Upsala J Med Sci 93: 201-214, 1988 

Storage of Human Red Blood Cells and Platelets 
Some aspects concerning the factors leading t o  storage lesion 

characterized as morphological changes and vesiculation. 
Minireview based on a doctoral thesis 

Christel Solberg 
Department of Biochemistry, Institute of Medical Biology, University of Tromsm, Troms#, Norway 

ABSTRACT 
Y 

1. Storage renders erythrocytes more responsive to thermally induced morphological changes, 
especially the shedding of microvesicles. 4-8 week old cells can be morphologically "rejuvenated" by 
heating. 

2. If pH increases during storage of platelets an extensive loss of small particles occurs. The 
platelet disintegration is associated with a loss in the metabolic activity, discharge of LDH, 
increased suseptibility to phospholipid hydrolysis by phospholipase C and is found to be initiated 

during the actual preparation of platelet concentrates. 

3. Activation of platelets during preparation can be decreased by shortening the first centrifugation 

time or by using adenine in the anticoagulant. 
4. A 4 hour prestorage of the whole blood unit prior to centrifugation strongly decreases the 
activation of platelets upon stimuli and results in platelet concentates much more stable to storage. 

INTRODUCTION 

Biochemical and morphological changes in erythrocytes during storage. 

Upon storage, B series of metabolic and morphological changes occur in the erythrocyte producing 

eventually a non-viable cell form that is rapidly removed from the body upon transfusion. To 
understand these changes, it is necessary to understand the structure and properties of the fresh 
erythrocyte. 

The red cell membrane consists of a lipid bilayer of several differenl classes of lipids (30) with an 

ssyinetric distribution of the individual lipid types (64). The cholinc-containing phospholipids ( PC, 

SM) are located mainly in the outer layer and the amino phospholipids (PS, PE) preferentially in 
the inner layer. 

13-888572 20 1 



Phosuliolipid composition in fresh human erythrocytes (30). 

Phosoholipid class Molar uercentaee 

SM Sphingomyelin 24.5f2.0 
PC Pliosphatidylcholine 25.4fl.l 
PS Phosphatidylserine 5.8f1.7 
PE Phosphatidylethanolamine 27.0f1.7 
PIP Phosphatidylinositol-4,5-bisphosphate 1 .4M0.3 
PI Phosphatidyl inositol 1.2M.1 
PA Phosphatidic acid 2.2M.2 

Lysophosphatidylethanolamine 1.3io.3 
Lysophosphatidyl choline 1.OM.3 

Integral membrane proteins penetrate the lipid bilayer and interact with the hydrophobic lipid core. 

These include receptor and antigen-bearing proteins, such as glycophorin A and the anion transport 
channel Band 3. The latter is most important in that the protein cytoskeleton is anchored to Band 

3. The red cell cytoskeleton consists of a highly, organized filamentous network mainly consisting 

of spectrin (band 1, 2), ankyrin (band 2 4 ,  band 4.1 and actin (band 5) (13,49,50,78,79). 
The metabolic changes occuring during storage result in membrane reorganisation and change in 

morphology. During storage the red cell undergoes a defined series of morphological changes 

(Fig.1) 

Fig.1. Scanning electron micrograph of stored red cells. 
It passes from the smooth discocyre (1) to a crenated disc (2, echinocyte I; 3, echinocyte 11) 
thereafter it swells to a crenated sphere (4, echinocyte 111) and finally to a sphere with multiple 
short, thin spicules (5, sphero-echinocyte) that will gradually shed off (6, spherocyte) (16,45,47). 

During storage intracellular Ca ’+ increases and ATP decreases (25,33,37,73,96). The echinocyte 
formation and vesiculation (budding of the thin spicules) can be induced by treating fresh cells with 

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Ca2+ and ionophore A 23187 (1,Z). Echinocyte transformation can also be induced by metabolic 
depletion simply by incubating the red cells at 37°C for 24 h and results in two different reactions 

(69). One is the increase in lysolecithiri in the outer phospholipid bilayer resulting in an expansion 
in the outer leaflet and echinocytosis (42), the other slower change is the suggested rearrangement 

of the membrane proteins (29). 

ATP does not directly control either the form or deformability of the membrane, but events 

secondary to ATP depletion are responsible for the induced changes (28). 

The degree of irreversible change upon metabolic depletion depends of many external factors such 

as: rate, length of time of AT€' depletion, temperature, pH, Ca 2 + ,  Mg 2 + ,  plasma, oxygen availability. 
After about 30 h ATP depletion major lesions occur in the form of surface components loss 

(vesiculation) increase in cytoplasmic viscosity and osmotic fragility (93). 

