Implementing Best Practices for Blood Management

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Implementing Best Practices for Blood Management

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Title: Implementing Best Practices for Blood Management

1
(No Transcript)
2
Learning Objectives
After taking part in the workshop, participants
should be able to

Outline the prevalence of anemia in medical and
surgical patients
List the potential clinical and pharmacoeconomic
benefits of current blood management strategies
Identify the risks associated with transfusion
Determine the appropriate transfusion trigger in
managing individual patients with anemia
Develop and implement critical pathways for blood
management based on current best practices and
available critical pathways resources

3
Workshop Materials

Workshop binder includes
Presentation slides
Samples of critical pathway implementation
resources (eg, algorithms, pocket cards, posters,
form letters)
Champion sign-up form
Breakout session worksheets
CME/CE evaluations

4
Workshop Materials (cont.)

Complimentary USB Flash Drive
Presentation slides
Sample critical pathways implementation resources
such as
Critical pathway algorithms
Pocket cards
Posters
Templates and form letters
Additional resources (eg, organizations to
contact, Web site links for transfusion
guidelines, suggested reading)

5
Breakout Sessions

Please think about how the data presented today
may impact your critical pathways for blood
management
During the breakout sessions, you will begin the
process of developing or updating your blood
management pathways
There will be 3 breakout sessions
Review the sample critical pathways in your
binder and identify areas that may need
modification at your institution (30 min)
Identify barriers to implementing critical
pathways at your hospital (15 min)
Develop a plan of action to overcome barriers to
implementation (15 min)

6
Blood An Emotional Topic

the sweeping story of a substance that has been
feared, revered, mythologized, and used in magic
and medicine from earliest timesa substance that
has become the center of a huge, secretive, and
often dangerous worldwide commerce.
From the publishers description of the book

Starr D. Blood An Epic History of Medicine and
Commerce. New York, NY HarperCollins Publishers
2000.
7
Blood Collection and Utilization in the US

15 million units of whole blood and RBCs donated
29 million units of blood components transfused
Mean age of whole-bloodderived platelet units
3.16 days at transfusion
3.08 days for an apheresis platelet unit
Average cost of RBC units increased by 30.8
from 2002
135 hospitals canceled elective surgery on 1
days because of blood inventory shortages

US Dept of Health and Human Services. The 2005
Nationwide Blood Collection and Utilization
Survey Report. Available at http//portal.aabb.or
g/apps/docs/05nbcusrpt.pdf. Accessed April 23,
2007.

2004 statistics.
8
The 3 Pillars of Blood Management

Optimizing the hemoglobin level by recognizing,
detecting, and treating anemia in all clinical
situations
Understanding anemia and harnessing the
physiology of it, making it tolerable while
optimization occurs
Having a consistent approach to blood conservation

9
Prevalence of Anemia
10
WHO Definition of Anemia vsHb Distribution in
the General Population
Anemia in Men Hb lt13 g/dL
Hb distribution in women13.3 ? 0.9 g/dL
3000
Hb distribution in men15.2 ? 0.9 g/dL
2500
2000
N40,000 (NHANES III, 1988-1994)
Frequency
1500
1000
500
0
10
10.5
11
11.5
12
12.5
13
13.5
14
14.5
15
15.5
16
16.5
17
17.5
18
Hb Level (g/dL)
World Health Organization. Geneva, Switzerland
2001. Dallman PR, et al. In Iron Nutrition in
Health and Disease. London, UK John Libbey Co
199665-74.
11
Prevalence of Anemia in Critically Ill Patients
Percentage of Critically Ill Patients With Anemia
Vincent JL, et al. JAMA. 20022881499-1507.von
Ahsen N, et al. Crit Care Med. 1999272630-2639.
12
Prevalence of Anemia at Admission Among Various
Patient Groups
Patient type Prevalence () Reference

Wilson A, et al. Am J Med. 2004116(suppl
7A)50S-57S.
Shander A, et al. Am J Med. 2004116(suppl
7A)58S-69S.
Knight K, et al. Am J Med. 2004116(suppl
7A)11S-26S.
Belperio PS, et al. Am J Med. 2004116(suppl
7A)27S-43S.

13
Incidence of Preoperative Anemia
30 25 20 15 10 5 0
65,788 patients (1980-2000) Preoperative
evaluation WHO anemia definition
MenWomen

20-30
31-40
41-50
51-60
61-70
71-80
81-90
gt90
Years
Reproduced with permission from Kulier A, Gombotz
H. Anaesthesist. 20015073-86.
14
Anemia A Potent Multiplierof Mortality
No HF, No CKD, No Anemia
1
Anemia Only
1.9
CKD Only
2.05
HF Only
2.86
CKD, Anemia
3.37
HF, Anemia
3.78
HF, CKD
4.86
HF, CKD, Anemia
6.07
0
1
2
3
4
5
6
7
Relative Risk of 2-Year Mortality
N 1.1 million (5 Medicare sample, 1996-1997)
Herzog CA, et al. Presented at 6th Annual
Scientific Meeting of the Heart Failure Society
of America September 22-25, 2002 Boca Raton,
Florida. Abstract 226.
15
Effects of Anemia Treatment on Renal Patients
Partial correction of anemia to Hb 11-12 g/dL in
patients with CKD may
Reduce morbidity, hospitalization, and
mortality1-3
Improve QOL,6,7 exercise capacity,8cognitive
function,2 and sexual function3
Improve LV structureand function4,5
1. Xia H, et al. J Am Soc Nephrol.
1999101309-1316. 2. Bedani PL, et al. Nephron.
200189350-353. 3. Wu SC, et al. Scand J Urol
Nephrol. 200135136-140. 4. Hayashi T, et al. Am
J Kidney DIs. 200035250-256. 5. Portoles J, et
al. Am J Kidney Dis. 199729541-548. 6. Revicki
DA, et al. Am J Kidney Dis. 199525548-554. 7.
Furuland H, et al. Nephrol Dial Transplant.
200318353-361. 8. Clyne N, et al. Nephron.
199260390-396.
16
An Introduction to Blood Management
17
Blood Management
Patient Centered

Appropriate Transfusion Medicine
Blood Conservation
18
Potential Benefits of Blood Management

Addresses the issue of anemia
Reduces patient exposure to allogeneic blood
Improves patient outcome
Helps with preserving current blood supplies
Reduces costs
Prepares for forthcoming pay-per-performance
guidelines and other future regulatory issues

