Document Type : Original Article

Authors

1 Dept. of Oral and Maxillofacial Surgery, School of Dentistry, Shiraz University of Medical Sciences, Shiraz, Iran

2 Dept. of Anatomical Sciences, Histomorphometry, Stereology Research Center, Shiraz University of Medical Sciences, Shiraz, Iran

3 Dept. of Clinical Science, School of Veterinary Medicine, Shiraz University, Shiraz, Iran

4 Dept. of Periodontology, School of Dentistry, Shiraz University of Medical Sciences, Shiraz, Iran.

5 Postgraduate Student, Dept. of Oral and Maxillofacial Surgery, School of Dentistry, Shiraz University of Medical Sciences, Shiraz, Iran.

Abstract

Statement of the Problem: Autogenous bone graft is the gold standard for bone reconstruction. osteogenic cells must be kept viable in graft for a successful procedure. In extracorporeal preservation of grafts during surgery three different factors may influence the quality of grafts. These factors include temperature, storage medium and time period.
Purpose: In this study we evaluated the effects of different storage media, temperatures and times on osteoblast count in autogenous bone grafts, preserved extracorporeally.
Materials and Method: Samples were obtained from iliac crest region in a goat. The grafts were preserved in 36 groups of different storage time, temperature and medium. Samples were histomorphometrically analysed to determine osteoblast count as the criteria of graft quality.
Results: In almost all samples room temperature was the most and incubator was the least favorable storage temperatures. In grafts preserved in room temperature no difference was noted between normal saline and ringer lactate solution and in almost all of the samples autologous blood and dry environment were more favorable media than ringer lactate solution. The effects of time period of storage highly depended on the combination of temperature and solution.
Conclusion: the results demonstrated that for preserving as many osteoblasts as possible in bone grafts, the best temperature is room temperature and the least favorable temperature is incubator. Also the best medium for graft storage is blood, which shows better results than normal saline and ringer lactate solution when bone fragments are preserved in room temperature.

Keywords

Introduction

Autogenous bone graft is considered the best method and gold standard for bone defect reconstruction, as it provides three basic factors including osteoinductive molecules, a proper scaffold, and osteogenic cells. It is crucial to keep graft osteogenic cells viable because they are responsible for new bone formation after transplantation [ 1 ]. Although it is highly recommended to implant the autogenous grafts immediately after harvest, it may not be possible. As a result, the bone graft must be stored for a certain amount of time extracorporeally [ 2 , 3 ].

Several storage media have been introduced for graft preservation including normal saline solution, Ringer’s lactate solution, distilled water, different culture media [ 4 ], and autologous blood derived products including whole blood, plasma, serum, platelet-rich-plasma (PRP) [ 5 ], platelet-poor-plasma (PPP) [ 6 ], and so on.

Normal saline solution and Ringer’s lactate solution are the most common infusion fluids in operation room settings. Normal saline solution is also the most common solution used in surgeries as coolant and irrigation [ 4 ]. Most surgeons also consider whole blood a proper medium for bone graft maintenance and it can easily be obtained during surgery [ 5 ]. Although air exposure is considered the most inappropriate medium for bone graft maintenance, in clinical practice the grafts are often stored in dry environments [ 7 ].

Rocha et al. [ 8 ] studied the effects of preserving bone grafts for 30 minutes in different storage media including normal saline solution, PPP, and dry environment in comparison with a control group, which was implanted immediately. The results showed more empty lacunae in the dry group when compared with the control group, the saline group, or the PPP group. No significant difference was reported in the count of empty lacunae between the saline group, the PPP group, and the control group.

Another factor is preservation temperature. There are three temperature ranges usually possible in operation rooms, during surgeries. These include cold preservation (2-8°c), room temperature (18-24°c), and incubator (37°c). Antonenas et al. [ 9 ] preserved blood stem cells in room temperature and refrigerator for 24 hours, 48 hours, and 72 hours. His study showed a great loss of viable cells in the grafts stored in room temperature (21.9%) compared to those stored in refrigerator (9.4%). Finally, the time interlude that a graft is preserved extracorporeally, can affect the quality of the bone graft. Williams et al. [ 10 ] stored canine femoral condyles at 4°c for 14, 21, and 28 days. His study showed >95% cell viability at 14 days, 75-98% at 21 days, and 65-90% at 28 days of preservation. In this study, we have assessed the effects of three major factors on regenerative potential of autogenous cancellous bone grafts.

