-legal
concerns persist.[24, 25]

We identified the procurement of the injection
pack as an additional opportunity to reduce
emissions. A survey of the clinicians performing
the injections identified several items that were
deemed to be safely dispensable from the
intravitreal packs – these were: plastic tongs for
betadine application, a 2 ml syringe, the hard
outer plastic container, and the paper hand towel.
Betadine is generally applied to the patient’s
skin using a cotton gauze held by hand, the 2
ml syringe was not used and the hand towel
was not necessary because alcohol was used
rather than hand washing to sterilize the hands
between patients. Removal of these items from
our packs achieved a price reduction of €2.05
per pack, negotiated with our supplier. Using the
input–output model for production, distribution,
and consumption and the lifecycle-based analysis
for disposal, this equates to 0.56 kg CO2 eq per
injection (4%) or an overall reduction of 3,360
kg CO2 eq per annum for our hospital-based
intravitreal service (based on our annual provision
of 6,000 injections).

DISCUSSION

Discussion around the importance of sustainability
in ophthalmology has increased over the past
decade.[26, 27] To our knowledge, this is the first
study to estimate the carbon emissions attributable
to intravitreal injections. This intervention has
rapidly become the most common invasive
procedure performed in ophthalmology.[28] An
intravitreal injection is a typical medical procedure.
We hope that our breakdown of the sources of
emissions, from the different components of the
procedure, will help to identify the most suitable
targets for carbon reduction strategies.

Current estimations of international rates of
intravitreal injections differ. Data from the USA
estimates the 2013 rate at 130 injections per
100,000 population.[16] The USA estimates project
a 10–20% per annum increase in numbers of
injections performed. If we use an estimate of
15% and adjust the UK 2015 estimate of 714 per
100,000, the estimated rate for 2018 is 1,248 per
100,000. For the current UK population (66 million),
this amounts to 824,000 injections. Though pack
contents will differ across units, similar changes to

contents of injection packs used in the UK could
yield a substantial reduction (approximately 460
ton CO2 eq). To put the figures into context, a one-
way, economy class transatlantic flight from London
to New York City produces an estimated 480 kg
CO2eq per person.

[29]

In addition to the reductions possible in carbon
emissions, the judicious omission of unnecessary
single-use plastics from routine procedure packs
has other environmental benefits. The European
Union (EU) has recently followed some countries
in banning the use of several forms of single-use
plastics.[30] Plastic does not biodegrade and there
are an estimated 269,000 tons of plastic floating
in the ocean.[31] Three of the four dispensable
items in our packs are hard plastic. Dialogue with
manufacturing companies may be able to further
reduce the plastic contents of the packs through
omission of unnecessary items. The annual weight
of the dispensable plastic in the packs used by our
service is over 240 kg.

In 2013, Morris et al estimated the carbon
emissions attributable to the Cardiff cataract
pathway to be 181 kg CO2 eq, with an annual
production of 63 mega ton kg CO2 eq in England.

[14]

The proportional breakdown of the components
of the cataract pathway differs slightly from that
of an intravitreal injection. Procurement was the
largest proportional contributor in the cataract
pathway at 53.8%. Procurement would also be the
highest proportional contributor in the intravitreal
injection footprint should the anti-VEGF agents
use be included. Proportional energy use was
understandably greater for the cataract surgery
pathway (36.1% vs 4%), as was the contribution of
waste disposal (1.6% vs 0.05%). Proportional travel
estimates were less in the cataract surgery pathway
(10.1% vs 76.6%) but gross travel emissions were
greater (18.3 vs 10.49 kg CO2 eq). The cataract
pathway included two separate round-trip journeys
per patient, potentially explaining the higher gross
figure.

Our study has allowed us to identify some easily
implemented changes, which would achieve a
significant carbon reduction if extrapolated to a
national level and is an example of a “bottom-up”
change that is immediately realizable. The far larger
contribution of the production, distribution, and
consumption elements of procurement, compared
with the waste disposal element, highlights the
need to target emission generation at source.
Efforts to recycle (challenging in healthcare due

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Carbon Footprint of Intravitreal Injections; Power et al

to infection control concerns) and improve waste
management are likely to be small in comparison.
The omission of unnecessary items eliminates all
of the emissions embedded in the procurement
process of an item.

Our study has some limitations. As
demonstrated by the comparison of cataract
surgery and intravitreal injection, carbon estimation
is, by its nature, variable. It is impossible to
measure every direct and indirect contribution
to these complex processes. Our boundaries
exclude known and unknown sources of carbon
emissions. Methodologies for carbon estimation
are not designed with specific industries in mind
and interpretations of models can differ. Patient
travel estimates reflect the local geography and
the boundaries of the studied catchment area;
thus, variation is expected. Calculations relating to
the production of materials (or the “procurement”
component of this footprinting analysis) may under
and overestimate emissions as the estimates are
based on price alone. These estimates are based
on production in broadly defined industries, not
directly on ophthalmology. We recognize the
limitations of our estimates based on input–output
data but feel that they are sufficiently accurate to
satisfy our aims.

Other studies have estimated the GHG
production associated with the production of
pharmaceutical agents. Parvatker et al recently
performed a component LCA of several inhaled
anesthetic agents using a chemical-engineering
scale-up technique.[32] This is a more accurate
measure of the emissions associated with the
simple production of a volume of a drug. It does
not, however, consider the background emissions
associated with research and development,
marketing, etc. In addition, it is a technique, which
is very complex to perform so it may be difficult for
clinicians and non-specialists to replicate it.

If sustainability is a goal of the wider
ophthalmology community, intravitreal injections,
due to their exponential increases in volume,
should be a prime target for such efforts. Despite
some limitations, we feel our estimation is a
good guide for the component breakdown of the
carbon emission profile of an intravitreal injection.
The calculation of a carbon footprint is clearly
not necessary for every individual procedure.
The results not always intuitive and analysis of a
process can give us valuable insight into where
to focus on reduction strategies. We echo Morris

et al in stressing the importance of focusing
on procurement while again demonstrating
the somewhat limited potential impact of
waste recycling strategies.[14] In the future, the
introduction of long-acting agents may reduce the
number of injections performed.[33] This represents
the greatest potential to achieve large scale
emissions reductions associated with intravitreal
injections as it would tackle both procurement
and travel associated emissions. Extensive carbon
savings would be achievable, not to mention the
obvious economic and service provision benefits.

For many clinicians, the large quantity of
GHG produced by our health sector may seem
outside of their direct control or responsibility.
Nonetheless, clinicians should recognize that they
can make simple changes that can have an
immediate positive impact on carbon emissions.
We must lead by example and address the
harmful effects of mindless wastefulness in our
daily practice. Sensible alterations to pack contents
can have economic benefits, as well as lowering
GHG production. These reductions can have
a large overall impact when extrapolated to a
service or even a national level. In addition to
lowering GHG production, the reduction in single-
use plastics has other environmental benefits
beyond the scope of this study. Pre-prepared
packs are in widespread use for many minor
procedures across healthcare, and our study may
encourage other clinicians to make similar choices.
We strongly advocate bottom-up interventions to
drive an overall reduction in carbon emissions in
ophthalmology and healthcare as a whole.

Acknowledgement

The authors would like to thank Prof. Nick Holden,
University College Dublin, School of Biosystems
and Food Engineering for his help in advising us
on our carbon footprinting methodology.

Financial Support and Sponsorship

None.

Conflicts of Interest

The authors declare no conflicts of interest.

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