This document discusses blood products and plasma substitutes. It provides information on the components of blood, including plasma, red blood cells, white blood cells and platelets. It describes various blood products like whole blood, red blood cell concentrates, platelet concentrates, fresh frozen plasma and cryoprecipitate. Their preparation, storage, shelf life, indications and administration are outlined. Dried human plasma is also discussed as a plasma substitute with advantages over whole blood. Potential problems in preparation of dried plasma like transmission of viral jaundice and neutralization of plasma agglutinins are addressed.
Blood products:Collection, Processing and Storage of whole human blood, dried...Steffi Thomas
blood and its components, conditions for being a donor, anti-coagulants, whole human blood, changes in composition during storage, red blood cells, concentrated platelets, plasma, dried human plasma, fresh frozen plasma, dried human serum, plasma substitutes, ideal properties of plasma substitute, dextran, gum saline, polyvinylpyrrolidone
Biopharmaceutics: Mechanisms of Drug AbsorptionSURYAKANTVERMA2
Biopharmaceutics is defined as the study of factors influencing the rate and amount of drug that reaches the systemic circulation and the use of this information to optimise the therapeutic efficacy of the drug products.
Blood products:Collection, Processing and Storage of whole human blood, dried...Steffi Thomas
blood and its components, conditions for being a donor, anti-coagulants, whole human blood, changes in composition during storage, red blood cells, concentrated platelets, plasma, dried human plasma, fresh frozen plasma, dried human serum, plasma substitutes, ideal properties of plasma substitute, dextran, gum saline, polyvinylpyrrolidone
Biopharmaceutics: Mechanisms of Drug AbsorptionSURYAKANTVERMA2
Biopharmaceutics is defined as the study of factors influencing the rate and amount of drug that reaches the systemic circulation and the use of this information to optimise the therapeutic efficacy of the drug products.
The phenomenon of complex formation of drug with protein is called as Protein drug binding. The proteins are particularly responsible for such an interaction. A drug can interact with several tissue components.
Methods of enhancing Dissolution and bioavailability of poorly soluble drugsRam Kanth
Greetings!
Good Day to all...
Topic: Methods of Enhancing Bioavailability
Several approaches discussed are
1. Micrnoization
2. Use of Surrfactants
3. Use of Salt forms
4. Alteration of pH of microenvironment
5. Use of metastable polymorphs
6. Solute-Solvent Complexation
7. Solvent Deposition
8. Selective Adsorption on Insoluble Carriers
9. Solid Solutions
10. Eutectic Mixtures
11. Solid Dispersions
12. Molecular Encapsulation with Cyclodextrins
Please do clarify for doubts if any....
Thank you all for watching this presentation.
Immunosuppressants are drugs or medicines that lower the body's ability to reject a transplanted organ. Another term for these drugs is anti-rejection drugs. There are 2 types of immunosuppressants:
Induction drugs: Powerful antirejection medicine used at the time of transplant
Maintenance drugs: Antirejection medications used for the long term.
It contains indications of blood and blood products and perioperative blood therapy that we usually follow in Aiims Patna ..its is most recent one made in April 2020
The phenomenon of complex formation of drug with protein is called as Protein drug binding. The proteins are particularly responsible for such an interaction. A drug can interact with several tissue components.
Methods of enhancing Dissolution and bioavailability of poorly soluble drugsRam Kanth
Greetings!
Good Day to all...
Topic: Methods of Enhancing Bioavailability
Several approaches discussed are
1. Micrnoization
2. Use of Surrfactants
3. Use of Salt forms
4. Alteration of pH of microenvironment
5. Use of metastable polymorphs
6. Solute-Solvent Complexation
7. Solvent Deposition
8. Selective Adsorption on Insoluble Carriers
9. Solid Solutions
10. Eutectic Mixtures
11. Solid Dispersions
12. Molecular Encapsulation with Cyclodextrins
Please do clarify for doubts if any....
Thank you all for watching this presentation.
Immunosuppressants are drugs or medicines that lower the body's ability to reject a transplanted organ. Another term for these drugs is anti-rejection drugs. There are 2 types of immunosuppressants:
Induction drugs: Powerful antirejection medicine used at the time of transplant
Maintenance drugs: Antirejection medications used for the long term.
It contains indications of blood and blood products and perioperative blood therapy that we usually follow in Aiims Patna ..its is most recent one made in April 2020
Surgery resident postgraduate presentation on the use of blood and products presented dept of surgery, Niger Delta University Teaching Hospital, Okolobiri, Bayelsa State, Nigeria
Welcome to Secret Tantric, London’s finest VIP Massage agency. Since we first opened our doors, we have provided the ultimate erotic massage experience to innumerable clients, each one searching for the very best sensual massage in London. We come by this reputation honestly with a dynamic team of the city’s most beautiful masseuses.
ASSISTING WITH THE USE OF URINAL BY ANUSHRI SRIVASTAVA.pptxAnushriSrivastav
Male patients confined to bed usually prefer to use the urinal for voiding.
The use of a urinal in the standing position facilitates emptying of the bladder
If the patient is unable to stand, the urinal may be used in bed. Patients may also use a urinal in the bathroom to facilitate measurement of urinary output.
