Departments of 1Orthopaedics, Traumatology & Rehabilitation, 2Basic Medical Sciences and 3Deanship of Research & Postgraduate Affairs, Faculty of 
Medicine, International Islamic University Malaysia, Kuala Lumpur, Malaysia
*Corresponding Author e-mails: ariffs@iium.edu.my and mdariffs@hotmail.com

تقومي النسجيات حلبيبات اهليدروكسي آباتيت يف وجود أو عدم وجود بالزما 
غنية بالصفائح الدموية مقابل طُْعم عظمي ذايت

دراسة مقارنة للمواد احليوية املستخدمة يف دمج الفقرات يف األرانب النيوزلندية البيضاء

زمزوري زكريا، �سي نور ز�رد ��سي �سيمان، ز�نريا بيونغ، حممد عارف �رشف �لدين، �أحمد حافظ ذو �لكفل، قمرول �آرفن خالد

abstract: Objectives: Hydroxyapatite (HA) has osteoconductive properties and is widely used as a bone graft 
substitute. Platelet-rich plasma (PRP) is an autologous product with osteoinductive effects. Hypothetically, a 
combination of both would augment the bone formation effect of HA and widen its application in spinal fusion 
surgeries. This study aimed to compare new bone formation with HA granules alone and in combination with 
PRP versus an autologous bone graft during a lumbar intertransverse process spinal fusion. Methods: A total of 
16 adult New Zealand white rabbits underwent single-level bilateral intertransverse process fusion at the L5–L6 
vertebrae. One side of the spine received either HA granules alone or a combination of HA granules and PRP, 
while the contralateral side received an autologous bone graft. Four animals each from the HA group and the 
HA plus PRP group versus the autograft group were assessed either at six or 16 weeks by undecalcified histology 
and histomorphometry. The mean percentage of new bone areas over the corresponding fusion masses were 
compared between groups. Results: No significant difference in new bone formation was observed between the 
HA and HA plus PRP groups at six or 16 weeks. The autograft group had significantly more new bone formation 
at six and 16 weeks (P = 0.004 and <0.001, respectively). Conclusion: An autologous bone graft remains superior 
to HA granules, with or without PRP. HA granules demonstrated an excellent osteoconductive scaffold but had 
poor biodegradability. While PRP enhances the properties of HA granules, these biomaterials do not have a 
synergistic effect.

Keywords: Autografting; Hydroxyapatite; Lumbar Vertebrae; Platelet-Rich Plasma; Spinal Fusion.