19
Strategies for Blood Management in Surgical
Patients

Preoperative
Reduce level at which transfusion is performed
Increase preoperative RBC mass (EPO, iron)
Preoperative autologous donation
Intraoperative
Meticulous hemostasis and operative technique
Acute normovolemic hemodilution
Blood salvage
Postoperative
Restricted phlebotomy
Blood salvage

Adapted from Goodnough LT, et al. Transfusion.
200343668-676.
20

Understanding the Physiology and Reserve of
Anemia

21
Anemia Lower the Transfusion Trigger Point?

Hb 7.0 g/dL-9.0 g/dL sufficient in critically ill
patients
Hébert PC, et al. N Engl J Med. 1999340409-417.
Much lower Hb tolerated (gt5.0 g/dL) in
nonstressed normal patients
Weiskopf RB, et al. Anesthesiology.
2000921646-1652.
Patients with CAD may require Hb levels in
slightly higher ranges (8.0 g/dL-9.0 g/dL) and
avoid tachycardia
?-blockers
Euvolemia
Minimum, safe (optimal) Hb/Hct unknown
Trigger can be lowered to avoid transfusions

22
Compensatory Mechanisms of Anemia

Hb 6.0-7.0 g/dL tolerable (blood loss
controlled good cardiac function)
? Cardiac output
? Coronary flow
? Blood viscosity
? O2 consumption
? O2 extraction

Corwin HL, Hébert PC. Physiology of anemia and
red blood cell transfusion. In Spiess BD, Spence
RK, Shander A, eds. Perioperative Transfusion
Medicine. 2nd ed. Philadelphia Lippincott
Williams Wilkins 2006chap 6.
23
Adaptation to Anemia

Low Hb is well tolerated for short periods
Maintenance of perfusion is required for
tolerance of anemia
High viscosity fluid (colloid) is better than
crystalloid not albumin
For severe anemia add high FIO2 to increase the
dissolved portion of O2

24
Should the transfusion trigger in your
institution be revised?Discussion
25

Pharmacologic Agents for the Treatment of Anemia

26
Erythropoietin Regulates Red Blood Cell
Production
Renal interstitial peritubular cells detect low
blood oxygen levels
EPO stimulates the proliferation and
differentiation of erythroid progenitors into
reticulocytes and prevents apoptosis
Erythropoietin (EPO) secreted into the blood
EPO
More reticulocytes enter circulating blood
Increased oxygen delivery to tissues
Reticulocytes differentiate into erythrocytes,
increasing the erythron size
Dessypris E. In Lee G, et al, eds. Wintrobes
Clinical Hematology. Vol 1. Baltimore, Md
Lippincott, Williams Wilkins
1998169-192. Bunn H. In Isselbacher K, et al,
eds. Harrisons Principles and Practice of
Internal Medicine. 13th ed. New York, NY
McGraw-Hill 19941717-1721.
27
Erythropoietic AgentsExogenous Erythropoietin

Formulations
Epoetin alfa (global)
Epoetin beta, epoetin delta, epoetin omega
(non-US, international)
Darbepoetin alfa (novel erythropoiesis-stimulating
protein with longer terminal half-life than
epoetin alfa)
Hematologic effects identical to endogenous
erythropoietin
Apoptotic agents neuro-/cardioprotection

28
FDA-Approved Indications for Erythropoiesis-Stimul
ating Agents

Epoetin alfa (Procrit)1
Treatment of anemia of chronic renal failure
patients
Treatment of anemia in zidovudine-treated
HIV-infected patients
Treatment of anemia in cancer patients on
chemotherapy
Reduction of allogeneic blood transfusion in
surgery patients
Darbepoetin alfa (Aranesp)2
Treatment of anemia associated with chronic renal
failure, including patients on dialysis and
patients not on dialysis
Treatment of anemia in patients with nonmyeloid
malignancies where anemia is due to the effect of
concomitantly administered chemotherapy

Procrit (epoetin alfa) prescribing information.
Raritan, NJ Ortho Biotech Products, LP 2007.
Aranesp (darbepoetin alfa) prescribing
information. Thousand Oaks, Calif Amgen Inc.
2007.

29
Erythropoietin Dosing

Use the lowest dose that will gradually increase
the Hb concentration to the lowest level
sufficient to avoid the need for RBC transfusion
Darbepoetin alfa administration (starting dose)
Chronic renal failure IV or SC as a single
weekly injection
Patients receiving chemotherapy SC weekly or
once every 3 weeks
Epoetin alfa administration (starting dose)
Chronic renal failure IV or SC injection 3 x
weekly
Zidovudine-treated HIV-infected patients IV or
SC injection 3 x weekly
Cancer patients on chemotherapy SC 3 x weekly or
weekly
Surgery patients
300 U/kg/d SC for 10 days before surgery, on the
day of surgery, and for 4 days after surgery or
600 U/kg SC once weekly (21, 14, and 7 days
before surgery) plus a fourth dose on the day of
surgery
All patients should receive adequate iron
supplementation

IV route is recommended for patients on dialysis.
Aranesp (darbepoetin alfa) prescribing
information. Thousand Oaks, Calif Amgen Inc.
3/2007. Procrit (epoetin alfa) prescribing
information. Raritan, NJ Ortho Biotech Products,
LP March 2007.
30
New Safety Information for ESAs

Revised product labeling for Aranesp, Epogen,
and Procrit includes a new boxed warning about
using the lowest dose possible to avoid the need
for blood transfusion because of the increased
risk for death and serious cardiovascular events
when administered to achieve a target Hb gt12 g/dL
in cancer, renal failure, and surgical
patients1-4
In cancer patients, the use of ESAs
Shortened the time to tumor progression in
patients with advanced head and neck cancer
receiving RT when administered to target a Hb gt12
g/dL
Shortened overall survival and increased deaths
attributed to disease progress at 4 mo in
patients with metastatic breast cancer receiving
CT when administered to a Hb gt12 g/dL
Increased the risk of death when administered to
a target Hb gt12 g/dL in patients with active
malignant disease receiving neither CT nor RT.
ESAs are not indicated for this population

US Food and Drug Administration Center for Drug
Evaluation and Research. Information for
Healthcare Professionals. Erythropoiesis
stimulating agents (ESA) Aranesp (darbepoetin),
Epogen (epoetin alfa), and Procrit (epoetin
alfa). FDA alert 11/16/2006, updated 2/16/2007
and 3/09/2007. Available at http//www.fda.gov/cd
er/drug/InfoSheets/HCP/RHE2007HCP.htm. Accessed
April 30, 2007.
Aranesp (darbepoetin alfa) prescribing
information. Thousand Oaks, Calif Amgen Inc.
3/2007.
Epogen (epoetin alfa) prescribing information.
Thousand Oaks, Calif Amgen Inc. 3/2007.
Procrit (epoetin alfa) prescribing information.
Raritan, NJ Ortho Biotech Products, LP March
2007.