The earliest change in the membrane structure upon ATP depletion is the increase in the amount of 

spectrin-actin-4.1 complex that can be extracted from the membrane by exposure to low-ionic 
strength buffers (48). Band 4.1 is associated with the lipid membrane by a polyphospho-inositide 

(PIP,,PIP)-regulated binding to glycophorin ( 5 ) .  The binding sites for actin and band 4.1 are 

localized to the tail of the spectrin tetramer. Near to the head region of spectrin is the binding 
site for ankyrin (89). The spectrin 8-chain has four phosphorylation sites in the end of the 

molecule where the end-to-end association with the a-chain occurs and close to the ankyrin binding 

sites. A 

confoimationally intact cytoskeleton is essential for maintaining the cell shape and deformability. 

Upon heating a decrease in spectrin extractability can be measured prior to onset of red cell 

fragmentation and shape change (56). 

Conformationally intact spectrin is necessary for preserving the membrane phospholipid asymmetry. 

When intact red cells are oxidised with agents that selectively crosslink spectrin, 30-50% of the 

inner membrane phospholipids, phosphatidylserine (PS) and phosphatidylethanolamine (PE), become 
accessible at the outer membrane surface (32). If these amino-phospholipids become exposed on the 

outer surface of the red cell or platelet, they will activate the conversion of prothrombin to 
thrombin and promote intravascular clotting (65,94). Exposure of PS and PE on the exterior of 

blood cells also makes them more adherent to endothelial cells (75) and increases the trapping into 

the reticuloendothelial cells (76). While the relationship between spectrin phosphorylation and 

shape change is only indirect (4,68), it is clearly evident that the phospholipid asymmetry and shape 

change are ATP-dependent (77). The maintenance of the membrane phospholipid asymmetry is due 

to two different processes: 

Ankyrin has also a phosphorylation site localized in the spectrin-binding domain (12). 

i )  

ii) 

Binding of aminophospholipids to spectrin (32,SO). 

"Pumping" of lipids from the outside back to the inside, by the bidirectional ATP-dependent 

"flip-flop" enzyme (flippase) (92). 

Although there is only 1.4% phosphatidylinositol-4,5.bisphosphate (PIP , ) in the membrane it is 
evident that the conversion of PIP, to P i  is directly correlated to ATP depletion (30). Concomit- 
tant with this conversion phosphatidic acid will dephosphorylate to diacylglycerol. Taken together 

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the changes in lipid population will shrink the inner membrane monolayer by 0.6%, which is enough 
to convert discocytes to echinocytes III (10). 
High levels of intracellular calcium activate the Ca '+ -dependent phospholipase C resulting in the ' 
degradation of PIP and PIP to the fusogenic diacylglycerol (3). 

In conclusion, to survive in the circulation the erythrocyte must be both strong and flexible 

(49,50,57). The "cellular deformability" is necessary for passage through the microcapillaries and 
especially through the narrow portals of the spleen. The biconcave disc-shape of normal eryth- 
rocytes creates a surface area-to-volume relationship that is advantageous for this purpose. The 

sphere has in contrast to the discoid form minimum area-to-volume ratio and is therefore far less 
flexible and deformable. Stored cells not only lose in vivo viability because of increased trapping 
in the spleen but also disappear from the circulation because of increased adhesion to endothelial 

cells. 

Preparation and storage of platelets 

Whereas the human red cell is a rather simple non-nucleated cell consisting of a flexible and very 

stable, uniformly built up membrane enclosing a near-saturated solution of hemoglobin with the only 
function to transport 0 and CO , , the platelet is a complex, non-nucleated, very active cell. 
Platelets have, in addition, mitochondria performing oxidative phosphorylation and resulting in 36 

ATP/glucose molecule instead of only 2 ATP/glucose in the glycolytic pathway. The adenine 
nucleotides in the platelets are enclosed in three physically distinct compartments, 64% in the dense 

granule pool (human ATP/ADP ratio = 0.7), 32% in the metabolic pool (ATE'/ADP ratio = 4-5) and 
4% in the F-actin bound pool (ADP only) (36). 