Provide skin care and perineal hygiene after urinal use and maintain a professional manner
EQUIPMENT
Urinal with end cover (usually attached)
Toilet tissue
Clean gloves
Additional PPE, as indicated
ASSESSMENT
Assess the patient’s normal elimination habits.
Determine why the patient needs to use a urinal, such as a physician’s order for strict bed rest or immobilization.
Assess the patient’s degree of limitation and ability to help with activity
Assess for activity limitations, such as hip surgery or spinal injury, which would contraindicate certain actions by the patient.
Check for the presence of drains, dressings, intravenous fluid infusion sites/equipment, traction, or any other devices that could interfere with the patient’s ability to help with the procedure or that could become dislodged.
Assess the characteristics of the urine and the patient’s skin.
Document the patient’s tolerance of the activity. Record the amount of urine voided on the intake and output record, if appropriate. Document any other assessments, such as unusual urine characteristics or alterations in the patient’s skin.
SPECIAL CONSIDERATION
Urinal should not be left in place for extended periods because pressure and irritation to the patient’s skin can result. If patient is unable to use alone or with assistance, consider other interventions, such as commode or external condom catheter.
It may be necessary to assist patients who have difficulty holding the urinal in place, such as those with limited upper extremity movement or alteration in mentation, to prevent spillage of urine.
The urinal may also be used standing or sitting at the bedside or in the patient’s bathroom, if patient is able to do so.
Unlocking the Benefits of Cognitive Behavioural Therapy (CBT) with Renewed Edgerenewed edge
Discover the transformative potential of Cognitive Behavioural Therapy (CBT) with Renewed Edge. This presentation covers the core principles of CBT, its development, practical applications, benefits, and how to get started with this evidence-based approach to improving mental well-being.
Damage to the spinal cord above the sacral region causes reflex incontinence. This condition causes loss of voluntary control of urination; but the micturition reflex pathway often remains intact, allowing urination to occur without sensation of the need to void
Overflow incontinence occurs when a bladder is overly full and bladder pressure exceeds sphincter pressure, resulting in involuntary leakage of urine. Causes often include head injury; spinal injury; multiple sclerosis; diabetes; trauma to the urinary system; and postanesthesia sedatives/hypnotics, tricyclics, and analgesia
Hyperreflexia, a life-threatening problem affecting heart rate and blood pressure, is caused by an overly full bladder. It is usually neurogenic in nature; however, it can be caused functionally by blockage
Diseases that cause irreversible damage to kidney tissue result in end-stage renal disease (ESRD).
uremic syndrome- An increase in nitrogenous wastes in the blood, marked fluid and electrolyte abnormalities, nausea, vomiting, headache, coma, and convulsions characterize this syndrome. As the uremic symptoms worsen, aggressive treatment is indicated for survival
Nocturia - awakening to void one or more times at night
An excessive output of urine is polyuria.
. A urine output that is decreased despite normal intake is called oliguria.
increased urine formation (diuresis)
a stoma (artificial opening)
Urinary Retention. Urinary retention is an accumulation of urine resulting from an inability of the bladder to empty properly.
URINE OVERFLOW- The sphincter temporarily opens to allow a small volume of urine (25 to 60 mL) to escape. With retention a patient may void small amounts of urine 2 or 3 times an hour with no real relief of discomfort or may continually dribble urine.
pain or burning during urination (dysuria) as urine flows over inflamed tissues
blood-tinged urine (hematuria)
Urinary incontinence is the involuntary leakage of urine that is sufficient to be a problem. It can be either temporary or permanent, continuous or intermittentUrinary elimination depends on the function of the kidneys, ureters, bladder, and urethra. Kidneys remove wastes from the blood to form urine. Ureters transport urine from the kidneys to the bladder. The bladder holds urine until the urge to urinate develops. Urine leaves the body through the urethra. All organs of the urinary system must be intact and functional for successful removal of urinary wastes. Intact efferent and afferent nerves from the bladder to the spinal cord and brain must be present
INTAKE AND OUTPUT OF URINE
Assess the patient’s average daily fluid intake.
at home, ask him or her to estimate his or her intake by showing a measurement on a commonly used glass or cup
Special receptacles (urimeters) that attach between indwelling catheters and drainage bags are a convenient means of accurately measuring urine volume. A urimeter holds 100 to 200 mL of urine. After measuring urine from a urimeter, drain the cylinder
R3 Stem Cells and Kidney Repair A New Horizon in Nephrology.pptxR3 Stem Cell
R3 Stem Cells and Kidney Repair: A New Horizon in Nephrology" explores groundbreaking advancements in the use of R3 stem cells for kidney disease treatment. This insightful piece delves into the potential of these cells to regenerate damaged kidney tissue, offering new hope for patients and reshaping the future of nephrology.
CRISPR-Cas9, a revolutionary gene-editing tool, holds immense potential to reshape medicine, agriculture, and our understanding of life. But like any powerful tool, it comes with ethical considerations.
Unveiling CRISPR: This naturally occurring bacterial defense system (crRNA & Cas9 protein) fights viruses. Scientists repurposed it for precise gene editing (correction, deletion, insertion) by targeting specific DNA sequences.
The Promise: CRISPR offers exciting possibilities:
Gene Therapy: Correcting genetic diseases like cystic fibrosis.