31
Strategies for Primary and Secondary Prevention
of Venous Thromboembolism

Pharmacologic1,2
LMWH (eg, enoxaparin, dalteparin)
Unfractionated heparin (UFH)
Oral anticoagulants (eg, warfarin)
Antiplatelet (eg, aspirin)
Pentasaccharide (eg, fondaparinux)
Direct thrombin inhibitors (eg, bivalirudin,
argatroban)

Mechanical1
Intermittent pneumatic compression
Graduated compression elastic stockings

1. Geerts WH, et al. Chest. 2004126(3
suppl)338S-400S. 2. Nutescu E, Racine E. Am J
Health-Syst Pharm. 200259S7-S14.
32
CMSs Final Coverage Determination for the Use of
ESAs in Cancer

On July 30, 2007, CMS announced its final NCD for
the use of ESAs in cancer and related neoplastic
conditions. Tx is only reasonable and necessary
under the following conditions
The Hb level immediately prior to initiation or
maintenance of ESA tx is lt10 g/dL (or HCT lt30)
The starting dose for ESA tx is the recommended
FDA label starting dose, no more than 150/U/kg 3
x wk for epoetin and 2.25 µg/kg/wk for
darbepoetin alpha. Equivalent doses may be given
over other approved time periods
Maintenance of ESA therapy is the starting dose
if the Hb level remains lt10 g/dL (or HCT lt30) 4
wk after initiation of therapy and the rise in Hb
is ?1 g/dL (HCT ?3)

Centers for Medicare Medicaid Services (CMS).
Decision Memo for Erythropoiesis Stimulating
Agents (ESAs) for non-renal disease indications
(CAG-00383N). Available at https//www.cms.hhs.go
v/mcd/viewdecisionmemo.asp?id203. Accessed
September 20, 2007..
33
CMSs Final Coverage Determination for the Use of
ESAs in Cancer (cont.)

For patients whose Hb rises lt1 g/dL (HCT rise
lt3) compared to pretx baseline over 4 wk of tx
and whose Hb remains lt10g/dL after 4 wk of tx (or
HCT lt30), the recommended FDA label starting
dose may be increased once by 25. Continued use
of the drug is not reasonable and necessary if
the Hb rises lt1 g/dL (HCT rise lt3) compared to
pretx baseline by 8 wks of tx
Continued administration of the drug is not
reasonable and necessary if there is a rapid rise
in Hb gt1 g/dL (HCT gt3) over 2 wk of tx unless
the Hb remains below or subsequently falls to lt10
g/dL (or HCT lt30). Continuation and
reinstitution of ESA therapy must include a dose
reduction of 25 from the previously administered
dose
ESA tx duration for each course of chemotherapy
includes the 8 wk following the final dose of
myelosuppressive chemotherapy in a chemotherapy
regimen
CMS has narrowed the scope of its final decision
to make no NCD at this time on the use of ESAs in
myelodysplastic syndrome

In patients receiving ESAs preoperatively for
reduction of allogeneic RBC transfusions, a
higher incidence of DVT was documented in
patients not receiving prophylactic
anticoagulation
Antithrombotic prophylaxis should be strongly
considered for such patients

US Food and Drug Administration Center for Drug
Evaluation and Research. Information for
Healthcare Professionals. Erythropoiesis
stimulating agents (ESA) Aranesp (darbepoetin),
Epogen (epoetin alfa), and Procrit (epoetin
alfa). FDA alert 11/16/2006, updated 2/16/2007
and 3/09/2007. Available at http//www.fda.gov/cd
er/drug/InfoSheets/HCP/RHE2007HCP.htm. Accessed
April 30, 2007.
Aranesp (darbepoetin alfa) prescribing
information. Thousand Oaks, Calif Amgen Inc.
3/2007.
Epogen (epoetin alfa) prescribing information.
Thousand Oaks, Calif Amgen Inc. 3/2007.
Procrit (epoetin alfa) prescribing information.
Raritan, NJ Ortho Biotech Products, LP March
2007.

35
Conditions for Which CMS Proposed ESA Treatment
Not Reasonable and Necessary

Any anemia in cancer or cancer treatment patients
due to folate deficiency, B12 deficiency, iron
deficiency, hemolysis, bleeding, or bone marrow
fibrosis
The anemia associated with the treatment of acute
and chronic myelogenous leukemias (CML, AML), or
erythroid cancers
The anemia of cancer not related to cancer
treatment
Any anemia associated only with radiotherapy
Prophylactic use to prevent chemotherapy-induced
anemia
Prophylactic use to reduce tumor hypoxia
Patients with erythropoietin-type resistance due
to neutralizing antibodies
Anemia due to cancer treatment if patients have
uncontrolled hypertension

On August 8, 2007, ASH stated that it is
particularly concerned about the third limitation
because the new policy restricts coverage of ESAs
when a patients Hb rises gt10 g/dL after the
first 4 wk of therapy and has recommended that
this be an area in which CMS should reconsider
its policy
On August 1, 2007, ASCO stated that it remains
seriously concerned about many of the provisions
in the new policy, including but not limited to
The new policy restricts coverage of ESAs
whenever a patients Hb goes gt10 g/dL, which is
inconsistent with both the FDA-approved labeling
and national guidelines
For hypo- or nonresponders, the new policy allows
for a 1-time dose escalation of 25, which is
inconsistent with the FDA-approved label and
national guidelines
The new policy also states that if after any
2-wk period of time Hb rises by gt1 g/dL, ESA tx
should be discontinued (depending on the Hb
level). This could result in patients needing to
have weekly blood draws to assess the rate of Hb
rise over any give 2-wk period
ASCO will continue to pursue solutions to these
issues with CMS, HHS, and Congress

ASH statement on The Centers for Medicare
Medicaid Services (CMS) national coverage
determination (NCD) for coverage of
erythropoiesis-stimulating agents (ESAs) for
non-renal uses. August 8, 2007. Available at
http//www.hematology.org/policy/news/08082007.cfm
. Accessed September 20, 2007.
ASCO Update on ESA Final National Coverage
Decision. August 1, 2007. Available at
http//www.asco.org/portal/site/ASCO/menuitem.c543
a013502b2a89de912310320041a0/?vgnextoida353a59e3c
124110VgnVCM100000ed730ad1RCRD. September 20,
2007.