Material and Method

A one-year-old healthy brown female goat (Capraaegagrus hircus) weighing 28 kg was chosen as the animal model. This study was done according to International animal rights with adherence to the animal experiment rules assigned by Shiraz University of Medical Sciences. Before the surgery, 30cc of blood was obtained from right jugular vein under aseptic condition. The blood was mixed with 6cc of sodium citrate 3.8%, as anticoagulant. The blood was transferred to previously sterilized and labeled laboratory tubes assigned for blood as storage medium. Other tubes contained sterile normal saline solution; Ringer’s lactate solution, or they were empty.

The animal was anesthetized by Ketamine (25mg/ kg) and midazolam (0.2mg/kg) intramuscularly. For local anesthesia, 3.8 ml of lidocaine with epinephrine was injected in surgical site. A single dose of Pen & Strep (2.5mg/kg) was injected intravenously in right jugular vein. The animal was placed on surgery table in sitting position. Surgery was conducted under aseptic condition. The hair on right iliac crest area was shaved and antisepsis was done with aqueous solution of povidone. Animal was covered with sterile drapes and the surgical site was exposed through a perforated drape.

A full-thickness 5cm long incision was placed over right anterior iliac crest with a # 15 blade. Using periosteal elevator, medial and lateral subperiosteal dissection was performed to expose the lateral surface of the iliac crest completely. A 3cm×3cm cortical window was removed by chisel and osteotome to gain access to the cancellous bone. Cancellous blocks were removed by curette and chisel. Blocks were cut by a fine scissor to 180 pieces; the mean volume was 4mm×4mm×4mm. each bone graft sample was transferred to a tube containing storage media.

Copious irrigation of the surgical site with normal saline was done. No active bleeding was noticed. Periosteum, muscle, and fascia were separately sutured with vicryl 4-0. The skin was sutured with Nylon 3-0 and dressing was applied. For studying the effects of three major factors on regenerative potential of autogenous cancellous bone grafts, we used histomorphometrical analysis to evaluate osteoblast count in graft volume unit. These factors included:

1. Different storage media including normal saline solution, Ringer's lactate solution, autologous blood, and dry environment

2. Different storage temperature including cold preservation (2-8°c), room temperature (18-24°c), and incubator (37°c)

3. The time interval that the bone grafts were preserved: 2 hours, 4 hours and 12 hours

The tubes containing specimen and storage medium were distributed evenly in three categories. Each category included 60 tubes and represented storage temperature, including cold preservation, room temperature, and the incubator. Among the 60 tubes in each category, 15 contained normal saline solution, 15 contained Ringer’s lactate solution, 15 contained autologous blood with anticoagulant and 15 tubes did not contain any medium representing the dry environment. Two hours after the harvest time, from each temperature category and storage medium groups, five tubes were selected randomly and the specimens were immediately immersed in 10% formaldehyde solution for 48 hours. Same procedure was done after 4 hours and 12 hours of bone graft preservation.

Bone graft decalcification was performed by EDTA 4.13%, dehydration by ethanol 95% and embedded in paraffin. We used oriented method in order to obtain isotropic uniform random (IUR) sections. Paraffinized bone grafts were semi-serially sectioned in 20µm thickness (H&E staining) using a microtome.

A video-microscopy system consisting of a microscope (Nikon, E-200, Japan) linked to a video camera (SONY, SSC Dc 18P, Japan), a P4 PC computer and a LG monitor (795 FT plus) was utilized for analysis.

The number of osteoblasts was counted with an optical dissector design for 20µm thick sections. Through this method, the count of osteoblasts in a volume unit of the bone specimen was determined. An unbiased counting frame was superimposed on the image of bone graft section on monitor on average 70-100 microscopic fields, which were selected for every bone graft sample. The counting frame had two borders of inclusion and two borders of exclusion. The initial field was selected randomly out of the sample section; the remaining fields were selected by moving the microscope stage using microscope stage along X- and Y-axis in equal intervals. An oil immersion lens with ×100 magnification was used. To assess the numerical density of osteoblasts, the focus area was also moved on Z-axis. Through traveling on Z-axis and using magnification of 60×, a microcater (Hidenhain MT-12, Germany) which calculated the Z-axis movements was employed. Each plane thickness is 5µm, but the first nuclei that came into focus, were excluded. Within the next 5µm of traveling on Z-axis (height) any nucleolus which came into maximal focus was counted, if located within the counting frame or in contact with the inclusion border and did not touch the exclusion border or the frame. Numerical density of osteoblasts was calculated by the following formula [ 11 ]:

Nv=ƩQ(Ʃp×a(f)×h)

In this equation, ƩQ represents the sum of the counted osteoblasts for each sample, a(f) represents the frame area and Ʃp represents the total number of fields in X- and Y-axis on which osteoblasts were counted.