The platelet plasma membrane is very similar to the erythrocyte membrane, the phospholipids are 
asymmetrically arranged in the same pattern (20.95). 
Spectrin-like molecules underlying the membrane have been found (23) with concomittant changes in 
the organization of cytoskeletal elements and the exposure of internal phospholipids upon activation 
of platelets (9,21). 
The platelet membrane has, in addition, several different receptors and is easily activated by many 

different agents (22,39,55). Many of these substances can also be released during the activation 
process itself such as ADP and serotonin (released from the platelet dense granulae), arachidonic 
acid and thromboxane A, (from the phospholipid breakdown in the platelet membrane), thrombin 

(from the activation of prothrombin by the coagulation cascade) and collagen (released from injured 
epithelial cells). Activation can also be induced by physical stimuli such as cell-cell contact which 

occurs, for example, during mixing (6.7). centrifugation (53,74) and gel filtration (74). Activation of 
the platelet membrane results in the breakdown of phospholipids and especially in changes in the 
small phosphatidylinositol pool. The polyphosphatidylinositol (PJP ) hydrolysis to the second 
messengers inositoltriphosphate (JP ) and diacylglycerol (DG) is the initial agonist (e.g., thrombin, 
collagen, platelet activating factor, thromboxane A , )-stimulated event in the phosphatidylinositol 
turnover (14,51,63). JP, mobilizes Ca2+ from intracellular stores and initiates PI hydrolysis. DG 

204 



and Ca2' in concert serve as a direct activator of protein kinase C resulting in the phosphorylation 
of the 40 kDa protein and the Ca2'-enhanced serotonin release from dense granulae (39). DG, once 
produced, disappears very rapidly; it is converted either to phosphatidic acid or by the action of 

diglyceride lipase degraded to glycerol and arachidonic acid (1 1,39). 
The Ca 2+ mobilization also activates phospholipase A 

further facilitated by DG (40) and results in arachidonic acid release from the major phospholipid 

pools (PC, PE, PS) (17,70). Liberated arachidonic acid is rapidly converted to prostaglandins and 

thromboxanes which in turn are capable of activating other phospholipids in the membrane resulting 

in a positive feedback loop (35). 
The activation of PLC and PLA, working together leads to an amplified response (8,17). 

Both enzymes lead to arachidonic acid liberation 

different ways (91). 

PLC has an pH optimum of 7.5, is specific for phosphatidylinositol and liberates diglyceride. PLA, 

activity is enhanced by increasing the pH (7.5 to 9.5), hydrolyses PC, PE, PS and liberates free 

fatty-acid and lysophospholipids (17). There is also a synergistic amplifiction in the platelet 

response as a result of simultaneously stimulation by different agonists (8,26,66). 

In morphological terms the activation of platelets is seen as a change from a smooth disc to a 
sphere with pseudopods. The first phase in platelet activ-ation is a reversible shape change. If 

the cell is more strongly activated a second phase will follow which is associated with release of 

the granulae content and irreversible changes occur (44). 
A Na'/H+ antiporter is involved in the pathway leading to arachidonic acid mobilization by epineph- 

rine, ADP and low concentrations of thrombin (8). Removal of extraplatelet Na' or increasing 
extraplatelet H t  (i.e. decreasing extraplatelet pH from 7.35 to 6.8) causes a blockage in the Na'LH' 
exchange system and inhibits platelet aggregation (88). 

The morphological change in stored platelets is found to be well correlated with the posttransfusion 
viability and those concentrates having the highest proportion of discoid platelets also have the 

best survival (41). There is also a close correlation between the pH in the platelet concentrate 
(PC) after storage and the morphology (83). At pH 7.2-6.8 platelets maintain a normal discoid 

shape. With decreasing pH, platelets swell and at pH less than 6.0 all platelets are spherical (59). 

This fall in pH is due to lactate production from glycolysis (58). If the platelets are supplied with 

enough 0 2 ,  lactate production and thereby pH decrease is prevented. A new generation of storage 
bags with increased gas permeability has therefore been developed (61). The high gas permeability 

very effectively prevents the pH fall below 6.0. In the first generation of platelet storage bags the 
shelf life for PC was limited to 3 days because the rapid decrease in pH. In the second generation 
of platelet storage bags the shelf life has been extended to 5-7 days. 

Loss of respiratory metabolism as observed by rising PO, and decreasing p C 0 ,  results in decreasing 
ATP levels. The platelet storage lesion, measured as the decrease in platelet count, increasing 
discharage of intracellular lactate dehydrogenase (LDH), decrease in the extent of photometrically 

measured shape change induced by ADP and the ability of platelets to recover from hypotonic shock 

rue all found to be highly correlated to platelet ATP (34). 
For maintaining the phophoinositide cycle, ATP is necessary. It has recently been shown that the 

(PLA , ), a stimulation that is 

even though they hydrolyse phospholipids in 

205 



generation of PIP 2 ,  and not the second messengers IP and DG, controls the polymerization of actin 
and the mechanism of platelet shape change mechanism (43). The inability to produce PIP, could 
therefore be a limiting factor for in vivo viability and function. 