37
Recent FDA Actions for ESAs in Chronic Renal
Failureassociated Anemia

On September 11, 2007, the FDAs Cardiovascular
and Renal Drugs Advisory Committee and the Drug
Safety and Risk Management Advisory Committee
voted to reject setting a strict target Hb level
for the use of ESAs in treating anemia associated
with CRF
The committees agreed that ESA dosages used to
achieve the Hb levels in the Normal Hematocrit
and CHOIR studies are sufficient to form the
basis for ESA dosage recommendations
The committees recommended additional label
guidance and further analyses toward identifying
and appropriately treating patients who exhibit a
poor response to ESAs

U.S. Food and Drug Administration. Cardiovascular
and Renal Drugs and Drug Safety and Risk
Management Advisory Committee Meeting. September
11, 2007. Available at http//www.fda.gov/ohrms/d
ockets/ac/07/briefing/2007-4315b1-00-index.htm.
Accessed September 19, 2007.
38
Efficacy of Erythropoietin in Treating Patients
Undergoing Major Elective Orthopedic Surgery
60
N200
rHuEPO 300 U/kg SC
50
N208
N316
Placebo
40
Transfusions,
30
20
10
0
COPES1
Faris et al2
de Andrade et al3
Primary outcome event any transfusion or Hb
concentration lt8 g/dL.

Canadian Orthopedic Perioperative Erythropoietin
Study Group. Lancet. 19933411227-1232.
Faris PM, et al. J Bone Joint Surg Am.
199678A(suppl)62-72.
de Andrade JR, et al. Am J Orthop.
199625533-542.

39
Efficacy of Erythropoietin in Treating
Critically Ill Patients

Plt.002 Plt.001 Plt.01. Adapted with
permission from Corwin HL, et al. Crit Care Med.
1999272346-2350.
40
Antifibrinolytic and Hemostatic Medications

Serine protease inhibitor
Aprotinin
Inhibits trypsin, plasmin, and kallikrein
Lysine analogues
e-aminocaproic acid/tranexamic acid
Inhibit plasmin
Desmopressin acetate (DDAVP)
Recombinant activated human coagulation factor
VII (rFVIIa)
Topical hemostatic agents and tissue adhesives
and sealants

41
Aprotinin Indications, Usage, and Warnings

Indicated for prophylactic use to reduce
perioperative blood loss and the need for blood
transfusion in patients undergoing
cardiopulmonary bypass in the course of CABG
surgery who are at an increased risk for blood
loss and blood transfusion
Given by slow IV infusion an initial (test) dose
should be administered before the loading dose
Warnings
Hypersensitivity or anaphylactic reactions
higher risk on second exposure
Renal dysfunction

Trasylol (aprotinin injection) prescribing
information. West Haven, Conn Bayer
Pharmaceuticals Corporation December 2006.
42
Aprotinin (Trasylol) Black Box Warning
Trasylol administration may cause fatal
anaphylactic or anaphylactoid reactions. Fatal
reactions have occurred with an initial (test)
dose as well as with any of the components of the
dose regimen. Fatal reactions have also occurred
in situations where the initial (test) dose was
tolerated. The risk for anaphylactic or
anaphylactoid reactions is increased among
patients with prior aprotinin exposure and a
history of any prior aprotinin exposure must be
sought prior to Trasylol administration. The
risk for a fatal reaction appears to be greater
upon re-exposure within 12 months of the most
recent prior aprotinin exposure. Trasylol should
be administered only in operative settings where
cardio-pulmonary bypass can be rapidly initiated.
The benefit of Trasylol to patients undergoing
primary CABG surgery should be weighed against
the risk of anaphylaxis associated with any
subsequent exposure to aprotinin.
Trasylol (aprotinin) prescribing information.
Bayer Pharmaceuticals Corporation December 2006.
43
Risk Associated With Aprotinin Use in Cardiac
Surgery

Recent observational studies show that, compared
with the use of aminocaproic acid or tranexamic
acid or no drug, aprotinin use among patients
undergoing CABG surgery is associated with
Increased perioperative risk of acute renal
failure, myocardial infarction/heart failure, and
stroke/encephalopathy1
Increased risk of late mortality2
Investigators advise against further use of
aprotinin because safer and less expensive
alternatives are available1,2
Such studies using propensity-adjusted,
multivariable logistic regression analysis may
reflect selection, site-level, and other biases3

Mangano DT, et al. N Engl J Med.
2006354353-365.
Mangano DT, et al. JAMA. 2007297471-479.
Ferguson TB Jr. JAMA. 2007297527-529.

44
Desmopressin (DDAVP)

Synthetic analogue of vasopressin
? Plasma levels of factor VIII and von Willebrand
factor in deficient and healthy patients
? Platelet adhesion to the vessel wall (no effect
on platelet count or aggregation)
? PTT and bleeding time
Action not understood
Now reserved for mild to moderate von Willebrand
disease and uremic platelet dysfunction
Not useful in cardiac surgery
When given rapidly, may cause flushing,
hypotension, and increased heart rate

Levy JH. Pharmacological approaches to prevent or
decrease bleeding in surgical patients. In
Spiess BD, Spence RK, Shander A, eds.
Perioperative Transfusion Medicine. 2nd ed.
Philadelphia Lippincott Williams Wilkins
2006chap 30.
45
Vitamin K Therapy

IV is faster than SC or PO
1-10 mg IV effective dose slow infusion to
handle vasodilatation or anaphylaxis
Prothrombin time will begin to correct within 6
hours and is usually normal within 24 hours
Fresh frozen plasma (FFP) can be used for more
rapid correction
rFVIIa studies for warfarin reversal now under
way

46
Recombinant Factor VIIa

Produced by baby hamster kidney cell lines and
free of human protein
Initiates hemostasis through the tissue
factordependent coagulation pathway
Enhances coagulation at the site of injury
Indicated for bleeding episodes and surgical
bleeding in patients with
Hemophilia A or B with inhibitors
Factor VII deficiency

47
Off-label Use of rFVIIa

Trauma
Hepatic failure
Postprocedure bleeding (tooth extraction)
Prior to liver transplantation
Prior to invasive procedures (liver biopsy, GI
endoscopy, ethanol injection)
Reversal of warfarin effect
Upper GI bleeding
Platelet dysfunction
Cardiac surgery
Intracranial hemorrhage

48
Adjuvant Agents

While treating patients with epoetin, provide
simultaneous treatment with
Iron
Folic acid
Vitamin B12