Kruskal-Wallis non-parametric test was used for data analysis and a p Value <0.05 was considered statistically significant. SPSS statistical software (version 15) was utilized for statistical analysis.

Results

Storage Media Comparison

Four groups of storage media were compared with each other sorted and layered by similar time interval and storage temperature, each group contained five specimens. Table 1 shows different storage media comparisons in different preservation temperatures and times.

1. Comparison of four storage media groups, which preserved bone grafts for 2 hours in cold temperature, showed that the highest count was noted in samples stored in autologous blood, followed by dry environment, Ringer’s lactate solution, and finally normal saline solution respectively (p< 0.05).

2. Comparison of four storage media groups which preserved bone grafts for 4 hours in cold temperature showed the highest count was noted in samples stored in normal saline solution, followed by autologous blood, dry environment and finally Ringer’s lactate solution respectively (p<0.05).

3. Comparison of four storage media groups which preserved bone grafts for 12 hours in cold temperature showed that the highest count was noted in samples stored in dry environment, followed by Ringer’s lactate solution, normal saline solution, and autologous blood, respectively (p<0.05).

4. Comparison of four storage media groups, which preserved bone grafts for 2 hours in room temperature, showed the highest count was noted in samples stored in autologous blood, followed by ringer lactate or normal saline solutions and finally dry environment respectively (p< 0.05). No significant results were shown between samples stored in normal saline solution and Ringer’s lactate solution (p> 0.05).

Solution (I) Solution (J) 2 hours 4 hours 12 hours
Mean Difference (I-J) Sig. Mean Difference (I-J) Sig. Mean Difference (I-J) Sig.
Cold temperature Saline Ringer -3955.92140* .000 25196.30000* .000 -24263.0960* .000
Blood -59558.8714* .000 11199.06000* .000 6843.42000* .000
Dry -43916.7214* .000 17637.41000* .000 -43860.2200* .000
Ringer Saline 3955.92140* .000 -25196.3000* .000 24263.09600* .000
Blood -55602.9500* .000 -13997.2400* .000 31106.51600* .000
Dry -39960.8000* .000 -7558.89000* .000 -19597.1240* .000
Blood Saline 59558.87140* .000 -11199.0600* .000 -6843.42000* .000
Ringer 55602.95000* .000 13997.24000* .000 -31106.5160* .000
Dry 15642.15000* .000 6438.35000* .000 -50703.6400* .000
Dry Saline 43916.72140* .000 -17637.4100* .000 43860.22000* .000
Ringer 39960.80000* .000 7558.89000* .000 19597.12400* .000
Blood -15642.1500* .000 -6438.35000* .000 50703.64000* .000
Room temperature Saline Ringer -.00020 1.000 .00060 1.000 -.05320 1.000
Blood -50540.8204* .000 -70851.9100* .000 -49492.7368* .000
Dry 3804.14960* .000 -11804.9298* .000 -59024.6604* .000
Ringer Saline .00020 1.000 -.00060 1.000 .05320 1.000
Blood -50540.8202* .000 -70851.9106* .000 -49492.6836* .000
Dry 3804.14980* .000 -11804.9304* .000 -59024.6072* .000
Blood Saline 50540.82040* .000 70851.91000* .000 49492.73680* .000
Ringer 50540.82020* .000 70851.91060* .000 49492.68360* .000
Dry 54344.97000* .000 59046.98020* .000 -9531.92360* .000
Dry Saline -3804.14960* .000 11804.92980* .000 59024.66040* .000
Ringer -3804.14980* .000 11804.93040* .000 59024.60720* .000
Blood -54344.9700* .000 -59046.9802* .000 9531.92360* .000
Incubator Saline Ringer -11198.3490* .000 15747.68000* .000 33361.77040* .000
Blood -16797.5278* .000 1283.14220 .056 29862.28000* .000
Dry -28891.7600* .000 6415.72040* .000 1866.40060* .004
Ringer Saline 11198.34900* .000 -15747.6800* .000 -33361.7704* .000
Blood -5599.17878* .000 -14464.5378* .000 -3499.49040* .000
Dry -17693.4110* .000 -9331.95960* .000 -31495.3698* .000
Blood Saline 16797.52778* .000 -1283.14220 .056 -29862.2800* .000
Ringer 5599.17878* .000 14464.53780* .000 3499.49040* .000
Dry -12094.2322* .000 5132.57820* .000 -27995.8794* .000
Dry Saline 28891.76000* .000 -6415.72040* .000 -1866.40060* .004
Ringer 17693.41100* .000 9331.95960* .000 31495.36980* .000
Blood 12094.23222* .000 -5132.57820* .000 27995.87940* .000
*Statistically meaningful difference(p <0.05)
Table 1.Kruskal-Wallis comparison results for different storage media for bone graft preservation.