�لغنية  �لبالزما  وتعد  �لعظمي.  للطعم  كبديل  كثري�  وت�ستخدم  �لعظمي،  �لتو�سيل  خو��ص  لها  �آباتيت  �لهيدروك�سي  مادة  الهدف:  امللخ�ص: 
بال�سفائح �لدموية منتج ذ�تي ذو �آثار تو�سيل عظمي. ومن ناحية �فرت��سية يوؤدي �جلمع بني �ملادتني معا لتقوية عملية تكوين �لعظام 
تكوين  عملية  ملقارنة  �لدر��سة  هذه  وتهدف  �لفقر�ت.  دمج  جر�حات  يف  تطبيقاتها  من  وتو�سع  �آباتيت،  �لهيدروك�سي  مادة  بها  تقوم  �لتي 
عظام جديدة مع ��ستخد�م مادة �لهيدروك�سي �آباتيت مبفردها، و�أي�سا عند جمعها مع �لبالزما �لغنية بال�سفائح �لدموية يف مقابل ُطْعم 
عظمي ذ�تي �أثناء �إجر�ء عملية دمج �لفقر�ت بني �لناتئتني �مل�ستعر�ستني �لَقَطِنّي. الطريقة: �أجريت عملية ثنائية �جلانب لدمج �لفقر�ت بني 
�لناتئتني �مل�ستعر�ستني �لَقَطِنّية على 16 من �لأر�نب �لنيوزيلندية �لبي�ساء يف �لفقر�ت L5–L6. و�عطي يف جانب و�حد من �لعمود �لفقري 
حبيبات مادة  �لهيدروك�سي �آباتيت مبفردها، �أو مع مادة  �لهيدروك�سي �آباتيتمع �لبالزما �لغنية بال�سفائح �لدموية. بينما عمل يف �جلانب 
�لآخر �ملقابل من �لعمود �لفقري ُطْعم عظمي ذ�تي. ومت �إجر�ء تقومي ن�سيجي وهي�ستومورفوميرتي بعد 6 �أو 16 �أ�سابيع يف كل �أربعة �أر�نب 
من �ملجموعتني. ومتت مقارنة ن�سبة م�ساحة �لعظم �جلديد �إىل �أحجام �لفقر�ت �ملدجمة يف �ملجموعتني. النتائج: مل يالحظ �أي فرق معنوي 
يف تكوين عظم جديد بني �ملجموعتني يف �لأ�سبوعني �ل�ساد�ص و�ل�ساد�ص ع�رش. ومتيزت جمموعة �لطعم �لعظمي �لذ�تي بتكوين عظم �أكرث 
يف �لأ�سبوعني �ل�ساد�ص و�ل�ساد�ص ع�رش ) P = 0.004 و 0.001< على �لتو�يل(. اخلال�صة: يظل �لُطْعم �لعظمي �لذ�تي متفوقا على حبيبات 
�لهيدروك�سي �آباتيت، ويف وجود وغياب بالزما غنية بال�سفائح �لدموية. و�أظهرت حبيبات �لهيدروك�سي �آباتيت �أن لها قدرة ممتازة على 
�أن تكون "�سقالة" للتو�سيل �لعظمي. غري �أن لهذه �ملادة قابلية منخف�سة للتحلل �حليوي. و�أظهرت �لبالزما �لغنية بال�سفائح �لدموية قدرة 

على تقوية خو��ص مادة �لهيدروك�سي �آباتيت، �إل �أن هذه �ملو�د �حليوية لي�ص لها تاأثري تاآزري.
الكلمات املفتاحية: ُطْعم عظمي ذ�تي؛ �لهيدروك�سي �آباتيت؛ فقر�ت َقَطِنّية؛ بالزما غنية بال�سفائح �لدموية؛ دمج �لفقر�ت.

Histological Evaluation of Hydroxyapatite 
Granules with and without Platelet-Rich Plasma 

versus an Autologous Bone Graft
Comparative study of biomaterials used for spinal fusion in a New Zealand 

white rabbit model
Zamzuri Zakaria,1 Che N. Z. C. Seman,1 Zunariah Buyong,2 *Mohd A. Sharifudin,1 

Ahmad H. Zulkifly,1 Kamarul A. Khalid1,3

clinical & basic research

Sultan Qaboos University Med J, November 2016, Vol. 16, Iss. 4, pp. e422–429, Epub. 30 Nov 16
Submitted 18 Feb 16
Revisions Req. 20 Apr & 22 Jun 16; Revisions Recd. 25 May & 6 Jul 16
Accepted  19 Jul 16 doi: 10.18295/squmj.2016.16.04.004



Zamzuri Zakaria, Che N. Z. C. Seman, Zunariah Buyong, Mohd A. Sharifudin, Ahmad H. Zulkifly and Kamarul A. Khalid

Clinical and Basic Research | e423

Bone grafts are used in various clinical fields.1,2 Commonly, bone grafts are harvested from the patient’s own bones during surgery. 
However, serious complications related to the 
harvesting procedure can arise, such as bleeding, 
infection and chronic pain at the donor site, as well 
as increased costs and operating time.1,3,4 As a result, 
the demand for bone graft substitutes has led to 
multidisciplinary research designed to develop new 
biomaterial technology. 