49
Distribution of Iron in Tissue
Dietary iron
Duodenum (average, 1-2 mg per day)
Utilization
Utilization
Plasma transferrin (3 mg)
Bone marrow (300 mg)
Muscle (myoglobin) (300 mg)
Circulating erythrocytes (hemoglobin) (1800 mg)
Storage iron
Liver parenchyma (1000 mg)
Reticulo- endothelial macrophages (600 mg)
Adapted with permission from Andrews NC. N Engl J
Med. 19993411986-1995.
50
Functional Iron Deficiency

An imbalance between the iron needs of the
erythroid marrow and the iron supply, which is
not maintained at a rate sufficient to allow
normal hemoglobinization of the erythrocytes
Leads to reduced reticulocyte and erythrocyte
cellular Hb content
Characterized by both low transferrin saturation
concentration and serum iron despite normal or
elevated iron stores
Diagnosis may be based on measurement of the
proportion of hypochromic erythrocytes (HYPO) and
examination of erythrocyte hemoglobinization
using the reticulocyte Hb content (CHr) test

Scigalla P, et al. Contrib Nephrol.
19908255-64.Mcdougall IC, et al. Br Med J.
198929157-158.Thomas C, Thomas L. Clin Chem.
2002481066-1076.Mittman N, et al. Am J Kidney
Dis. 199730912-922.
51
Causes of Iron Deficiency

Inadequate iron absorption
Increased blood loss
Gastrointestinal blood loss (eg, epistaxis,
varices, gastritis, ulcer, tumor, IBD)
Genitourinary blood loss (menorrhagia, cancer,
chronic infection)
Pulmonary blood loss (pulmonary hemosiderosis,
infection)
Other blood loss (trauma, excessive phlebotomy,
large vascular malformations)

Andrews NC. N Engl J Med. 19993411986-1995.
52
Efficacy of IV Iron Therapy

Quickly replenishes depleted iron stores
Raises serum ferritin
Corrects iron-deficient erythropoiesis
Raises transferrin saturation (TSAT) and Hb
reticulocyte content (CHr)
Increases Hb, or decreases epoetin dose for same
Hb
Maintains iron-sufficient erythropoiesis
Replenishing iron stores assures adequate iron
supply in patients prone to blood loss(eg,
hemodialysis-related)

53
Current Status of Intravenous Iron Therapy
Absolute iron deficiency is defined as ferritin
lt200 µg/L and/or iron saturation lt20, or
relative iron deficiency (ferritin lt400 µg/L in
dialysis patients receiving erythropoietin
therapy, or the presence of gt10 hypochromic
erythrocytes and/or reticulocytes).
54
FDA-Approved Indications for IV Iron Therapy

Iron dextran injection, USP1,2
Patients with documented iron deficiency in whom
oral administration is unsatisfactory or
impossible
Black box warning regarding risk of fatal
anaphylactic-type reactions
Sodium ferric gluconate complex in sucrose
injection3
Iron deficiency anemia in patients undergoing
chronic hemodialysis who are receiving
supplemental epoetin therapy
Iron sucrose injection, USP4
Iron deficiency anemia in
Nondialysis dependent-chronic kidney disease
(NDD-CKD) patients receiving or not receiving an
erythropoietin
Hemodialysis dependent-chronic kidney disease
(HDD-CKD) patients receiving an erythropoietin
Pentoneal dialysis dependent-chronic kidney
disease (PDD-CKD) patients receiving an
erythropoietin

Dexferrum (iron dextran injection, USP) full
prescribing information. Shirley, NY American
Regent Laboratories, Inc.
INFeD (iron dextran injection, USP) full
prescribing information. Morristown, NJ Watson
Pharma, Inc.
Ferrelecit (sodium ferric gluconate complex in
sucrose injection) full prescribing information.
Corona, Calif Watson Pharma, Inc.
Venofer (iron sucrose injection, USP) full
prescribing information. Shirley, NY American
Regent Laboratories, Inc.

55
Dosing of Available Intravenous Iron Agents

Iron dextran (Dexferrum, INFeD)
Follow table and formula in PI for estimating
total iron required
Sodium ferric gluconate complex in sucrose
(Ferrlecit)
Recommended dosage is 10 mL (125 mg of elemental
iron) may be diluted in 100 mL of 0.9 NaCl
administered by IV infusion over 1 h or
administered undiluted as a slow IV injection (at
a rate of up to 12.5 mg/min)
Iron sucrose (Venofer)
HDD-CKD Administered undiluted as a 100 mg slow
IV injection over 2-5 min or as an infusion of
100 mg, diluted in a maximum of 100 mL of 0.9
NaCl over at least 15 min (total dose, 1000 mg)
NDD-CKD Administered as a total cumulative dose
of 1000 mg over 14 days as a 200 mg slow IV
injection over 2-5 min on 5 different occasions
within the 14-day period

Dexferrum (iron dextran injection, USP) full
prescribing information. Shirley, NY American
Regent Laboratories, Inc.
INFeD (iron dextran injection, USP) full
prescribing information. Morristown, NJ Watson
Pharma, Inc.
Ferrelecit (sodium ferric gluconate complex in
sucrose injection) full prescribing information.
Corona, Calif Watson Pharma, Inc.
Venofer (iron sucrose injection, USP) full
prescribing information. Shirley, NY American
Regent Laboratories, Inc.

56
Preoperative Iron Supplementation in Colorectal
Cancer Patients

Cohort of 569 patients undergoing colorectal
cancer surgery
32 patients with Hb 10 g/dL and 2 weeks of
preoperative iron treatment (200 mg)
84 patients with Hb 10 g/dL without iron
treatment (controls)
Results Increase in Hb by 2 g/dL in iron treated
Transfusion rate 9 in iron treated vs 27
without iron treated

Okuyama M, et al. Surg Today. 20053536-40.
57

Reducing Blood Loss During Surgery

58
Strategies for Reducing Blood Loss During Surgery

Careful surgical dissection and hemostasis
Use of controlled hypotensive anesthesia1
Maintenance of normothermia1
Blood cell salvage1
Tolerance of normovolemic anemia1
Elevating the surgical site2

Gil O, et al. Ann Thorac Surg. 1995601160-1161.
Park CK. Anesth Analg. 200091552-557.