5. Comparison of four storage media groups, which preserved bone grafts for 4 hours in room temperature, showed that the highest count was noted respectively in samples stored in autologous blood, followed by dry environment and finally ringer lactate or normal saline solutions (p< 0.05). No significant results were shown between samples stored in normal saline solution and Ringer’s lactate solution (p> 0.05).

6. Comparison of four storage media groups, which preserved bone grafts for 12 hours in room temperature, showed the highest count was noted respectively in samples stored in dry environment, followed by autologous blood and finally ringer lactate or normal saline solutions (p< 0.05). No significant results were shown between samples stored in normal saline solution and Ringer’s lactate solution (p> 0.05).

7. Comparison of four storage media groups which preserved bone grafts for 2 hours in incubator showed the highest count was noted respectively in samples stored in dry environment, followed by autologous blood, Ringer’s lactate solution, and finally normal saline solution (p< 0.05).

8. Comparison of four storage media groups which preserved bone grafts for 4 hours in incubator showed the highest count was noted respectively in samples stored in autologous blood or normal saline solution, followed by dry environment and finally Ringer’s lactate solution (p< 0.05). No significant results were shown between samples stored in normal saline solution and autologous blood (p= 0.056).

9. Comparison of four storage media groups, which preserved bone grafts for 12 hours in incubator showed the highest count was noted respectively in samples stored in normal saline solution, followed by dry environment, autologous blood, and finally Ringer’s lactate solution (p< 0.05).

Storage Temperature Comparison

Three groups of storage temperature were compared with each other, sorted and layered by similar time interval and storage medium; each group contained five specimens. Table 2 shows different storage temperatures comparisons in different storage media and times.

1. Comparison of three storage temperature groups, which preserved bone grafts for 2 hours in normal saline solution, showed the highest count was noted respectively in samples stored ‎in room temperature, followed by cold preservation and finally incubator (p< 0.05).

2. Comparison of three storage temperature groups, which preserved bone grafts for 4 hours in normal saline solution, showed the highest count was noted respectively in samples stored ‎in cold preservation, followed by room temperature and finally incubator (p< 0.05).

3. Comparison of three storage temperature groups, which preserved bone grafts for 12 hours in normal saline solution, showed the highest count was noted respectively in samples stored ‎in incubator, followed by cold preservation and finally room temperature (p< 0.05).

4. Comparison of three storage temperature groups, which preserved bone grafts for 2 hours in Ringer’s lactate solution, showed the highest count was noted respectively in samples stored ‎in room temperature, followed by incubator and finally cold preservation (p< 0.05).

5. Comparison of three storage temperature groups, which preserved bone grafts for 4 hours in Ringer’s lactate solution, showed the highest count was noted respectively in samples stored ‎in room temperature, followed by cold preservation and finally incubator (p< 0.05).