In Malaysia, researchers from a collaborative 
project have successfully manufactured and commer-
cialised a synthetic bone graft substitute known as 
GranuMas® (GranuLab, Kuala Lumpur, Malaysia); 
this product is made of locally produced calcium 
phosphate-based hydroxyapatite (HA) granules 
fabricated from limestone.5 Khadijah et al. tested 
this bone graft substitute on New Zealand white 
rabbits with non-critical tibial metaphyseal defects; 
undecalcified bone histology showed new bone 
formation two weeks after implantation and the defect 
was completely bridged by new bone at 4–6 weeks.6 As 
demonstrated in the animal model, HA granules have 
shown good evidence of bone formation in the weight-
bearing areas; however, there is currently no scientific 
evidence that this product is suitable for application 
in non-weight-bearing areas, such as in lumbar 
spinal fusion. 

In lumbar spinal fusion surgeries, an autologous 
bone graft is still considered the gold standard, as it 
possesses all of the properties necessary for bone 
regeneration, such as osteoconductivity, osteo-
inductivity and the presence of osteogenic cells.3 In 
comparison, HA granules are solely osteoconductive 
due to their similarity to the mineral components of 
bone tissue.7,8 Despite this, combining HA granules 
with growth factors—such as platelet-derived 
growth factor, transforming growth factor and 
vascular endothelial growth factor—can augment 
bone formation.9 The main purpose of this study 
was therefore to compare new bone formation using 
an undecalcified histology technique in a lumbar 
intertransverse process spinal fusion with HA alone 
and a combination of HA with platelet-rich plasma 
(PRP) versus an autograft control.

Methods

A total of 16 New Zealand white rabbits between 
10–19 months old and 2.25–3.40 kg were used in this 
study. The animals were randomly divided into two 
groups of eight rabbits each to form a HA group and 
a HA plus PRP group. Two assessment periods were 
chosen to show differences in the fusion healing and 
remodelling changes as a previous study indicated 
histological evidence of fusion-healing changes at 16 
weeks.10 As such, each group was further subdivided 
into two groups of four rabbits according to the time of 
observations (at six or 16 weeks, respectively).

Assumptions for the mean percentage of bone 
area in subgroups were made according to sample size 
calculations, since a previous study reporting a similar 
method of comparison using new bone formation in 
intertransverse process spinal fusions was performed 
at 12-week intervals.10 The sample size was calculated 
using PASS software, Version 2008 (NCSS LLC, 
Kaysville, Utah, USA), to measure the difference of 
the mean percentage of bone area in subgroups with 
80% power and a significance level of <0.05. In a one-
way analysis of variance (ANOVA) test, the means of 
three samples of four individuals each were compared. 
The total sample of 16 subjects achieved 91% power 
to detect differences among the means versus the 
alternative of equal means using an F-test with a <0.05 
significance level. The size of the variation in the means 
was represented by their standard deviation (24.94). 
The common standard deviation within a group was 
assumed to be 20.00 [Table 1].

All of the animals underwent a bilateral inter-
transverse process spinal fusion between the L5 and 
L6 vertebrae using a previously described lateral 
approach technique.11 A single orthopaedic surgeon 
with previous experience in animal studies performed 
the surgery and a trained laboratory technician 
administrated the anaesthesia. Synthetic GranuMas® 
HA granules (GranuLab) between 1,000–2,500 µm 
with a tap density of 0.524 g/mL and ~48% porosity 
were used. The platelet-rich plasma (PRP) was 
obtained from the rabbits’ peripheral blood using a 
gravitational platelet sequestration technique with 
a table-top centrifuge machine.12 The processing 

Advances in Knowledge
- Calcium phosphate-based hydroxyapatite (HA) granules can be used as bone substitutes in non-weight bearing areas such as in a 

lumbar intertransverse process spinal fusion.
- HA granules have excellent osteoconductive properties but lack biodegradability.
- Autologous bone grafts result in significantly more new bone formation in comparison to HA granules, with or without platelet-rich 

plasma (PRP).