Agriculture: Engineering crops resistant to pests and harsh environments.
Research: Studying gene function to unlock new knowledge.
The Peril: Ethical concerns demand attention:
Off-target Effects: Unintended DNA edits can have unforeseen consequences.
Eugenics: Misusing CRISPR for designer babies raises social and ethical questions.
Equity: High costs could limit access to this potentially life-saving technology.
The Path Forward: Responsible development is crucial:
International Collaboration: Clear guidelines are needed for research and human trials.
Public Education: Open discussions ensure informed decisions about CRISPR.
Prioritize Safety and Ethics: Safety and ethical principles must be paramount.
CRISPR offers a powerful tool for a better future, but responsible development and addressing ethical concerns are essential. By prioritizing safety, fostering open dialogue, and ensuring equitable access, we can harness CRISPR's power for the benefit of all. (2998 characters)
Leading the Way in Nephrology: Dr. David Greene's Work with Stem Cells for Ki...Dr. David Greene Arizona
As we watch Dr. Greene's continued efforts and research in Arizona, it's clear that stem cell therapy holds a promising key to unlocking new doors in the treatment of kidney disease. With each study and trial, we step closer to a world where kidney disease is no longer a life sentence but a treatable condition, thanks to pioneers like Dr. David Greene.
Antibiotic Stewardship by Anushri Srivastava.pptxAnushriSrivastav
Stewardship is the act of taking good care of something.
Antimicrobial stewardship is a coordinated program that promotes the appropriate use of antimicrobials (including antibiotics), improves patient outcomes, reduces microbial resistance, and decreases the spread of infections caused by multidrug-resistant organisms.
WHO launched the Global Antimicrobial Resistance and Use Surveillance System (GLASS) in 2015 to fill knowledge gaps and inform strategies at all levels.
ACCORDING TO apic.org,
Antimicrobial stewardship is a coordinated program that promotes the appropriate use of antimicrobials (including antibiotics), improves patient outcomes, reduces microbial resistance, and decreases the spread of infections caused by multidrug-resistant organisms.
ACCORDING TO pewtrusts.org,
Antibiotic stewardship refers to efforts in doctors’ offices, hospitals, long term care facilities, and other health care settings to ensure that antibiotics are used only when necessary and appropriate
According to WHO,
Antimicrobial stewardship is a systematic approach to educate and support health care professionals to follow evidence-based guidelines for prescribing and administering antimicrobials
In 1996, John McGowan and Dale Gerding first applied the term antimicrobial stewardship, where they suggested a causal association between antimicrobial agent use and resistance. They also focused on the urgency of large-scale controlled trials of antimicrobial-use regulation employing sophisticated epidemiologic methods, molecular typing, and precise resistance mechanism analysis.
Antimicrobial Stewardship(AMS) refers to the optimal selection, dosing, and duration of antimicrobial treatment resulting in the best clinical outcome with minimal side effects to the patients and minimal impact on subsequent resistance.
According to the 2019 report, in the US, more than 2.8 million antibiotic-resistant infections occur each year, and more than 35000 people die. In addition to this, it also mentioned that 223,900 cases of Clostridoides difficile occurred in 2017, of which 12800 people died. The report did not include viruses or parasites
VISION
Being proactive
Supporting optimal animal and human health
Exploring ways to reduce overall use of antimicrobials
Using the drugs that prevent and treat disease by killing microscopic organisms in a responsible way
GOAL
to prevent the generation and spread of antimicrobial resistance (AMR). Doing so will preserve the effectiveness of these drugs in animals and humans for years to come.
being to preserve human and animal health and the effectiveness of antimicrobial medications.
to implement a multidisciplinary approach in assembling a stewardship team to include an infectious disease physician, a clinical pharmacist with infectious diseases training, infection preventionist, and a close collaboration with the staff in the clinical microbiology laboratory
to prevent antimicrobial overuse, misuse and abuse.
to minimize the developme
2. BLOOD
• Main transport system in the body.
• Blood carries raw materials and finished products from where they
originate to where they are used and transports waste products to
disposal sites.
• Accounts for about 7% of the body weight of a normal adult.
• Blood is composed of plasma and cells suspended in plasma (RBC,
WBC, PLATELETS)
• Plasma is largely made up of water in which many constituents are
dissolved. These constituents include
PROTEINS:
• ALBUMIN: The most common protein in blood.
• Blood clotting proteins made by the liver.
VINESHA
3. PLASAMA
• 55% of blood.
• Liquid part of the
blood.
• Plasma transports:
o Soluble food
molecules.
o Waste products.
o Hormoes.
o Antibodies.
VINESHA
5. WHITE BLOOD CELLS
(WBCs)
• The body’s defence.
• Part of the immune
system.
• Larger than RBCs.
• Have nucleus.
• 4000-13000 per mm2.
• Two types:
o Phagocytes.
o Lymphocytes.
VINESHA
6. • ERYTHROPOIETIN: A protein made by the kidneys that
stimulates red cell production.
• IMMUNOGLOBULINS: Antibodies made by plasma
proteins in response to infections.
HORMONES
Such as thyroid hormone and cortisol.
MINERALS
Such as iron and magnesium.
VITAMINS
Such as folic acid and B12.
ELECTROLYTES
Such as calcium, potassium and sodium.