Temperature (I) Temperature (J) 2 hours 4 hours 12 hours
Mean Difference(I-J) Sig. Mean Difference (I-J) Sig. Mean Difference (I-J) Sig.
Normal saline solution 2-8°c 18-24°c -31158.59100* .000 10965.05000* .000 2566.29120* .000
37°c 3276.34860* .000 12248.20000* .000 -20530.32000* .000
18-24°c 2-8°c 31158.59100* .000 -10965.05000* .000 -2566.29120* .000
37°c 34434.93960* .000 1283.15000* .048 -23096.61120* .000
37°c 2-8°c -3276.34860* .000 -12248.20000* .000 20530.32000* .000
18-24°c -34434.93960* .000 -1283.15000* .048 23096.61120* .000
Ringer’s lactate solution 2-8°c 18-24°c -27202.66980* .000 -14231.24940* .000 26829.33400* .000
37°c -3966.07900* .000 2799.58000* .000 37094.54640* .000
18-24°c 2-8°c 27202.66980* .000 14231.24940* .000 -26829.33400* .000
37°c 23236.59080* .000 17030.82940* .000 10265.21240* .000
37°c 2-8°c 3966.07900* .000 -2799.58000* .000 -37094.54640* .000
18-24°c -23236.59080* .000 -17030.82940* .000 -10265.21240* .000
Autologous blood 2-8°c 18-24°c -22140.54000* .000 -71085.92000* .000 -53769.86560* .000
37°c 46037.69222* .000 2332.28220* .000 2488.54000* .000
18-24°c 2-8°c 22140.54000* .000 71085.92000* .000 53769.86560* .000
37°c 68178.23222* .000 73418.20220* .000 56258.40560* .000
37°c 2-8°c -46037.69222* .000 -2332.28220* .000 -2488.54000* .000
18-24°c -68178.23222* .000 -73418.20220* .000 -56258.40560* .000
Dry environment 2-8°c 18-24°c 16562.28000* .000 -18477.28980* .000 -12598.14920* .000
37°c 18301.31000* .000 1026.51040* .035 25196.30060* .000
18-24°c 2-8°c -16562.28000* .000 18477.28980* .000 12598.14920* .000
37°c 1739.03000* .004 19503.80020* .000 37794.44980* .000
37°c 2-8°c -18301.31000* .000 -1026.51040* .035 -25196.30060* .000
18-24°c -1739.03000* .004 -19503.80020* .000 -37794.44980* .000
*Statistically meaning full Difference (p <0.05)
Table 2.Kruskal-Wallis comparison results for different temperatures for bone graft preservation.

6. Comparison of three storage temperature groups, which preserved bone grafts for 12 hours in Ringer’s lactate solution, showed the highest count was noted respectively in samples stored ‎in cold preservation, followed by room temperature and finally incubator (p< 0.05).

7. Comparison of three storage temperature groups, which preserved bone grafts for 2 hours in autologous blood, showed the highest count was noted respectively in samples stored ‎in room temperature, followed by cold preservation and finally incubator (p< 0.05).

8. Comparison of three storage temperature groups, which preserved bone grafts for 4 hours in autologous blood, showed the highest count was noted respectively in samples stored ‎in room temperature, followed by cold preservation and finally incubator (p< 0.05).

9. Comparison of three storage temperature groups, which preserved bone grafts for 12 hours in autologous blood, showed the highest count was noted respectively in samples stored ‎in room temperature, followed by cold preservation and finally incubator (p< 0.05).

10. Comparison of three storage temperature groups, which preserved bone grafts for 2 hours in dry environment, showed the highest count was noted respectively in samples stored ‎in cold preservation, followed by room temperature and finally incubator (p< 0.05).

11. Comparison of three storage temperature groups, which preserved bone grafts for 4 hours in dry environment, showed the highest count was noted respectively in samples stored ‎in room temperature, followed by cold preservation and finally incubator (p< 0.05).

12. Comparison of three storage temperature groups, which preserved bone grafts for 12 hours in dry environment, showed the highest count was noted respectively in samples stored ‎in room temperature, followed by cold preservation and finally incubator (p< 0.05).

Storage Time Comparison

Three groups of storage time were compared with each other sorted and layered by similar storage temperature and medium, each group contained five specimens. Table 3 shows different storage times comparison in different preservation media and temperatures.