Application to Patient Care
- The results of this study showed that HA granules and a combination of HA granules and PRP are potentially good bone substitutes in 

spinal fusion procedures; however, autologous bone grafts result in significantly more new bone formation.



Histological Evaluation of Hydroxyapatite Granules with and without Platelet-Rich Plasma versus an Autologous Bone Graft 
Comparative study of biomaterials used for spinal fusion in a New Zealand white rabbit model

e424 | SQU Medical Journal, November 2016, Volume 16, Issue 4

was done under sterile conditions. The HA granules 
and platelet gel were prepared prior to implantation 
following the decortication of the transverse processes. 
The HA granules were mixed with the platelet gel in a 
Petri dish before being implanted into the fusion bed. 
One side of the spine was then implanted with either 
HA granules alone (the HA group) or HA mixed with 
PRP (the HA plus PRP group). The contralateral site 
of the spine acted as a control and received an iliac 
crest bone graft (the autograft group). The same 
rabbit was used in both one experimental group and 
the control group so as to eliminate the confounder 
of physiological variability between individual rabbits.

Subsequently, the rabbits were euthanised at either 
six or 16 weeks post-implantation. Their spines were 
harvested from the L4 to L7 vertebrae en bloc with the 
adjacent paravertebral muscles. A hard tissue band 
cutting and microgrinding system (Exakt Advanced 
Technologies, Norderstedt, Germany) was used to 
produce undecalcified tissue sections. Retrieved 
specimens were fixed in 10% neutral buffered formalin, 
dehydrated in a series of concentrations (70%, 90% 
and 100%) of ethanol and then cleared in chloroform. 
The specimens were then infiltrated in various 
concentrations (10%, 30%, 50%, 70%, 90% and 100%) of 

hydroxyethyl methacrylate (Technovit® 7200, Heraeus 
Kulzer, Hanau, Germany) before being embedded in 
pure hydroxyethyl methacrylate (Technovit® 7200, 
Heraeus Kulzer). The tissue sections were then stained 
using the Masson-Goldner trichrome staining method 
and analysed using a transmitted light microscope 
(Olympus® BX61, Olympus Corp., Tokyo, Japan).

The total area of fusion mass was defined as the 
area spanning from the upper border of the transverse 
process of L5 vertebra (TP5) superiorly, the lower 
border of the transverse process of L6 vertebra 
inferiorly, the intertransverse membrane ventrally and 
the ventral border of paraspinal muscles. New bone 
area was defined as an area with mineralised bone, 
marrow within the mineralised area and osteoids. 
Unremodelled or native transverse processes, marrow 
within the transverse processes, cartilaginous tissue, 
soft tissue stroma, HA granules and the remnants of 
the autograft were excluded from the measurement of 
new bone.

The total fusion and new bone areas were measured 
in pixels using Photoshop CS4 Extended, Version 
11.0 (Adobe Systems Inc., San Jose, California, USA). 
Examples of the calculation of fusion mass, measured 
total fusion and new bone areas are shown in Figure 1. 

Table 1: Sample size calculations for assumptions of the mean percentage of bone areas

Power Average k Total Alpha Beta SD of 
means

SD Effect size

0.90861 4.00 3 12 0.05000 0.09139 24.94 20.00 1.2472

SD = standard deviation.

Figure 1: Schematic diagrams showing examples of the quantification of areas of (A) full thickness fusion mass, (B) total 
fusion mass and (C) new bone in a New Zealand white rabbit model receiving an autograft and either hydroxyapatite 
granules or hydroxyapatite granules plus platelet-rich plasma.
HAG = hydroxyapatite granules; TP5 = transverse process of the L5 vertebra; TP6 = transverse process of the L6 vertebra.



