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Proceedings S.Z.M.C. Vol: 34(2): pp. 4-6, 2020.             PSZMC-743-34-2-2020 
 
Transfusion Medicine Practice in a Pandemic; Use of 
Convalescent Plasma in the Management of COVID-19 
Sarah Tehseen 
Saskatchewan Health Authority, Canada CA. 
 

COVID-19 pandemic has now infected over 1 
million people and caused 62,000 deaths around the 
world as of April 5th, 2020.1 It is caused by a virus 
of Coronaviridae family now named SARS-CoV (2) 
which leads to severe viral pneumonia and acute 
respiratory distress syndrome (ARDS).2 The number 
of cases continue to rise globally with a growing 
increase in mortality. At this time, no specific 
treatment is found to be curative for COVID-19 
however multiple experimental treatments are being 
explored.3 
Current therapy for COVID-19 is mainly supportive 
with a focus on prevention by reducing and 
containing the spread of the virus.3The experimental 
therapies being investigated include antivirals like 
lopinavir-ritonavir, interferon-1β, the RNA 
polymerase inhibitor Remdesivir and chloroquine.4 
The use of plasma from convalescent COVID-19 
patients is an attractive option since it provides 
passive immunity by neutralizing antibodies and has 
precedence in the management of viral pneumonia 
caused by other viruses of Coronoviridae family as 
well. Though the quality of evidence of available 
literature is moderate to low, the studies showed a 
consistent reduction in mortality among patients 
with influenza or SARS-CoV (1).5 Blood supplier 
systems in Canada and the US are currently working 
towards developing clinical trials to investigate the 
effect of convalescent plasma on morbidity and 
mortality from COVID-19.6,7 FDA has approved its 
use for critically ill patients following expedited 
approval on a case by case basis.12 
 
The Pathophysiological basis for use of 
Convalescent Plasma:  
Both SARS-CoV(1) and the novel SARS-CoV-2 are 
highly pathogenic Coroviruses with a strong affinity 
for lungs. These viruses enter the target cells by (S) 
spike glycoproteins through the ACE-2 receptors. It 
is postulated that the neutralizing antibodies against 
these viruses inhibit the S spike mediated entry into 
target cells.8 Multiple animal models have also 
shown that these antibodies prevent re-infection and 
viral replication both SARS CoV (1) and CoV (2) 
viruses.9,10 

The source of these neutralizing antibodies can be 
human convalescent plasma or specific preparations 
in animal hosts. The human convalescent plasma 
can then be fractionated and treated to form hyper-
immune globulin. Hyper-immune globulin and 
animal-based antibody sources both require multiple 
processing steps which will be ultimately beneficial 
but cannot provide a rapid source of antibodies for 
the current epidemic. Hence, currently, straight 
administration of convalescent COVID-19 plasma 
seems to be the most rational step in the 
management of critically ill patients.13,14 
As mentioned above, plasma from convalescent 
patients will act through neutralizing antibodies that 
prevent viral entrance into target cells and potential 
replication. Other mechanisms such as antibody-
mediated cellular cytotoxicity and phagocytosis may 
also be possible.14 
A recent report of five critically ill individuals with 
ARDS and SARS-CoV (2) infection indicated 
resolution of ARDS in 2 patients and an overall 
improvement in respiratory status with no mortality 
in all 5 patients. All patients demonstrated a 
significant reduction in viral load. These patients 
received plasma from five donors who had 
recovered from SARS CoV (2) infection with high 
titers of neutralizing antibody.11 This case series in 
human subjects suggests a beneficial effect of the 
use of convalescent plasma, however, it is not 
possible to determine the extent of benefit from 
convalescent plasma as these patients were 
receiving multiple therapies at the same time 
including antivirals and anti-inflammatory agents.  
 
Potential Complications of Plasma 
Administration: 
Human plasma administration is not risk-free and 
can lead to mild as well as severe complications 
such as transfusion reaction associated lung injury 
(TRALI) and anaphylaxis. However, most studies 
do not indicate any significant side effects of plasma 
transfusion.5 There were two reported cases of 
possible TRALI after the use of convalescent 
plasma for an Ebola and a middle eastern respiratory 
syndrome (MERS) patient.15,16 
Another consideration is the pro-inflammatory 
characteristics of plasma and antibodies which may 

 



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Transfusion Medicine Practice in a Pandemic; Use of Convalescent Plasma in the Management of COVID-19 

exacerbate the ARDS contracted by COVID-19 
patients. Although the previous reports on the use of 
convalescent plasma as well as the current case 
series of 5 patients report no such adverse effects, 
this risk should be contemplated when deciding on 
plasma administration. 
 