During storage the cells can start to bud off membrane (vesiculation) resulting in a irreversibly 

changed cell membrane. In the erythrocyte this is a relatively slow process and the uniformly built 
up cell membrane renders the erythrocyte a good model for studying the vesiculation process. In 

the platelet, the cell interior consists of several different organelles and an internal surface- 

connecting system (52). The main function of the platelet is the activation and aggregation 

process. The storage lesion of platelets in the form of buddindfragmentation, could, because of 

rhe risk for an accelerated "self-activation", be explosive. From an deeper understanding of the 

circumstances responsible for and the mechanism of vesiculation/fragmentation it will be possible to 

change the preparation and storage properties and in that way make more storage-stable, viable 
blood cells. 

RESULTS AND DISCUSSION 

A. Red cell storage and vesiculation 

Fresh red cells are essentially unaffected by heating below the thermal transition temperature of 

spectrin (49"C), but above rhis temperature are very rapidly changed to large smooth spheres and 

subsequently to smaller smooth spheres (81). 
During in vitro storage of red cells metabolic and morphological changes gradually occur. Some of 
the morphological changes are easily reversible, sometimes simply needing increases in intracellular 

ATP for reversibility, whereas some changes are irreversible e.g. the transformatin to speroechino- 

cytes or sperocytes. 

During storage of red cells to the time of outdaling (4-8 weeks) the proportion of echinocytes(E)II 

and EIII is increased. A 1 minute heat treatment at 46°C of 4-8 weeks stored blood, readily 

increased the proportion of the discoid (D+EI) (i.e., morphologically "younger") cell forms (from 40 

to 55%) concornitlatit with a decrease in the proportion of EIII. Recent findings of others also 

show that red cells, stored for 42 days in SAGM-solution, show a significantly increased (39% to 

51%) precentage of discoid formed cells (D+EI) upon a one hour incubation at 37'C. This latter 
improvement in morphology does not, however, result in any change in the in vivo posttransfusion 

survival, potassium leak, glucose consumption or ATP concentration (38). It is thus highly 
questionable whether this morphological improvement we observe using the 46'C treatment 

represents a true "rejuvenation" of the aged erythrocytes. 

If the stored cells instead are rejuvenated (by incubation with adenosine or adenine to raise the 

intracellular ATP level), the improvment in morphology is followed by an increased in vitro viability 

(37,47,90). 

Prolonged heating of stored cells at 46'C resulted in a fall in the precentage discoid formed cells 

and a marked increase in the spheroechinocytic cells (i.e., "accelerated ageing"). Thus indicating 
thal lhere are still unrepaired changes in the stored cell membrane, making the cells more 

206 



susceptible to heating than are fresh cells. 
At 48 C, extensive shedding of microvesicles and a gradual increase in the number of spherocytes 

occurs. At 5OoC a rapid and extensive microvesiculation associated with a rapid conversion to 

spherocytes of different sizes is observed. 

During ATP-depletion, spectrin will be dephosphorylated and result in echinocytosis. The loss of 

the interaction between the spectrin-cytoskeleton and the phospholipid-bilayer could explain the 

facilitated vesiculation occuring upon heating around the spectrin-transition temperature (67,78,81). 

The spherocyte was found not to respond morphologically to heating other than by lysing. 

Longster (47) has also shown, that stored cells which already have reached the "smooth sphere 

state, were similar to the type of cells which were rapidly removed from the circulation upon 

transfusion. He also found that these cell types cannot revert to disc form upon incubation at 

37°C with or without added adenine. 

The speroechinocyte, but not the earlier morphological forms, is also readily lysed upon treatment 
with phospholipase C (PLC, Bacillus cereus) and this enzyme can be used as a tool for assessing the 

degree of in vitro ageing of stored red cells (45). This would suggest some marked differences in 

the nature of the cell membrane in spheroechinocytes. Most probably a lowering of the lateral 

packing pressure in the membrane (24), although other membrane rearrangements cannot be 

excluded. Little (46) showed that glass-bottle stored RBC were more susceptible to PLC lysis than 

plastic bag ( D E W -  containing) stored cells. 