59
Cell Salvage Technique

Collected blood is citrated, filtered, washed
with saline, concentrated, and returned to the
patient
Efficacy and quality are directly dependent on
the skill of the operator and the processes
established
Contamination by amniotic fluid, malignant cells,
or bacteria is a relative contraindication

Waters JH. Perioperative red cell salvage and
autotransfusion. In Spiess BD, Spence RK,
Shander A, eds. Perioperative Transfusion
Medicine. 2nd ed. Philadelphia Lippincott
Williams Wilkins 2006chap 33.
60
General Indications for Cell Salvage

Anticipated blood loss is 20 of the patients
estimated blood volume1
Blood would ordinarily be cross-matched1
More than 10 of patients undergoing the
procedure require transfusion1
The mean transfusion for the procedure exceeds 1
unit1
Other2
Religious beliefs, patient preference
Compatible donor blood unavailable
Adequate preoperative autologous donation not
possible
Unexpected blood loss
Red cell antibodies

Guidelines for blood recovery and reinfusion in
surgery and trauma. American Association of Blood
Banks Autologous Transfusion Committee 1996-1997
Committee. Bethesda, Md American Association of
Blood Banks 1997.
Waters JH. Perioperative red cell salvage and
autotransfusion. In Spiess BD, Spence RK,
Shander A, eds. Perioperative Transfusion
Medicine. 2nd ed. Philadelphia Lippincott
Williams Wilkins 2006chap 33.

61
Potential Cell Salvage Surgical Procedures

Cardiac
Valve replacement, redo bypass grafting
Orthopedic
Major spine, bilateral knee replacement, revision
hip replacement
Urology
Radical retropubic prostatectomy, cystectomy,
nephrectomy
Neurosurgery
Giant basilar aneurysm
Vascular
Thoracoabdominal/abdominal aortic aneurysm repair
Liver transplant

Adapted from Waters JH. Perioperative red cell
salvage and autotransfusion. In Spiess BD,
Spence RK, Shander A, eds. Perioperative
Transfusion Medicine. 2nd ed. Philadelphia
Lippincott Williams Wilkins 2006chap 33.
62
Potential Complications of Cell Salvage

Air embolism
Hypertension due to incomplete elimination of
epinephrine/norepinephrine
Hypertension/tachycardia due to incomplete
elimination of oxymetazoline
Loss of salvaged blood

Whole blood is withdrawn immediately before or
after anesthesia is initiated and is replaced
with crystalloid/colloid to maintain normovolemia
The blood is stored at room temperature in the
operating room for up to 4 h (up to 24 h with
refrigeration) and reinfused after bleeding
ceases or if the patient has an unacceptably low
Hb level
Procedure results in?O2 carrying capacity?
Blood viscosity? SNS stimulation? VR, stroke
volume, cardiac output? Number of RBCs lost
during surgery

64
Acute Normovolemic Hemodilution Calculating
Blood Withdrawal

How much volume of blood can be drawn?
Usually limited to a volume of 2000 mL or a
target hematocrit of 28, whichever comes first
Hb will decrease approximately 1 g/dL for each
unit of blood removed
Formula frequently used for determining amount of
blood to be withdrawn to reach desired Hct
V EBV ? Hcti Hctf / Hctav
Hb of 7.0 g/dL is also used
No agreed-upon standards

EBV estimated blood volume Hctav hematocrit
average during the hemodilution process Hctf
final desired hematocrit Hcti initial
hematocrit V volume of blood to be withdrawn.
Shander A, Rijhwani T. Intraoperative acute
normovolemic hemodilution. In Spiess BD, Spence
RK, Shander A, eds. Perioperative Transfusion
Medicine. 2nd ed. Philadelphia Lippincott
Williams Wilkins 2006chap 34.
65
Acute Normovolemic Hemodilution Potential
Patient Selection Criteria

Estimated blood loss 1500 mL
Preoperative Hb concentration 12 g/dL after
correction of normovolemia
Normal cardiovascular function (ie, no ischemic
signs, no ST-segment changes)
Absence of
Renal, lung, or other disease or infection
Untreated hypertension and liver cirrhosis
Coagulation abnormalities
Patients who have a type and crossmatch for
surgery

Kreimeier U, Messmer K. World J Surg.
1996201208-1217. Shander A, Rijhwani T.
Intraoperative acute normovolemic hemodilution.
In Spiess BD, Spence RK, Shander A, eds.
Perioperative Transfusion Medicine. 2nd ed.
Philadelphia Lippincott Williams Wilkins
2006chap 34.
66
Acute Normovolemic Hemodilution Safety
Considerations

The safety of ANH has been demonstrated in
cardiac,1,2 vascular,3 orthopedic,4,5 urologic,6
and general operations7 but no consensus has been
established
An ANH program must comply with AABB standards
Blood must be properly stored and labeled for
autologous use only
Minimizes the possibility of clerical error or
bacteria contamination

Boldt J, et al. J Cardiothorac Vasc Anesth.
1991523-28.
Johnson RG, et al. J Cardiothorac Vasc Surg.
1992104307-314.
Kramer AH, et al. Surg Gynecol Obstet.
1979149831-836.
Martin E, Ott E. Bibl Haematol. 198147322-337.
Hur SR, et al. Spine. 199217867-873.
Ness PM, et al. Transfusion. 199232226-230.
Laks J, et al. Ann Surg. 1974180103-109.

67
Acute Normovolemic Hemodilution Cost and Other
Considerations
Cost savings

ANH is equivalent to PAD but without wastage or
inventory and testing cost
Reduction in total transfusion costs (100/unit
with ANH compared with 269 with PAD)
Time consuming
Requires additional equipment/knowledge
Some studies suggest that significant benefit
(including economic) only for revision hip
surgery and radical prostatectomy

Underutilized?
68
Other Intraoperative Strategies

Hypervolemic hemodilution
No blood is withdrawn
Blood volume is expanded aggressively
Decreased number of RBCs lost during surgery
Postoperative diuresis and recovery
Regional anesthesia
Epidurals performed for orthopedic procedures
including hip and knee

69
Other Intraoperative Strategies (cont.)

Controlled hypotension
MAP 50-65 mm Hg
Do not use if the patient has CVS, CNS, renal,
or liver dysfunction
Controlled hypothermia
O2 consumption is decreased 6 for each C
Increased O2 solubility in the plasma via a left
shift of the oxyhemoglobin dissociation curve
Must maintain temperature gt33 C (arrhythmia,
coagulopathy)

70
Other Intraoperative Strategies (cont.)

Hemoglobin-based oxygen carriers
Can augment tissue oxygen delivery and may
decrease RBC transfusions
Variety of products each has its own limitations
and advantages
Currently under experimental and clinical
investigation
Perfluorocarbon emulsions
Possess a unique ability for enhanced gas
solubility
Shown to improve hepatocellular injury after
hemorrhagic hypotension compared with use of
blood, colloid, or combination of blood and
colloid

Hare GMT, Mazer CD. Hemoglobin-based oxygen
carriers. In Spiess BD, Spence RK, Shander A,
eds. Perioperative Transfusion Medicine. 2nd ed.
Philadelphia Lippincott Williams Wilkins
2006chap 19.Spahn DR, et al. Anesthesiology.
2002971338-1349.
71
Hemostatic Surgical Instruments