Zamzuri Zakaria, Che N. Z. C. Seman, Zunariah Buyong, Mohd A. Sharifudin, Ahmad H. Zulkifly and Kamarul A. Khalid

Clinical and Basic Research | e425

The percentage of new bone area was calculated from 
the total number of pixels filled with new bone over 
the total number of pixels in the fusion mass area. 
The mean percentage of new bone over the total 
fusion mass area in the autograft, HA and HA plus 
PRP groups at different periods were analysed using 
the Statistical Package for the Social Sciences (SPSS), 
Version 16 for Macintosh (IBM Corp., Chicago, 
Illinois, USA). The percentage of new bone was then 
compared statistically using the one-way ANOVA 
and Tukey’s and Dunnett’s post hoc tests. A P value of 
<0.050 was considered statistically significant.

This study was approved by the International 
Islamic University Malaysia Research Ethics Comm-
ittee, International Islamic University Malaysia, Kuala 
Lumpur, Malaysia (#IIUM/305/14/1).

Results

At six weeks post-implantation, the fusion mass in 
the autograft group was well defined and easily 
differentiated from the surrounding paraspinal muscle, 
which was stained brick red. Evidence of remodelled 
woven bone was observed in the fusion mass near 
the middle of TP5. Immature new bone trabeculae 
or woven bones were seen in the peripheral zones 
around the transverse processes and adjacent to both 
decorticated sides of the transverse processes. In the 
central zone, the fusion mass was made up of immature 
new bone trabeculae, bone marrow, remnants of old 
bones (either autografted or grafted bones), cartilage 
and soft tissue stroma. 

In the autograft group, the remnants of old bones 
at six weeks were in close contact and integrated 
well with the islands of newly formed bone. Well-
organised and regularly arranged collagen fibres and 
osteocyte lacunae characterised the remnants of the 
old bones. The lacunae appeared empty and contained 
no osteoids. In this section, the green mineralised old 
bone appeared brighter than the new bone (woven 
or newly remodelled bone). In the same way, the 
undecorticated side of the transverse processes also 
displayed a green colour similar in intensity to the old 
bones [Figure 2A]. 

Areas of endochondral bone formation in the 
autograft group at six weeks post-implantation were 
characterised by a different chondroblast morphology. 
The chondroblasts in the small lacunae nearest to the 
stromal tissue were evenly spaced in the matrix of 
the reserve zone. Adjacent to this, the chondroblasts 
were stacked up in columns in the proliferative zone. 
Next to this zone, the lacunae were hypertrophied 
in the maturation zone. Subsequently, the hyaline 
cartilages were calcified and resorbed by osteoclasts 
in the resorption zone. Osteoblasts were attached to 
the calcified hyaline cartilage and secreted osteoids. 
Osteoids were observed scattered in the calcification 
zones and the adjacent woven bone. New bone 
trabeculae in these areas appeared less dense compared 
to the newly formed woven bone. In between bone 
trabeculae, cells of various sizes—suggestive of bone 
marrow—were observed [Figure 2B]. Evidence of 
adipose cells was noted in the marrow during this 
observation period.

Figure 2: Photomicrographs of Masson-Goldner trichrome-stained sagittal sections at either (A & B) six or (C) 16 weeks 
post-implantation showing the full thickness fusion mass of a New Zealand white rabbit receiving an autograft. A: Old bone 
(OB) can be seen in direct contact with the new bone (NB) trabeculae at x100 magnification. B: Islets of remodelled bone 
trabeculae and marrow as well as NB, cartilage and remnants of the autograft or OB are seen across the fusion mass at x200 
magnification. C: Note the completely remodelled NB and almost complete cortical rim (arrows) bridging the bone between 
the transverse processes at x40 magnification. There is also visible loss of the normal anatomical structure of the transverse 
process of the L6 vertebra (TP6) and a common shared marrow cavity with the fusion mass. The soft tissue gap near the TP6 
is filled with soft tissue stroma, various stages of endochondral bone cartilage formation and minimal remnants of OB.
OB = old bone; M = marrow; NB = new bone; CR = cortical rim; TP5 = transverse process of the L5 vertebra; TP6 = transverse process of the 
L6 vertebra.