VINESHA
7. BLOOD PRODUCTS:
Therapeutic substance prepared from human blood.
WHOLE BLOOD:
Unseparated blood collected into an approved container containing an
anticoagulant preservative solution.
BLOOD COMPONENT:
• A constituent of blood, separated from whole blood such as
o Red blood concentrate.
o Red blood suspension.
o Plasma.
o Platelet concentrates.
o Plasma or platelets collected by apheresis.
o Cryoprecipitate, prepared from fresh frozen plasma: rich in factor VIII and fibrinogen.
PLASMA DERIVATIVES:
• Human plasma proteins prepared under pharmaceutical manufacturing conditions
such as,
o Albumin.
o Coagulation factor concentrates.
o Immunoglobulins.
VINESHA
8. INDICATIONS
VINESHA
• Anemia.
• Major surgical operations.
• Accidents resulting in considerable blood loss.
• Cancer patients requiring therapy.
• Women in childbirth and new born babies in certain
cases.
• Patients of hereditary disorders like Haemphilia and
Thalassaemia.
• Severe burn victims.
9. CONDITIONS FOR BEING A DONOR
A person in good health is accepted as a donor provided that
he or she is;
• Not suffering from any diseases that can be transmitted by
transfusion. This includes syphilis, malaria, and serum
jaundice.
• Not anaemic. The haemoglobin content of blood should not
be less than 12.5% for females and 13.3% for males.
• Not taking medications which might prove toxic or have
allergic reactions in a patient e.g. antibiotics.
VINESHA
11. CITRATES
VINESHA
The solution most often used as a blood anticoagulant is
known as Acid-citrate dextrose (ACD)
• Sodium citrate (2.0 – 2.5 g)
• Dextrose (3.0 g)
• Water for injection (q.s. upto 120ml)
The citrate prevents clotting by binding the calcium ions as
unionized calcium citrate, thus preventing a vial step of
clotting.
12. Why acid citrate and not normal citrate?
The normal trisodium citrate has a very high alkaline pH in solution
which causes considerable caramelisation of dextrose ( darkening)
during sterilization and the two solutions have to be autoclaved
separately.
The acid citrate produces a pH of about 5 and causes little or no
caramelisation.
The higher concentration (2.5g/120ml) is often preferred because it more
efficiently reduces the formation of small clots.
Why add dextrose?
The dextrose delays the hemolysis of the erythrocytes in vitro and
prolongs their life after transfusion.
Its function is hypothesized to be connected with the synthesis of
compounds such as ATP, that are important in making energy available to
living cells.
VINESHA
13. HEPARIN
• Naturally occurring anticoagulant.
• Made by the mast cells of the connective tissue surrounded
blood vessels.
• It inhibits clotting in the circulatory system.
• Occasionally, it is used in blood for transfusion when large
volumes must be given to one patient and the corresponding
amounts of citrate would be harmful e.g. in cardiac surgery
• It quickly less activity in blood in vitro and normal
quantities are effective for about a day.
• ACD on the other hand, prolongs the storage life to three
weeks.
• Heparin is expensive and may continue its action even after
transfusion, thus needing administration of neutralizing
substances such as protamine sulphate.
VINESHA
14. DISODIUM EDETATE
• This is also a chelating agent like ACD.
• It has a strong affinity for divalent metals, and thus will bind
to calcium firmly.
• It is sometimes preferred when preservation of blood
platelets is essential.
• ACD is almost as effective as disodium edetate.
• The survival of red blood cells in dextrose edetate is as good
as in ACD.
VINESHA
16. WHOLE HUMAN BLOOD
• DEFINITION: One unit whole blood contains 450ml of donor
blood plus anticoagulants.
• VOLUME: 450ml.
• STORAGE: between 2-6°C in approved blood bank refrigerator.
Transfusion should be started within 30 minutes of removal from
refrigerator.
• SHELF LIFE: 21 days.
• INDICATIONS:
o Red cell replacement in acute blood loss with hypovolemia.
o Exchange transfusion.
• CONTRAINDICATIONS: risk of volume overload in patients with
• Chronic anaemia.
• Incipient cardiac failure.
VINESHA
17. CHANGES IN COMPOSITION OCCUR
DURING STORAGE
• Significant detoriation of clotting factors.
• Total loss of functioning granulocyte and platelets.
• Concentration of hydrogen and potassium ions in plasma
increases during storage.
• Thus the infusion of large amount of stored whole blood
results in infusion of undesirable constituent.
VINESHA
18. • Blood is collected aseptically from the median cubital
vein in the front elbow
• This blood is put into a sterile container containing an anticoagulant
solution and the bottle is gently shaken to ensure that blood and
anticoagulant are well mixed, thus preventing the formation of small
fibrin clots
• A maximum of 450ml of blood is taken in one
attendance
• Immediately afterwards the container is sealed and
cooled to 2-6°C for storage
VINESHA
19. TESTING OF WHOLE BLOOD
• At the time that blood is collected, two small additional amounts
are collected:
• One, which is often obtained by draining the collecting tube, is
put into a small 5ml bottle and is firmly attached to the main
container. This is for testing compatibility with the blood of the
recipient.