Electrocautery (thermal cautery)
An electric current is used to heat a treatment
instrument or probe
The heated probe cauterizes capillary vessels and
small arteries, minimizing blood loss
Lasers
Laser energy is used to cut, vaporize, and
simultaneously coagulate a targeted area without
disrupting adjacent tissue
Cutting is achieved hemostatically, making
systems suitable for endoscopic and open-surgical
procedures
Promote clotting by localizing heat in bleeding
vessels, resulting in coagulation

72
Hemostatic Surgical Instruments (cont.)

Microwave scalpel
Concentrates a localized high-power microwave
field around the leading edge of a scalpel blade
Since microwave energy is absorbed in tissue, can
provide in-depth coagulation during surgery on
vascular organs such as the spleen and liver
Argon-beam coagulator
Uses a beam of ionized argon gas (argon plasma)
to conduct a high-frequency electric current to
bleeding tissues with limited tissue contact
Can be used for hemostasis of surface, diffuse
bleeding from parenchymatous tissues (eg, of the
liver, spleen)

73
Postoperative Strategies

Minimize phlebotomy
Cell salvage
Treatment with erythropoietin and iron
Decrease CMRO2
Sedation, analgesia
Positive pressure ventilation, muscle relaxation
Controlled hypothermia

74
Question-and-Answer Session
75
Blood Transfusion
76

Blood Transfusion

Patient blood management has been lost in
transfusion Axel Hofmann, Economist
77
Potential Candidates for Transfusion

Patients undergoing
Cardiopulmonary bypass or cardiac surgery
Urgent or emergent procedures
Obstetric procedures
Organ transplantation
Major noncardiac surgery
Patients with pre-existing blood disorders or
acquired deficiency secondary to massive bleeding
Critically ill patients

American Society of Anesthesiologists Task Force
on Perioperative Blood Transfusion and Adjuvant
Therapies. Anesthesiology. 2006105198-208.
78
Transfusion Risks/Complications

Transfusion-related immunomodulation (TRIM)
Systemic inflammatory response syndrome (SIRS)
Transfusion-related acute lung injury (TRALI)
Viral and bacterial transmission
Increased nosocomial infection
Increased mortality
Administrative errors
Acute transfusion reactions
Stored donor blood The Cold Storage Lesion
Free hemoglobin

79
Serious Hazards of Transfusion (SHOT), 2005
DTR (28) 4.6
TRALI (23) 3.8
TTI (3) 0.5
PTP (2)0.3
ATR (68) 11.2
IBCT (485) 79.6
N609
ATR acute transfusion reaction DTR delayed
transfusion reaction IBCT incorrect blood
component transfused PTP posttransfusion
purpura TRALI transfusion related acute lung
injury TTI transfusion transmitted
infection.Serious Hazards of Transfusion Annual
Report 2005. Available at http//www.shotuk.org/
SHOT20report202005.pdf. Accessed April 24, 2007.
80
Transfusion Errors

Mistransfusion estimated
114,000 RBC units in the US1
128,000 RBC units in the UK2
10 labeling error 11,000 samples
25 lab error
Remainder clinical setting
Fatality exceeds HIV-related transmission by 4-
to 8-fold

Williamson LM, et al. BMJ. 199931916-19.
Sazama K. Transfusion. 199030583-590.

81
Transfusion-related Acute Lung Injury (TRALI)

Incidence estimates vary1
Difficulty in ruling out left atrial hypertension
(eg, transfusion-associated circulatory overload
TACO, congestive heart failure) as cause
Characteristics of acute lung injury
indistinguishable from TRALI
Lack of agreement on case definition
Lack of awareness, underreporting/underdiagnosis
of TRALI
Leading cause of transfusion-related mortality1
(1200,000 cases2)
Proposed mechanisms
Passively transfused donor HLA class I/II or
neutrophil antigens3
Mixture of predisposition and infusion of
blood-related lipid-derived mediators4,5

Kleinman S. Transfusion. 2006461465-1468.
Holness L. Available at http//www.fda.gov/ohrms/
dockets/ac/04/transcripts/2004-4057t1.htm.
Accessed May 22, 2007.
Popovsky MA, Moore SB. Transfusion.
198525573-577.
Silliman CC, et al. Vox Sang. 199263133-136.
Silliman CC, et al. Transfusion. 199737719-726.

82
Blood Components Associated With TRALI

Significant reported
Whole blood
RBC
FFP
Apheresis platelets
Whole-bloodderived platelet

Isolated
WBC
IVIG
Cryoprecipitate
Stem cells

FFP fresh frozen plasma IVIG IV immune
globulin RBC red blood cells WBC white
blood cells.
Shander A, Popvsky MA. Chest. 2005128598-604.
83
Potential and Current Infectious Risks to the
Blood Supply

Simian foamy virus (SFV)
HHV-8
West Nile virus
Chagas
nCJD
Malaria
SARS
Influenza

84
Bacterial Infections

Risk of bacterial sepsis in red cells and
platelet 13000 units transfused
Sepsis develops in 125,000 units of platelets
and 1250,000 units of RBCs transfused
Bacterial detection performed early will miss
late infection (platelets)
Pathogen inactivation, is that the answer?

Blajchman MA, et. al. Transfus Med Rev.
200519259-272.
85
Decline in Risks of Transfusion-Transmitted HIV,
HBV, HCV, and Bacterial Infections
1983 1985 1987 1990 1996 1999 2003 2004 Revised
HIV Non-A, non-B HCV p24 HCV and HIV West
Nile Bacterial donor antibody hepatitis antibody
antigen nucleic acid virus nucleic screening def
erral screening surrogate screening testing testin
g acid testing of platelets criteria testing
Adapted with permission from Blajchman MA,
Vamvakas EC. N Engl J Med. 20063551303-1305 and
Busch MP, et al. JAMA. 2003289959-962.
86
Acute Transfusion Reactions

Anaphylaxis
110,00011500-3000 transfusions (platelets)
IgA-mediated, IgA-deficient recipient
Fatal up to 5
Transfusion-associated circulatory
overload(TACO) 13000 for all products
Other immune- and antibody-mediated reactions

87
Donor Leukocytes

Persistence of donor WBCs in trauma patients for
up to 1.5 years after an allogeneic blood
transfusion
2 x 109 WBCs in one unit of packed red blood
cells
1 x 108 WBCs centrifuged, buffy-coat depleted
1-5 x 106 WBCs leukocyte filter,
leukocyte-depleted