Dose and Timing of Plasma Administration: 
There is no recommended dose of plasma for 
COVID-19 patients. The patients treated during the 
SARS-CoV2 epidemic received two consecutive 
transfusions of 200-250 ml of ABO compatible 
plasma collected from donors on the same day11 
Patients with Ebola virus were also treated with a 
similar dose.17 Clinical trials being designed to 
study the impact of convalescent plasma are using 2 
doses of 200-250ml of plasma over 1-2 days.23 
Data obtained from the use of convalescent plasma 
for viral illnesses has shown its maximum benefit 
when administered early during disease.  It can be 
hypothesized that the rapid reduction of high viral 
inoculum with neutralizing antibodies leads to the 
blunting of pro-inflammatory response and ARDS 
compared to late administration when the 
inflammatory response has been established.18 In the 
reported case series on the use of human plasma for 
COVID-19 patients, it was given between days 10-
22 of hospital admission.11 Among patients infected 
with SARS CoV-1, the plasma was administered on 
day 14 of admission according to observational 
studies18 The use of convalescent plasma is only 
investigated in patients with severe respiratory 
illness needing significant support.7,11 
 
Donor Perspectives: 
Donors should be considered for plasma collection 
after complete resolution of symptoms for at least 
28 days before donation or resolution of symptoms 
for 14 days with a negative test for SARS-CoV2.7 
They can be contacted through the hospital 
registries after discharge or through widespread 
educational and marketing campaigns catered to 
both public and healthcare providers. Screening the 
population for titers of IgG antibodies against 
SARS-CoV2 as potentials for plasma donation is 
another option but has significant budgetary 
constraints.21 
These donors should obey the local guidelines for 
donor eligibility. At the very least infectious disease 
testing for transfusion-transmitted disease must be 
performed before accepting the plasma donation. It 
is recommended that plasma should be collected 
from men and women with no prior history of 
pregnancy to mitigate the risk of TRALI.7 

The titers of neutralizing antibodies in the plasma of 
convalescent SARS-CoV(1) patients reached a peak 
at 4 months and continued to decline afterward.19 
The patterns of antibody rise and decline in SARS-
CoV (2) convalescent patients are still undetermined 
but it is likely beneficial to consider plasma 
donation in the first 4 months after diagnosis of 
COVID-19 for maximal benefit. It is also interesting 
that individuals with severe illness due to SARS-
CoV1 were more likely to have high titers of 
neutralizing antibodies in their plasma. Whether this 
holds for SARS-CoV2 as well needs to be 
elucidated.20 
Ideally, the collected plasma should be tested for 
titers of neutralizing antibodies against SARS-
CoV2. Current clinical trials in the US are using a 
minimum titer of 1:64 as a criterion for plasma 
collection based on prior research on SARS-CoV1.22 
However, the determination of antibody titers may 
prove to be difficult in resource-limited settings. At 
a minimum, potential donors should be tested for 
the presence of neutralizing antibodies using ELISA 
or similar techniques.21 
 
Plasma Collection and Storage: 
Plasma collection can be undertaken using pheresis 
machines or following a whole blood donation. One 
benefit of pheresis is that it will allow the donor to 
donate plasma every 2 weeks whereas whole blood 
donations can only be performed every 12 weeks. 
Whole blood donation and subsequent separation 
and storage of plasma may be more applicable to 
resource-limited settings and should be considered.  
After collection from convalescent donors, plasma 
can be donated immediately or frozen at -18 degrees 
Celsius for up to 12 months for later use or pooled 
to form hyperimmune globulin. Pathogen reduction 
technique for viral inactivation of plasma, if 
available, should be performed before plasma 
administration.17 
 

CONCLUSION 

There are no proven therapeutic modalities for the 
cure of COVID-19. While significant research is 
underway to develop medical therapies and vaccines, 
none are available in a time-sensitive fashion. The 
use of convalescent plasma as a source of passive 
immunity against the virus is a feasible and timely 
solution for critically ill patients. This option can be 
utilized in resource-limited settings as well with 
appropriate modifications to plasma collection, 
donor testing, and administration based on locally 
developed protocols. As plasma administration has 
some significant risks, its use must be carefully 
weighed against the benefits when considering 



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Transfusion Medicine Practice in a Pandemic; Use of Convalescent Plasma in the Management of COVID-19 

treatment. Ongoing clinical trials will help 
determine the optimal dose, timing and the patient 
cohort most likely to benefit from this treatment 
modality. 
 

REFERENCES 

1. https://www.who.int/docs/default-source/ 
coronaviruse/situation-reports/20200405-sitrep-
76-covid-19.pdf?sfvrsn=6ecf0977_4 

2. Lu, Roujian, et al. "Genomic characterization 
and epidemiology of 2019 novel corona virus: 
implications for virus origins and receptor 
binding." The Lancet 395.10224. 2020;565-574. 