• The second, somewhat larger sample is used as soon as possible
for:
o Serological test to confirm the absece of syphilis and other diseases
o To determine the ABO blood group of the cells and plasma and the Rh
grouping of the cells.
VINESHA
20. RED BLOOD CELLS
• Red blood cells contain haemoglobin and serve as the primary
agent for transport of oxygen to tissues.
PREPARATION : It is prepared by removing most of the citrated
plasma from whole blood by centrifugation or sedimentation.
DESCRIPTION: 150-200ml red cells from which most of the
plasma has been removed.
INFECTION RISK: Same as whole blood.
INDICATIONS: Relacement of red cells in anaemic
patientsd(chronic anaemia).
DESCRIPTION- Generally available in two types:
• RCC without additive solution.
• RCC with additive solution.
VINESHA
22. ADVANTAGE OF TRANSFUSING RBC OVER WHOLE
BLOOD:
• RBC increases oxygen carrying capacity without increasing
blood volume. This is useful in chronic anemia and CHF.
• Removal of plasma decreases plasna protein thus decreases
the chances of allergic or anaphylatic reactions.
ADVANTAGES OF USING RBC WITH ADDITIVE
SOLUTIONS:
• Reduces the viscosity of blood, hence making the
transfusion easy.
• Shelf life of RCC increases from 35 days to 42 days.
• Post transfusion viability of red cells increases.
VINESHA
23. PLATELET COMPONENTS
Platelet therapy may be achieved by infusion of either
• APHERESIS PLATELETS
• PLATELETS (whole blood- derived platelet concentrates).
In either component, platelets are suspended in an appropriate volume of original
plasma, which contains near normal levels of stable coagulation factors that are stored
at room temperature.
STORAGE: Between 20-24°C.
SHELF LIFE: 5 days.
INDICATIONS: The therapeutic goal of platelet transfusion is to provide adequate
numbers of normally functioning platelets for the prevention or cessation of bleeding.
Treatment of bleeding due to :
• Thrombocytopenia.
• Platelet function defects.
DOSAGE AND ADMINISTRATION: One unit of platelets would be expected to
increase the platelet count of a 70kg adult by 5,000 to 10,000/µl. The therpeutic adult
dose is 1 unit of apheresis platelets or 4 to 6 units of whole blood derived platelets.
VINESHA
24. PLASMA COMPONENTS
• Plasma is the aqueous part of blood and can be derived from the
separation of a whole blood collection or by apheresis collection.
• Important elements in plasma include albumin, coagulation
factors, fibrinolytic proteins, immunoglobulin, and other
proteins.
• Fresh frozen plasma (FFP).
• Cryoprecipitate.
• Dried human plasma.
VINESHA
25. FRESH FROZEN PLASMA (FFP)
DEFINITION:
FFP is plasma separated by normal whole blood donation by single
donor and rapidly frozen within 6 hours of being collected. It
contains all coagulation factors.
VOLUME: 200ml – 220ml (1 unit).
STORAGE: at -30°C or colder.
SHELF LIFE: 1 year.
NOTE: before use, FFP should be thawed in blood bank in
thawing bath between 30°C to 37°C. FFP should be administered
as soon as possible after thawing.
VINESHA
26. FRESH FROZEN PLASMA (FFP)
INDICATIONS:
Used in patients with multiple coagulation factor deficiencies
• Liver diseases.
• Warfarin ( anticoagulant) overdose.
DOSAGE: Initial dose of 10 to 15 ml/kg.
ADMINISTRATION:
• Must be ABO compatible.
• No compatibility testing required.
• Infuse using standard blood transfusion set as soon as possible
after thawing.
VINESHA
27. CRYOPRECIPITATE:
DEFINITION:
Cryoprecipitate are precipitated proteins if plasma rich in factor
VIII and fibrinogen obtained from a single unit of fresh frozen
plasma.
VOLUME: 10ml to 20ml.
STORAGE: At -30°C or colder.
SHELF LIFE: 1 year.
NOTE: Before use, should be thawed in blood bank thawing bath
between 300 to 370°C. once thawed, cryoprecipitate should be
transfused immediately but in any case not later than 6 hours.
VINESHA
28. INDICATIONS:
As an alternative to factorVIII concentrate in the treatment of inherited
deficiencies of FACTOR VIII (haemophilia A).
DOSAGE:
2 units/10 kg wt. one bag contains more than 80 units of factor VIII and
more than 150mg of fibrinogen.
Each unit of factor VIII per kg raises plasma factor VIII by 2%.
ADMINISTRATION:
No compatibility testing is required.
After thawing, infuse as soon as possible through a standard blood
transfusion set.
Must be transfused immediately or within 4 hours of thawing.
VINESHA
29. DRIED HUMAN PLASMADISADVANTAGESOF
WHOLEBLOOD
• It has poor keeping
properties
necessitating use
within three weeks
• It requires
refrigeration
• It must be compatible
with the blood of the
recipient
ADVANTAGESOF
DRIEDPLASMA
• Properly stored it
keeps well for at least
five years
• If protected from light
it can be stored at
room temperature
provided is below
20°C
• It can be given to
patients of any blood
group
Thus under suitable circumstances, DRIED PLASMA can be used
as a substitute for whole blood
VINESHA
30. PREPARATION
• Prepared from time expired citrated blood
• The blood is centrifuged and the supernatant fluid is siphoned off
• This siphoned fluid is then combined and batches less than 10 bottles
are pooled, choosing the correct ration of blood groups to neutralize
the powerful agglutinins
• The pools are kept at 4 to 6°C while samples arae tested for sterlity
and no pool is usedd unless it passes.