B .  Storage of platelet concentrate in the first generation containers (PL-146). 

The phospholipids of fresh human platelets are extremely resistant to hydrolysis by externally added 

PLC (82). This was also the case with activated fresh platelets. During storage, presumably as a 

result of decreases in the lateral packing of phospholipids in the external leaflet, the suceptibility 

to PLC degradation increases. 

These suggested ch'anges in membrane packing pressure occumng both in stored red cells and 

stored platelets could arise from a build up in the levels of components such as diglyceride, 

lysophospholipids or free fatty acids in the membrane (20). 
The extent of phospholipid hydrolysis upon incubation of platelets with PLC is dependent on the 
plasma pH after storage (82). PC with a pH 6.6-6.8 resulted in only 1045% phospholipid hydrolysis. 

Lower pH resulted in higher degradation. Increasing pH resulted in a more marked increase in the 

susceptibility to hydrolysis by PLC and this was found to be very extensive (50-60%) at pH>7.4. 
Note that the pH values refer to the plasma pH in the concentrates after storage. All platelets 

were incubated with PLC at the same pH. 

In PC with pH>7.3 after storage, there was also a prominent change in morphology. The size 
distribution of PC shows that the platelets have become smaller and the PC contaiii an increased 

number of microvesicles/platelet fragments (83). A quarter of the platelets were balloon-formed or 
lysed and the discharge of LDH was elevated. 

The storage lesion was also found to be more marked for PC of lower pH after storage. The 
progressive disc-to-sphere swelling was reversible as long as the pH was >6.1. 

207 



C. Storage of platelet concentrate in second veneration containers (PL 1240. PL 7321. 

i) Influence of storage containers. 

A limiting factor for platelet storage in the first generation of bags, was rate of diffusion of gases, 

especially 0, through the bag walls. 

types of plastics (polyolefin, Fenwal type PL 732) (61) or by using other types of plasticizer in PVC 
bags (Fenwal 1240, Cuttler CLX) (31) the gas diffusion could be increased. 

When PC stored in the first generation of bags (PL 146) were compared to PC in the second 

generation of bags (PL 1240), at storage expiry the latter were, in our hands, found on average to 
have become much more alkaline (84,85). In view of the well established connection between 

changes in pH during storage and loss of vkblility (41,58,60,61) the above observation would lead 

one to expect an enhanced loss of platelet quality in the second generation of bags. Indeed, this 

rise in pH during storage was associated with extensive evidence of platelet degradation in the 

form of decreased platelet count, high levels of extracellular LDH activity and very abnormal 

platelet size distribution profiles as shown in the Coulter Counter. This latter feature arose, from 

platelet disintegration as seen in electron microscopy ( 8 5 )  and with the subsequent appearance of 

large numbers of small particles (84). There was a strong correlation between the extent of pH 
increase during storage and the increase in relative number of small particles (e0.85). Isolation of 

these small particles showed that they g had a very considerable procoagdant activity, 

measured as platelet factor 3 activity (PF3) (84). Similar findings have recently been found by 
Miller and Bode (54). Using a flow cytometer these workers have shown the occurrence of small 

particles in stored PC and that these particles have PF3 activity. They have also found that 

thrombin inhibitors in the anticoagulant inhibit thrombin production and the release of 

PF3 (18,19). 

The discharge of LDH was also strongly correlated with the pH changes. In PL 1240 the LDH 

discharge was several-fold higher than that observed in PL 146 bags. The average LDH discharge in 

3 PC after 4 days storage in PL 146 (i.e. storage life expiry) was 11% and in PL 1240 30% which rose 

to 45% after 6 days storage (storage life expiry for PL 1240 stored PC). 

A major difference between PL 146 and PL 1240 is the nature of the plasticizer used in the 

manufacture of the plastic from which the storage bag is constructed. 

In PL 146 DEHP (di-ethyl-hexyl-phthalate) plasticizer is used and this is easily extracted from the 

plastic, is fat-soluble and is known to be accumulated in the cell membrane (71). DEHP has been 

found to inhibit phospholipase A ,  activity and can thereby decrease the platelet aggregation ability 

(72). This chemical has also been shown to inhibit the vesiculation from erythrocytes (27). The 

storage life for red cell decreases from 35 to 21 days if types of storage bag, other than DEHP- 
containing ones, are used (62,71). 