3. Fauci, Anthony S., H. Clifford Lane, and Robert 
R. Redfield. "COVID-19 - navigating the 
uncharted." 2020; 1268-1269. 

4. World Health Organization. WHO R&D 
Blueprint: informal consultation on 
prioritization of candidate therapeutic agents for 
use in novel corona virus 2019 infection, 
Geneva, Switzerland, 24 January 2020. No. 
WHO/HEO/R&D Blueprint (nCoV)/2020.1. 
World Health Organization, 2020. 

5. Mair-Jenkins, John, et al. "The effectiveness of 
convalescent plasma and hyperimmune 
immunoglobulin for the treatment of severe 
acute respiratory infections of viral etiology: a 
systematic review and exploratory meta-
analysis." The Journal of infectious diseases 
211.1. 2015; 80-90. 

6. Levy, Prokopchuk-Gauc et al. NEBMC 
statement on convalescent plasma and IVIG for 
treatment of COVID-19 infection.March31st,2020 

7. https://www.fda.gov/vaccines-blood-biologics/ 
investigational-new-drug-ind-or-device-
exemption-ide-process-cber/investigational-
covid-19-convalescent-plasma-emergency-inds 

8. Walls, Alexandra C., et al. "Structure, function, 
and antigenicity of the SARS-CoV-2 spike 
glycoprotein." Cell (2020). 

9. Subbarao, Kanta, et al. "Prior infection and 
passive transfer of neutralizing antibody prevent 
replication of severe acute respiratory syndrome 
corona virus in the respiratory tract of 
mice." Journal of virology 78.7. 2004; 3572-7. 

10. Bao L, Deng W et al. Re-infection could not 
occur in SARS-CoV (2) infected rhesus 
macaques. Boprxiv. 2020 0313 (not yet peer-
reviewed) 

11. Shen, Chenguang, et al. "Treatment of 5 
Critically Ill Patients with COVID-19 with 
Convalescent Plasma." JAMA. 2020. 

12. Tanne, Janice Hopkins. "COVID-19: FDA 
approves use of convalescent plasma to treat 
critically ill patients." 2020. 

13. Beigel, John H, et al. "Safety and tolerability of 
a novel, polyclonal human anti-MERS corona 
virus antibody produced from 
transchromosomic cattle: a phase 1 randomized, 
double-blind, single-dose-escalation study." The 
Lancet Infectious Diseases 18.4. 2018; 410-18. 

14. Casadevall, Arturo, and Liise-anne Pirofski. 
"The convalescent sera option for containing 
COVID-19." The Journal of clinical 
investigation 130.4 (2020). 

15. Mora-Rillo, Marta, et al. "Acute respiratory 
distress syndrome after convalescent plasma 
use: treatment of a patient with Ebola virus 
disease contracted in Madrid, Spain." The 
Lancet Respiratory Medicine 3.7. 2015; 554-62. 

16. Chun, Sejong, et al. "Possible transfusion-
related acute lung injury following convalescent 
plasma transfusion in a patient with the Middle 
East respiratory syndrome." Annals of 
laboratory medicine 36.4. 2016; 393-5. 

17. Tiberghien, Pierre, et al. "Collecting and 
evaluating convalescent plasma for COVID-19 
treatment: why and how." Vox Sanguinis. 2020. 

18. Momattin, Hisham, et al. "Therapeutic options 
for Middle East respiratory syndrome 
coronavirus (MERS-CoV)–possible lessons 
from a systematic review of SARS-CoV 
therapy." International Journal of Infectious 
Diseases 17.10 .2013; 792-8. 

19. Cao, Wu-Chun, et al. "Disappearance of 
antibodies to SARS-associated corona virus 
after recovery." New England Journal of 
Medicine 357.11. 2007; 1162-3. 

20. Hung, Ivan FN, et al. "Effect of clinical and 
virological parameters on the level of 
neutralizing antibody against pandemic 
influenza A virus H1N1 2009." Clinical 
Infectious Diseases 51.3. 2010; 274-9. 

21. Focosi, Daniele, et al. "CONVALESCENT 
BLOOD PRODUCT THERAPIES FOR 
COVID-19: A SYSTEMATIC REVIEW."2020. 

22. https://clinicaltrials.gov/ct2/show/study/NCT04
325672 

23. https:/clinicaltrials.gov/ct2/show/NCT04332835 
 
The Authors: 
Dr. Sarah Tehseen 
Saskatchewan Health Authority, Canada CA.  
Email: sarah.tehseen@gmail.com