• Then 400ml quantities are dispensed into bottles and subjected to freeze drying
• General aspects of freeze drying are allowed with special features of the
plasma process
• Preliminary freezing
• Primary drying
• Secondary drying
31. PRELIMINARY FREEZING
• The bottles are sealed with bacteriologically efficient pads covers by
ring tape closures and then centrifuged at -18°C.
• The liquid snap freezes and becomes a distributed around the inside of
the bottle.
PRIMARY DRYING
• The bottles of frozen material are mounted horizontally in the drying
chamber and a high vacuum is applied.
• The ice sublimes on to a condensing coil kept at -50°C and a small
heater provides the latent heat required fro evaporation.
• This stage takes about 2 days, after which the residual moisture content
about 2%.
SECONDARY DRYING
• This is done in another chamber by vacuum desiccation over
phosphorous pentoxide.
• It takes about a day, and the product is left with about 0.5% of moisture.
VINESHA
32. PROBLEMS TO OVERCOME DURING PREPARATION
• Transmission of viral jaundice.
• Neutralization of plasma agglutinins.
TRANSMISSION OF VIRAL JAUNDICE
There are two types:
- Infective hepatitis.
- Homologous serum jaundice.
CONTROL: At present there is no reliable test by which carriers can be
detected.
• Attempts have been made to kill the causative viruses by treatment
with UV light, but the method is technically difficult.
• If the preparation of a bllod product involves pooling material from a
larger number of donors, infection in one or two bottles will be
distributed throughout the pool and appear in each of the units made
from it.
• Nowadays, the pool used for making dried plasma and serum are
limited to not more than ten donations, and the incidence of jaundice
is only slightly greater than when whole blood is transfused.
VINESHA
33. NEUTRALIZATION OF PLASMA
AGGLUTININS
• Agglutinins in the donors plasma usually do not damage the recipients
red cells.
• Occasionally, however, the plasma agglutinins are very powerful and
can cause serious hemolysis of the cells of the recipient.
• This means that incompatibility problems are not entirely eliminated
by using products such as plasma and serum, that contain no cells.
• The problem has been overcome since the discovery that red cells
agglutinogen also occur as water soluble forms in plasma, saliva and
other body fluids.
• Consequently, by mixing plasma from different groups in suitable
proportions the powerful agglutinins can be cross neutralized by
soluble agglutinogen, producing a preparation that is safe to transfuse
to all groups.
• Most satisfactory ratio for mixing is 9 of A : 9 of O : 2 B or AB.
VINESHA
34. STORAGE:
• Dried plasma, kept below 20°C and protected from light,
moisture, and oxygen, remains usable almost indefinitely.
• Arbitrary expiry date of about 5 years.
• Its fitness for use is shown by its solubility when reconstituted
in a volume of water for injection (WFI), sodium chloride
injection or a solution containing 2.5% dextrose and 0.45%
sodium chloride.
• It must dissolve completely within ten minutes at room
temperature.
• Gel formation or incomplete solution indicates deteoriation.
• After reconstitution it must be used immediately.
VINESHA
35. THE FRACTIONATION OF PLASMA
• About 60% of plasma protein in albumin and therfore, it plays a
major part in maintaining the high osmotic pressure necessary to
retain fluid in the blood vessels.
• A very successful solvent precipitation technique was developed by
which other proteins, as well as albumin, were separated.
• Some of these, i.e. fibrinogen, prothrombin, and gamma globulin,
proved so valuable that protein fractionation of plasma quickly
became an established procedure.
CONDITIONS FOR THE PROCESS OF FRACTIONATION ARE:
• The process selected must not alter the biological properties of the
fraction nor affect the solubility.
• It must be possible to carry it out aseptically and ideally, the
conditions should discourage bacterial growth.
• Any additive must be harmless or easily removed after use.
• It must.
VINESHA
36. TECHNIQUES OF PROTEIN SEPARATION
COHN’S TECHNIQUE – Developed by E.J.Cohn
• Based on the use of an organic solvent (ethyl alcohol) to reduced the
solubility of the proteins, and was given flexibility by alterations of
pH, ionic strength (i.e., salt concentrations) and protein.
• On the other hand, it is necessary to keep the temperature very low
(0-5°C) to prevent solvent denaturation of proteins.``
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37. HUMAN PLASMA PROTEIN FRACTION
• A solution of some of the proteins from liquid plasma.
• The protein content is not less than 4.3%w/v and the product
exerts a colloidal osmotic pressure approximately equivalent to
that of pooled liquid plasma containing 5.2%w/v of protein.
• It must be stored between 5 to 20°C and protected from light
• Its use remains the same as dried plasma.
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38. • A stabilizer such as sodium caprylate or acetylteyptophan is
added. This allows the preparation to be heated for several hours
at a low temperature without significant denaturation of
proteins.
• Sodium chloride is added to make the preparation
approximately isotonic.