Time (I) Time (J) Cold preservation Room temperature Incubator
Mean Difference (I-J) Sig. Mean Difference (I-J) Sig. Mean Difference (I-J) Sig.
Normal saline solution 2.00 4.00 -30318.7114* .000 11804.92960* .000 -21346.8600* .000
12.00 -11654.7914* .000 22070.09080* .000 -35461.4600* .000
4.00 2.00 30318.71140* .000 -11804.9296* .000 21346.86000* .000
12.00 18663.92000* .000 10265.16120* .000 -14114.6000* .000
12.00 2.00 11654.79140* .000 -22070.0908* .000 35461.46000* .000
4.00 -18663.9200* .000 -10265.1612* .000 14114.60000* .000
Ringer’s lactate solution 2.00 4.00 -1166.49000* .000 11804.93040* .000 5599.16900* .000
12.00 -31961.9660* .000 22070.03780* .000 9098.65940* .000
4.00 2.00 1166.49000* .000 -11804.9304* .000 -5599.16900* .000
12.00 -30795.4760* .000 10265.10740* .000 3499.49040* .000
12.00 2.00 31961.96600* .000 -22070.0378* .000 -9098.65940* .000
4.00 30795.47600* .000 -10265.1074* .000 -3499.49040* .000
Autologous blood 2.00 4.00 40439.22000* .000 -8506.16000* .000 -3266.19002* .000
12.00 54747.50000* .000 23118.17440* .000 11198.34778* .000
4.00 2.00 -40439.2200* .000 8506.16000* .000 3266.19002* .000
12.00 14308.28000* .000 31624.33440* .000 14464.53780* .000
12.00 2.00 -54747.5000* .000 -23118.1744* .000 -11198.3478* .000
4.00 -14308.2800* .000 -31624.3344* .000 -14464.5378* .000
Dry environment 2.00 4.00 31235.42000* .000 -3804.14980* .000 13960.62040* .000
12.00 -11598.2900* .000 -40758.7192* .000 -4703.29940* .000
4.00 2.00 -31235.4200* .000 3804.14980* .000 -13960.6204* .000
12.00 -42833.7100* .000 -36954.5694* .000 -18663.9198* .000
12.00 2.00 11598.29000* .000 40758.71920* .000 4703.29940* .000
4.00 42833.71000* .000 36954.56940* .000 18663.91980* .000
*Statistically meaning full Difference (p <0.05)
Table 3.Kruskal-Wallis comparison results for different storage times for bone graft preservation.

1. Comparison of three time-period groups, which stored bone grafts in normal saline solution in cold preservation, showed the highest count was noted respectively in samples ‎stored for 4 hours, followed by 12 hours and finally 2 hours (p< 0.05).

2. Comparison of three time-period groups, which stored bone grafts in Ringer’s lactate solution in cold preservation, showed the highest count was noted respectively in samples ‎stored for 12 hours, followed by 4 hours and finally 2 hours (p< 0.05).

3. Comparison of three time-period groups, which stored bone grafts in autologous blood in cold preservation, showed the highest count was noted respectively in samples ‎stored for 2 hours, followed by 4 hours and finally 12 hours (p< 0.05).

4. Comparison of three time-period groups, which stored bone grafts in dry environment in cold preservation, showed the highest count was noted respectively in samples ‎stored for 12 hours, followed by 2 hours and finally 4 hours (p< 0.05).

5. Comparison of three time-period groups, which stored bone grafts in normal saline solution in room temperature, showed the highest count was noted respectively in samples ‎stored for 2 hours, followed by 4 hours and finally 12 hours (p< 0.05).

6. Comparison of three time-period groups, which stored bone grafts in Ringer’s lactate solution in room ‎ temperature, showed the highest count was noted respectively in samples ‎stored for 2 hours, followed by 4 hours and finally 12 hours (p< 0.05).

7. Comparison of three time-period groups, which stored bone grafts in autologous blood in room ‎ temperature, showed the highest count was noted respectively in samples ‎stored for 4 hours, followed by 2 hours and finally 12 hours (p< 0.05).

8. Comparison of three time-period groups, which stored bone grafts in dry environment in room ‎ temperature, showed the highest count was noted respectively in samples ‎stored for 12 hours, followed by 4 hours and finally 2 hours (p< 0.05).

9. Comparison of three time-period groups, which stored bone grafts in normal saline solution in incubator, showed the highest count was noted respectively in samples ‎stored for 12 hours, followed by 4 hours and finally 2 hours (p< 0.05). Comparison of three time-period groups, which stored bone grafts in Ringer’s lactate solution in incubator, showed the highest count was noted respectively in samples ‎stored for 2 hours, followed by 4 hours and finally 12 hours (p< 0.05).

10. Comparison of three time-period groups, which stored bone grafts in autologous blood in incubator, showed the highest count was noted respectively in samples ‎stored for 4 hours, followed by 2 hours and finally 12 hours (p< 0.05).

11. Comparison of three time-period groups, which stored bone grafts in dry environment in incubator, showed the highest count was noted respectively I samples ‎stored for 12 hours, followed by 2 hours and finally 4 hours (p< 0.05).