Histological Evaluation of Hydroxyapatite Granules with and without Platelet-Rich Plasma versus an Autologous Bone Graft 
Comparative study of biomaterials used for spinal fusion in a New Zealand white rabbit model

e426 | SQU Medical Journal, November 2016, Volume 16, Issue 4

In the autograft group, minimal grafted bone was 
observed at 16 weeks post-implantation. The remnants 
consisted mainly of cortical bone. A striking feature 
seen at this stage was the almost complete remodelling 
of the fusion mass, characterised by the presence of 
a cortical rim encasing cancellous bone and marrow 
within it. Under higher magnification, various sizes of 
cells were seen, suggestive of the multicellular content 
of the bone marrow. These cells were separated from 
each other by empty spaces. Remnants of transverse 
processes underwent total remodelling as part of the 
fusion mass [Figure 2C].

Six weeks post-implantation, new bone trabeculae 
were observed in the peripheral zones of the HA group. 
In the central zone, new bone trabeculae in between 
the HA granules almost bridged the transverse 
processes. Areas of soft tissue stroma and adjacent 
endochondral bone formation were also seen. There 
was extensive direct bonding between the new bone 
and the HA granules [Figure 3A]. Interestingly, new 
bone trabeculae had formed extensively on the surface 
of the HA granules in the fusion mass; however, no 
obvious new bone trabeculae were observed on 
the surfaces of the HA granules in contact with the 
margins of the fusion mass, neither at its junction 
with the paraspinal muscles nor the intertransverse 
membrane. At higher magnification, bone ingrowth 
was observed in some of the peripheral pores of the 
HA granules. No obvious remodelling was seen in the 
fusion mass at this time [Figure 3B].

In the HA group, scattered groups of stromal 
tissue and endochondral bone formation were seen in 
between the HA granules in the central region, similar 
to those observed in the autograft group. At 16 weeks 
post-implantation, new bone remodelled with the 
formation of bone marrow was observed [Figure 3C]. 
Scattered stromal tissues and on-going endochondral 
bone formation in the central zone were observed. No 
obvious evidence of early cortical rim formation was 
noted, unlike in the autograft group during the same 
observation period.

Generally, the HA granules in the HA plus PRP 
group were well defined and contained within the 
intended fusion site. In addition, fusion masses were 
better formed and a larger number of HA granules 
were observed on tissue sections in comparison to 
the HA group. Six weeks post-implantation, new 
bone trabeculae were seen only near the decorticated 
transverse processes (i.e. in the peripheral zone). In 
the central zone, a greater number of HA granules 
were contained in the fusion mass compared to the 
HA group. The spaces in between the HA granules 
were filled with either soft tissue stroma or dense 
material [Figure 4A]. The dense material was more 
prominent in spaces further from the decorticated 
transverse processes. Similar dense material was not 
found in either the autograft or the HA groups. The 
soft tissue stroma in the HA plus PRP group was 
composed of a few blood vessels and spindle-shaped 
fibroblast-like cells [Figure 4B]. Some stromal tissue 

Figure 3: Photomicrographs of Masson-Goldner trichrome-stained sagittal sections at either (A & B) six or (C) 16 weeks 
post-implantation showing the full thickness fusion mass of a New Zealand white rabbit receiving hydroxyapatite (HA) 
granules. A: The HA granules can be seen in direct contact with the new bone (NB) trabeculae at x10 magnification.
B: Stromal tissue and endochondral bone formation are observed in proximity to the HA granules at x20 magnification. 
C: There is evidence of NB remodelled with bone marrow formation at x4 magnification. Stromal tissue and many loci of 
on-going endochondral bone formation can be seen in close proximity to the HA granules. Evidence of a cartilaginous gap 
can be observed at the lower third of the fusion mass and there is no obvious cortical rim formation.
NB = new bone; HAG = hydroxyapatite granules; C = cartilaginous zone; M = marrow; TP5 = transverse process of the L5 vertebra; 
TP6 = transverse process of the L6 vertebra.