PL 1240 and CLX bags contain tri(2-ethylhexyl) trimellitate (TEHTM) as plasticizer. TEHTM is less 

fat soluble and results in a 30-fold reduction of plasticizer accumulated in platelet concentrates 

during 5 day storage at 22'C (i.e. 15 pg/ml of TEHTM compared with 450 pg/ml of D E W )  (31). 
The higher gas diffusion, in the second generation of bags, not only hinders the development of 

It was found that by using very thin-walled bags (60), other 



anaerobic conditions and the resulting lactate production but concomittantly accelerates CO 

diffusion out of the bags. An early rise in pH can sensitize the platelet to further damage 

resulting in less CO, production leading to further pH rise. A vicious circle resulting in high pH, 

loss of metabolic activity and platelet disintegration can in this way be established. Indeed, 

Murphy (61) has shown that deleterious changes and decrease in in vivo viability associated with 

high pH, could be largely prevented by storing PC in an atmosphere containing 10% CO, . 

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ii. Influence of memuation method . 

Platelets are isolated from whole blood by centrifugation. By using different recommended 

centrifugation methods we found that the metabolic activity during and after storage in the PC was 

very different depending on the precise centrifugation method used (85,86). Already the day after 

preparation there was a highly significant difference between the PO, values in the bags (86). 

Depending on the platelet concentration, pH and the metabolic activity in the PC, the LDH 
discharge and the extent of build up of small paraticles (S.P.) after storage could be predicted, to 

90% (LDH) and 86% (S.P.) respectively by the use of multivariate data analysis (86). 

This close correlation between the aspects of the storage lesion and loss of metabolic activity was 
confirmed in the recently published results of Holme (34) showing the correlation between metabolic 

activity, ATP concentration and storage lesion. 

Our findings concerning the strong influence of the centrifugation method used and the subsequent 

metabolic activity in stored PC was, however, in great contrast with experience reported widely in 

the U.S.A. 

The major difference between the blood collection and handling procedures in U.S.A. and our own 

is the time between blood withdrawal and subsequent preparation. In the U.S.A. about 80% of the 
blood is collected in blood-mobiles, resulting in a gap of several hours between donation and the 

separation of blood components. In Sweden and Norway the preparation of components is supposed 
to be carried out within two hours after phlebotomy (15). 

0 

I 
1 l h  dh 3 h  b h  

TIME OF STORAGE OF WHOLE BLOOD 

Fig. 2. Changes in aggregation response in whole blood upon storage from four different donators. 

209 



With the use of a whole-blood aggrometer, changes in the aggregation response after phlebotomy 

could be followed in whole blood, i.e., without any manipulations of the blood (Fig. 2). The 

aggregation response measured at 37°C starts to decrease after 2 hours. After 3 hour the aggrega- 

tion was less than half the maximum response (87). Preparation of PRP after a 4 hour prehold of 

whole blood results in a significantly decreased aggregation response upon stimulation with collagen. 

Using lower (cyclooxygenase-dependent) doses resulted in no aggregation (measured as change in 
light absorption), whereas PRP prepared exactly 60 minutes after blood withdrawal yielded a high 

aggregation response. 

' 

Using CPD-Adenine instead of CPD alone as 'anticoagulant was also found to decrease significantly 

the aggregation response to physiological doses of collagen. 

The superior morphological state of 6 day-stored platelet concentrates from platelets prepared after 

4h-rested blood compared with immediately processed blood is clearly apparent in electron microsc- 

opy (Fig.3.) 

Fig.3. Transmission electron micrographs of 6 day-stored PC. A= PC prepared close to phlebotomy 
showing a high number of lysed or fragmented platelets, which correpond to the high LDH 
discharge. B= PC prepared after 4 h prestorage of whole blood showing discoid platelets with well 
preserved internal structure and almost no lysed cells. 

A 4 hours prehold of CPD-whole blood prior to preparation in the secondgeneration of bags 

results in less activation during preparation and less storage lesion. 

The combination of storage a1 higher pH and no DEHP in CPD-plasma renders the time delay before 
preparation as a new important parameter to be considered in platelet storage. 

In Norway and Sweden and conceivably in other regions of the world as well, present blood bank 
practise is to process blood as soon as possible after donation. In such a situation, the combina- 

tion of the second generation storage containers and adenine-free anticoagulant can very easily 

yield substandard, potentially dangerous platelet preparations after storage. The uncovering of this 

fact together with what appears to be a very simple way of avoiding this problem is undoubtedly 

the most import'anl aspect of the work described in this thesis. 

210 



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Adress for correspondence: 

Christel Solberg 
Institute of Medical Biology 
University of Tromsg 
9001 Tromsg, Norway 

214