Discussion

The preservation circumstances studied in this article included different times, different storage media, and different storage temperatures. The time interval the grafts are preserved extracorporeally is a result of surgery and patient’s condition, but the storage medium and temperature is a choice the surgeon can decide. Based on the time expected for the surgery, one can determine the best storage condition for the highest quality of grafts.

In comparing the different storage media, in all specimens stored in room temperature, Ringer’s lactate solution and normal saline solution showed no difference in osteoblast preservation. In all grafts stored for 2 hours, autologous blood was superior to Ringer’s lactate solution and normal saline solution. In addition, in all bone grafts preserved for 12 hours, those stored in dry environment showed higher count of osteoblasts than that in Ringer’s lactate solution and blood.

In a total comparison, blood was a better medium than Ringer’s lactate solution, except grafts stored for 12 hours in cold preservation. In addition, dry environment preserved more osteoblasts in all situations, except for preservation of grafts for 2 hours in room temperature.

In the bone grafts stored for 2 hours in room temperature, the autologous blood resulted in the highest count of osteoblast, followed by ringer lactate or normal saline solution with dry environment causing the least count of osteoblasts. This is similar to the study Rocha et al. [ 8 ] performed, considering that they only stored the grafts for 30 minutes in room temperature, and found dry environment causing more empty lacunas. They found no difference between the grafts implanted immediately after harvesting and those stored in room temperature in either normal saline solution or PPP.

In comparing different temperatures, in all grafts stored for 4 hours, the ones kept in incubator showed the lowest osteoblast count; those stored in dry environment and blood all showed the same result. The specimens stored in autologous blood, room temperature was the best in preserving osteoblasts.

In a total comparison, incubator temperature caused the least count of osteoblasts except for the grafts stored for 2 hours in Ringer’s lactate solution and for 12 hours in normal saline solution. Moreover, in all specimens except those kept for 2 hours in dry environment, 4 hours in normal saline solution and 12 hours in either normal saline or Ringer’s lactate solution, room temperature was the best storage temperature for osteoblast preservation.

Antonenas et al. [ 9 ] showed more viable cells in grafts stored in normal saline solution in cold preservation than those kept in room temperature for 24, 48 or 72 hours; in this study, the specimens stored in normal saline for 4 or 12 hours, showed higher count of osteoblast in cold preservation than room temperature.

In comparing different time-periods the grafts were kept, in those preserved in room temperature, the grafts that were stored for 12 hours showed the least count of osteoblasts, except for the specimens stored in dry environment. In all bone grafts stored in autologous blood, those preserved for 12 hours showed less count of osteoblasts than those kept for 2 or 4 hours. However, the graft particles, which were stored for 12 hours in dry environment, showed higher count of osteoblast in comparison with those, preserved for 2 or 4 hours.

William et al. [ 10 ] preserved osteochondral grafts in refrigerator for at 4°c for 14, 21 and 28 days. Their study showed> 95% cell viability at 14 days, 75-98% at 21 days and 65-90% at 28 days of preservation. They stored osteochondral femoral condyles in a solution containing 10% fetal calf serum, glutamate, non-essential amino acids and anti-microbial agents like penicillin, streptomycin, and fungizone. Similarly, in our study the grafts in any medium, either infusion solutions or blood showed the least count of osteoblasts in 12 hours of storage than those stored for 2 or 4 hours.

In future studies, we recommend a further in vivo analysis to correlate these in vitro results with graft survival chance. In addition, other criteria such as bone spicule density can correlate with less bone graft resorption, which should be evaluated. One must consider that bone graft surgery success depends on many factors other than extracorporeal storage method, including surgeons’ qualification, soft tissue handling, recipient site quality, patient’s general health condition, and so on; all these factors may influence the results of in vivo studies.

Conclusion

In a total comparison, blood is a better medium than Ringer’s lactate solution, except for the grafts stored for 12 hours in cold preservation. The specimens stored in autologous blood, room temperature were the best in preserving the osteoblasts. In all bone grafts stored in autologous blood, those preserved for 12 hours showed less number of osteoblasts compared to those kept for 2 or 4 hours. Based on the results from this study, in order to preserve the highest count of osteoblasts in bone graft extracorporeal storage, room temperature and autologous blood is recommended. Room temperature is the most favorable and recommended temperature and the favorable storage media are saline solution, Ringer lactate solution, and autogenous blood. Moreover, the best time for bone storage out of body is shorter than 4 hours and longer preservation time would result in noticeable loss of osteoblasts, therefore it should be avoided.

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