• The solution is sterlized by filtration, aseptically distributed
into blood bottles and then heated at 60 +/- 0.5°C for 10hrs to
destroy the viruses of infective hepatitis and homologous serum
jaundice.
DRIED HUMAN PLASMA PROTEIN FRACTION
• Dried human plasma protein fraction is prepared by freeze
drying human plasma protein fraction.
• Its use is also the same as that of dried plasma.
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39. HUMAN FIBRINOGEN
• Fibrinogen is the soluble constituent of plasma which on addition of
thrombin is converted to fibrin (which is insoluble).
• After separation from plasma fractionation, the precipitation is
collected by centrifugation, dissolved in citrate-saline, and freeze
dried.
• The air in the containers displaced by nitrogen
• The citrate prevents spontaneous clotting when material is
reconstituted.
• The solution should be used as soon as possible and not later than 3
hours after preparation.
USE
• Occasionally fibrinogen is administered alone to treat fibrinogen
deficiency.
• But it is more often used in conjunction with thrombin.
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40. HUMAN THROMBIN
• Thrombin is an enzyme that converts fibrinogen to fibrin.
• The prothrombin obtained from the fractionation of plasma is
washed with distilled water and dissolved in citrate saline.
• It is converted to thrombin by adjustment pH to 7 and adding
thromboplastin and calcium ions.
• The solution is filtered and freeze dried, and the air in the
containers is replaced by nitrogen.
• It is reconstituted with saline when required.
• The fibrin clot produced when thrombin is mixed with fibrinogen
is used in surgery to suture severed nerves and to assist
adhesion of skin grafts.
• The clot also acts as a haemostat.
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41. HUMAN FIBRIN FOAM
• This is a sponge like mass of human fibrin.
• It is prepared by whipping a solution of fibrinogen into a froth by
mechanical means and then adding thrombin.
• The product is poured into trays and freeze dried, then cut into pieces of
convenient size and sterlized by dry heat at 130°C for 3hrs.
• The foam must be stored under dry conditions, protected from light and at a
temperature below 20°C. The other storage conditions are similar to that of
dried serum expect that fibrin foam not to be kept under fibrinogen.
USES OF HUMAN FIBRIN FOAM
• It is used with thrombin as a haemostat in surgery, when other methods used
to arrest bleeding have been unsuccessful.
• A piece is dipped in thrombin solution and applied to the bleeding area
• The combination of thrombin solution and the large rough surface provided
by the sponge causes the blood to clot.
• The foam can be left in situ, where it will be absorbed because it is entirely
of human human origin.
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42. HUMAN NORMAL IMMUNOGLOBULIN
INJECTION
• Immuno or gamma globulin obtained from the globulins fraction
separated in stage 3 of the fractionation of plasma, as had been
shown earlier
• The ionic strengths are critical and further fractionation is done
as follows:
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43. • The immunoglobulins are dissolved in a suitable solvent, usually 0.8% sodium
chloride solution, and a preservative, e.g. 0.01% thiomersal, is added.
• The solution is sterlized by filtration, packed in single dose containers and stored at
4 to 6°C with protection from light.
USES OF IMMUNOGLOBULINS:
• Used to prevent or attenuate diseases such as
o Measles.
o Rubella.
o Infectious hepatitis.
o Hepatitis B.
o Chickenpox.
o Hypogammaglobulinaemia (deficiency in gamma globulins)
• It is used to prepare specific immunglobulins such as:
o Human Anti Vaccinia Immunoglobulin – for small pox.
o Human Anti Tetanus Immunoglobulin.
o Human Anti D Immunoglobulins – used to suppress sensitization of Rh-ve
mothers to the Rh D antigen (Rh +ve infant).
o Anti HBs Immunoglobulin – this is still under investigation. It is an
immunoglobulin for Hepatitis B surface antigen.
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44. QUALITY CONTROL OF BLOOD
PRODUCTS
STANDARDS LABELLING
STERILITYAND
PYROGENS
SOLUBILITY
IDENTIFICATION
WHOLE BLOOD
LABELLING
DRIED PLASMA
PROTEIN
FRACTION
LABELLING
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45. IDENTIFICATION
• Precipitation tests with specific antisera are used to show that only
human serum proteins are present
• The characteristic mobilities of blood proteins in an electrophoretic
field. For example, in the plasma protein fraction there must not be less
than 58% of the protein having the mobility of albumin and not more
than 1% of gamma globulin
• Proteins can be identified by their sedimentation rate in an ultra
centrifuge.
• Differences in clotting behaviour are simpler but useful characteristics.
• Plasma clots when calcium chloride is added, but serum does not.
• Fibrinogen is identified by the clotting that occurs when thrombin is
added, and thrombin by the same result when it is mixed with plasma
• The determination of blood groups – ABO of plasma and cells and Rh
of cells, is an identification test for whole blood.
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46. STERILITY AND PYROGENS
• All blood products must comply with the official tests for
sterility.
• Preparations (i.e. immunoglobulins and the plasma protein
fractions) that are exposed to special risk of contamination with
pyrogens due to lengthy processing must also pass the test for
pyrogens.
SOLUBILITY
• Complete solubility in an appropriate volume of the usual
solvent, sometimes in a specified time, is required for all solid
preparations.
• It indicates that the protein constituents have not deteriorated.