Zamzuri Zakaria, Che N. Z. C. Seman, Zunariah Buyong, Mohd A. Sharifudin, Ahmad H. Zulkifly and Kamarul A. Khalid

Clinical and Basic Research | e427

was also seen in the cavities at the periphery of the 
granule. In one of the cavities, a multinucleated cell 
was discernible; however, whether this cavity was 
caused by osteoclastic activity or not could not be 
determined. No obvious new bone trabeculae were 
seen in close proximity. 

In the HA plus PRP group, new bone areas were 
found only near the transverse processes at 16 weeks 
post-implantation. In contrast to the six-week samples, 
areas with endochondral bone formation were located 
in the peripheral zone. In the central zone, the fusion 
mass was packed with HA granules. Unlike the 
granules in the HA group, the granules in the HA plus 
PRP group were closer together. The spaces in between 
the granules were filled with dense material and some 
stromal tissue, similar in appearance to those observed 
at six weeks. No obvious new bone growth was seen in 
the central zone in any of the samples.

The mean percentage of new bone area in the 
autograft group was significantly higher compared to 
the HA and HA plus PRP groups at six weeks post- 
implantation (65.5% versus 33.1% and 9.8%, respect-
ively; P = 0.004). At 16 weeks, the mean percentage 
of new bone area formed in the autograft group was 
86.4% compared to 33.5% in the HA group and only 

20.3% in the HA plus PRP group (P <0.001) [Table 2]. 
Dunnett’s post hoc test showed no statistically 
significant difference between the HA and HA plus 
PRP groups (P = 0.154). A post hoc test revealed 
that significant differences existed only between 
the autograft versus HA groups and the autograft 
versus HA plus PRP groups (P <0.001 each) and no 
significant differences were observed between mean 
bone percentages in the HA versus HA plus PRP 
groups (P = 0.487).

Discussion

A lumbar intertransverse fusion is commonly 
performed on patients with lumbar instability to 
regenerate bone tissue at sites previously occupied by 
muscle. Recently, HA has been used as a substitute 
for autologous bone grafting and there have been no 
detailed reports of intertransverse fusion failure.13,14 
Calcium phosphate-based HA is well known for its 
osteoconductive properties; however, studies have 
revealed that graft materials with osteoconductive 
properties alone are inadequate to generate new 
bone at this site.15–17 In its natural form, PRP contains 
growth factors and other cytokines;18,19 these growth 

Table 2: Mean percentage of new bone growth between groups receiving an autograft and either hydroxyapatite 
or hydroxyapatite plus platelet-rich plasma at six and 16 weeks post-implantation in a New Zealand white rabbit 
model (N = 16)

Six weeks post-implantation 16 weeks post-implantation

n Mean percentage ± SD n Mean percentage ± SD

Group

Autograft 8 65.5 ± 28.4 8 86.4 ± 12.0

HA 4 33.1 ± 9.0 4 33.5 ± 12.6

HA plus PRP 4 9.8 ± 9.0 4 20.3 ± 9.1

F statistic F(2,10) = 9.808 F(2,12) = 27.004

P value 0.004 <0.001

SD = standard deviation; HA = hydroxyapatite; PRP = platelet-rich plasma.

Figure 4: Photomicrographs of Masson-Goldner trichrome-stained sagittal sections at six weeks post-implantation 
showing the full thickness fusion mass of a New Zealand white rabbit receiving hydroxyapatite (HA) granules plus platelet-
rich plasma (PRP). A: Minimal new bone trabeculae are observable at x100 magnification and are adjacent to the transverse 
processes only. B: By enlarging an area of Figure 4A (yellow box) by x20 magnification, a cavity in the periphery of the HA 
granule can be seen filled with stromal tissue and a multinucleated cell. 
HAG = hydroxyapatite granules; S = stromal tissue.