Lee TH, et al. Blood. 1999933127-3139.
88
The Cold Storage Lesion
Offner PJ, et al. Arch Surg. 2002137711-717.Bro
wn M, Whalen PK. Crit Care Nurse.
200020(suppl)1-14. Zallen G, et al. Shock.
20001329-33.
89
Age of Blood
90
Transfusion-related Immunomodulation (TRIM)

Allogeneic blood transfusion
Infuses recipient with potentially
immunomodulatory substances foreign cells,
cell-associated soluble antigens, biological
response modifiers
Human studies (controversial and hotly debated)
suggest ABT (vs no transfusion/autologous
transfusion)
Positive effects ? renal allograft survival ?
risk of recurrent abortion ? recurrence of
Crohns disease
Negative effects ? recurrence rate of resected
malignancies ? post-op bacterial infections ?
mortality
TRIM effect thought to be due to leukocytes
Animal data
Strong signal in human data

Outcome Measures
Transfusion, Immune Modulation Infection, and
Death

92
Effect of Blood Transfusion on Long-term Survival
After Cardiac Surgery
1.00
No XFN n546
0.95
Survival
0.90
XFN n546
0.85
0
48
60
36
12
24
Months after CABG
Kaplan-Meier estimates of survival based on equal
propensity scores of any transfusion (XFN) versus
no transfusion (No XFN).
CABG coronary artery bypass grafting.
Figure reproduced with permission from Engoren
MC, et al. Ann Thorac Surg. 2002741180-1186.
93
Nosocomial Infections in the ICU
Overall
18
Plt.005
Transfused patients
Nontransfused patients
15.4
16
12
Percentage of Patients
8
5.9
2.9
4
0
N1717
n416
n1301
Reproduced with permission from Taylor RW, et al.
Crit Care Med. 2002302249-2254.
94
Nosocomial Infections in the ICU
Overall
18
Plt.0001
Transfused patients
Nontransfused patients
16
14.3
N2085
12
Percentage of Patients
7.5
8
5.8
4
0
157/2085
61/428
96/1557
Reproduced with permission from Taylor RW, et al.
Crit Care Med. 2006342302-2308.
95
Transfusions Correlate With Infections in a
Dose-Dependent Manner
1.2
0-15 Units of PRBC
1.0
Y 0.1375e0.1187x R2 0.7566
0.8
Incidence of Infection
0.6
0.4
0.2
0.0
0
2
4
6
8
10
12
14
16
Transfusions
Reproduced with permission from Claridge JA, et
al. Am Surg. 200268566-572.
96
Association Between Allogeneic Blood Transfusion
and Mortality
Odds ratio 60-90 d mortality in OHS studies (all
European)2-4
0.1
1
10
100

Meta-analysis, RCTs WBC-containing transfusions
and mortality1
No association detected across clinical settings
Association may exist in open heart surgery
(OHS)2-4

van de Watering et al
Bilgin et al
Wallis et al
Summary OR
Figure adapted with permission from Vamvakas EC.1

Vamvakas EC. Transfusion. 200343963-973.
Van de Watering LM, et al. Circulation.
199897562-568.
Bilgin YM, et al. Circulation. 20041092755-2760.
Wallis JP, et al. Transfusion. 2002421127-1134.

97
Quality and Outcomes

Evidence is compelling that blood transfusion is
associated with the risk of significant
morbidity, including
Bacterial contamination1
Transfusion-related acute lung injury (TRALI) and
other immunologic reactions2
Immunomodulatory effects (eg, TRIM)3
Circulatory effects (eg, TACO)4
Transfusion also is associated with increased
short- and long-term mortality rates5

Blajchman MA, et al. Transfus Med Rev.
200519259-272.
Kleinman S. Transfusion. 2006461465-1468.
Blajchman MA. Hematology. 200510(suppl
1)208-214.
Langenfeld JE, et al. Surgery. 1994116859-867.
Spiess BD, et al. Transfusion. 2004441143-1148.

Preoperative Autologous Donation

99
Preoperative Autologous Donation

Considered the standard of care for large-joint
orthopedic surgery
Expensive high cost of procurement, processing,
wastage, and discarding
Only 1 of every 2 donated units transfused
PAD blood is banked and carries same risk of
clerical error or misidentification as all banked
blood
Units of PAD blood have same functional
impairments as other cold-stored blood
PAD blood may not help patients avoid exposure to
allogeneic blood
50 of patients who undergo PAD arrive anemic the
day of surgery and require reinfusion of
autologous blood as well as allogeneic
transfusion to tolerate surgery

Etchason J, et al. N Engl J Med.
1995332719-724. Cohen JA, et al. Transfusion.
199535640-644.
100
Preoperative Autologous Donation
Contraindications

Relative Contraindications
Previous infarction
Cerebrovascular insufficiency
Hepatic failure
Anticoagulant treatment in progress (with
inhibitors of vitamin K)
Absolute Contraindications
High fever
Documented or probable bacteremia
Uncorrected hypovolemia
Acute hepatic failure
Cardiopathies (arrhythmias, angina, low
cardiogenic output)
Generally poor condition

101
Blood Product Transfusions

The Traditional Concept
Blood products are an effective therapeutic
intervention
The New Concept
Transfusion of blood products is an undesirable
outcome

L.T. Goodnough, MD
Red-cellcontaining components should not be
used to treat anemias that can be corrected with
specific medications such as iron, vitamin B12,
folic acid, or erythropoietin. Circular of
Information for the Use of Human Blood and
Components. Bethesda, Md American Association of
Blood Banks, Americas Blood Centers, and
American Red Cross 200212.
102
Transfusion Practice Evidence Based or
Behavior Based?

Amount of transfused products was found to be
inversely proportional to the physicians
knowledge of transfusion indications1
Variability in transfusion practice exists for
coronary artery bypass surgery2,3
Variability persists despite national consensus
guidelines3
Institutional variability in transfusion practice
also exists for liver transplantation4

Salem-Schatz SR, et al. Med Care.
199331868-878.
Goodnough LT, et al. JAMA. 199126586-90.
Stover EP, et al. Anesthesiology.
199888327-333.
Ozier Y, et al. Anesth Analg. 200397671-679.

103
What really happens in your institution?Discuss
ion
104
Transfusion Guidelines

Because of the risks associated with
transfusion, physicians should remain familiar
with currently recognized alternatives to
transfusion. Autologous transfusion techniques
(such as perioperative collection and
preoperative donation) should be considered, when
indicated, to reduce the need for allogeneic
transfusion with its attendant risks of disease
transmission and immune reaction

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