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47. ASSAYS
• For whole blood and concentrated RBCs the assay is a
determination of the haemoglobin value.
• For the remaining products, except fibrin foam (which has no
assay ) and thrombin, the protein constituent is determined
chemically.
• In thrombin there must be a minimum number of clotting
doses per mg, a clotting dose being the amount of thrombin
required to clot 1 ml of 0.1% fibrinogen in saline buffered at
7.2 to 7.3 in 15 seconds at 37°C.
• Determination of Na and K ions in plasma protein fraction
ensures that the level are not high enough to disturb the
electrolyte balance of the recipient.
• An assay for sodium citrate in the same product prevents
toxic effects from excess of this salt.
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50. PLASMA SUBSTITUTES
REPLACEMENT FLUID
• Replacement fluids are used to replace abnormal losses of blood,
plasma or other extracellular fluids by increasing the volume of
the vascular compartment, principally in:
• Treatment of patients with established hypovolaemia: e.g.
haemorrhagic shock.
• Maintenance of normovolaemia in patients with ongoing fluid
losses: e.g. surgical blood loss.
NEED FOR PLASMA SUBSTITUTES
• The limited supplies of plasma.
• The cost of producing the dried form.
• The risk of transmitting serum hepatitis.
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51. PROPERTIES OF IDEAL PLASMA SUBSTITUTE
• The same colloidal osmotic pressure as whole blood.
• A viscosity similar to that of plasma.
• A molecular weight such that the molecules do not easily diffuse
through the capillary walls.
• A fairly low rate of excretion or destruction by the body
• Eventual and complete elimination from the body.
• Freedom from toxicity. E.g. no impairment of renal function.
• Freedom from antigenicity, pyrogenicity, and confusing effects on
important tests such as blood grouping and the erythrocyte
sedimentation rate.
• Isotonicity, in solution, equal to that of blood plasma.
• High stability in liquid form at normal and sterilizing temperatures
and during transport and storage.
• Ease of preparation, ready availability and low cost.
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52. GUM SALINE
• Synonym for Injection of Sodium Chloride and Acacia having
6% acacia in 0.9% Sodium Chloride solution.
DISADVANTAGES:
• Signs of liver dysfunction as gum was not metabolized but
stored in various organs.
Polyvinylpyrrolidone – a synthetic colloid.
Disadvantage – suspected carcinogenicity.
DEXTRAN
• To date this is the most satisfactory plasma substitute.
• It is a polysaccharide produced when the bacterium Leuconostoc
mesenteroides is grown in a sucrose – containing medium.
• In the sugar industry it occurs as a slime that clogs pipes and
filters and interferes with crystallization.
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53. • The organism secretes an enzyme that converts sucrose to dextran
according to the following equation-
• Different strains produce dextrans of two main groups-
o Long practically unbranched chains of glucose units joined by 1-6
glucosidic linkages.
o Highly branched polymers containing of short chains of 1-6 units
joined by 1-4 and 1-3 linkages to branches.
• Branched chains are more likely to give rise to allergic reactions-
o Choose a suitable specially developed strain of the orgainsm that
produces dextran in which about 95% of the linkages are 1-6
production.
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54. • Production involves laboratory culture followed by growth in
seed tanks in the factory and then in 4500 cubic dm fermenters.
• PRECAUTIONS – need to prevent the hydrolysis of sucrose to
glucose and fructose during sterilization of the culture media.
Prevention measures include the adjustment of the media to
neutral pH before sterilization, and the avoidance of overheating.
• When maximum conversion to dextran has been obtained it is
precipitated by adding a suitable organiac solvent.
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55. • Natural dextran consists of chains of approximately 200,000
glucose units with molecular weights up to about 50
million.
• Very large molecules i.e., those with a molecular weight
above about 250,000 have serious drawbacks:
– They yield very viscous solutions that are difficult to administer.
– They may cause renal damage and allergic reactions.
– They interfere with blood matching and sedimentation tests by
causing rouleaux formation. Rouleaux are aggregates of red cells
that resemble piles of plates.
– They produce colloidal osmotic pressures that are lower than those
of small molecules.
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56. • Therefore to produce a material suitable for medical use it is necessary
to reduce the size of the natural molecules. This can be accomplished
in several ways:
o Acid hydrolysis (most widely used).
o Thermal degradation.
o Ultrasonic disintegration.
o Seeding the fermenter.
• The very small molecules, i.e. those of below a molecular weight of
about 60,000 also have disadvantages:
o They are rapidly excreted in urine.
o They pass into the tissue fluids causing an adverse osmotic pressure.
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57. The selected fraction still requires considerable purification to
remove-
• Reducing sugars – by further solvent precipitation. The main
contaminant is fructose, the by-product of fermentation.
• Fractionation solvents – by evaporation under reduced pressure.
• Inorganic salts – by demineralization in a mixed bed ion exchanger.
• Colour – by adsorption on to activated charcoal.
• Pyrogrens – by adsorption on to asbestos, or cellulose derivatives.
• Micro organisms – by filtration.
The solution is diluted to a concentration of 5% in either 5% dextrose
injection or sodium chloride injection, packed in sulphur treated soda-
lime bottles and closed with lacquered rubber plugs.
Finally, it is sterilized, usually by heating in an autoclave.
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