Histological Evaluation of Hydroxyapatite Granules with and without Platelet-Rich Plasma versus an Autologous Bone Graft 
Comparative study of biomaterials used for spinal fusion in a New Zealand white rabbit model

e428 | SQU Medical Journal, November 2016, Volume 16, Issue 4

factors have been shown to play an important role in 
promoting bone healing.20 Thus, hypothetically, the 
combination of HA granules and PRP would enhance 
the effect of HA granules on bone formation. 

In the current study, there was new bone form- 
ation at both ends of the fusion mass near the 
decorticated transverse processes in the HA group at 
six weeks. No intervening cartilage was seen in close 
proximity to this area. Areas of cartilage formation 
were observed in between the granules in the central 
zone. At 16 weeks, new bone was seen bridging the 
transverse processes. However, unlike in the autograft 
group, there was an absence of cortical remodelling 
and single marrow cavities in the HA group. This 
presumably occurred because most of the area in 
the fusion mass consisted of HA granules. In the HA 
plus PRP group, specimens showed almost the same 
results as those of the HA group. New bone formation 
was limited at both ends of the fusion mass near 
the decorticated transverse processes. Both of the 
transverse processes appeared to be healed instead of 
demonstrating the active bone outgrowth seen in both 
the autograft and HA groups. Moreover, no intervening 
cartilage was seen in close proximity to this area. The 
spaces between the granules in the central zone were 
mainly occupied by connective tissue stroma and no 
areas of cartilage formation were observed. One sample 
even demonstrated mature tissue fibrosis at 16 weeks. 
In contrast, no tissue fibrosis was observed in samples 
from the autograft or HA groups. Furthermore, 
there was no statistical difference between the HA 
and the HA plus PRP groups; this may be due to the 
small sample size of the current study as the power 
to demonstrate a difference between the groups 
was small.

Although HA demonstrates good osteoconduct-
ivity, the mean percentage of bone area among the 
HA group in the current study was significantly lower; 
this may be because the HA granules were minimally 
resorbed even at 16 weeks post-implantation and they 
occupied a large volume of the fusion mass. A similar 
explanation can be applied to the HA plus PRP group 
as well. Nevertheless, the results of this study indicate 
that HA granules and HA plus PRP may potentially 
be used as a good bone graft substitute for spinal 
fusion. Other studies in the literature are in agreement 
with these findings.2,21,22 The porous characteristics 
of HA potentially affect the histological outcomes of 
posterolateral lumbar fusion; Motomiya et al. found 
that the highly interconnected porous structure of 
HA was a promising environment for spinal fusion in 
a rabbit model in terms of producing fusion masses 
with higher cellular viability.23 In addition, Bansal et al. 
reported that HA in combination with β-tricalcium 

phosphate and bone marrow aspirate was a safe option 
for spinal fusion and had comparable effectiveness to 
an autologous bone graft; the major advantage of this 
option is the avoidance of donor site morbidity.2

Based on the results obtained from the current 
study, it is recommended that future research on HA 
granules or HA granules plus PRP focuses on the use 
of these materials in combination with spinal fusion 
instrumentation in larger-sized animal models. In 
spinal surgery, higher fusion rates are achieved when 
instrumentation is used.24 One of the limitations of 
the current study was the absence of macroscopic, 
radiographical and biomechanical analyses of the 
fusion areas. 

Conclusion

Autologous bone grafts remain superior to the 
implantation of HA granules or HA granules plus PRP 
in terms of new bone formation in intertransverse 
process spinal fusion. However, HA granules—either 
in combination with PRP or on their own—can be 
used as alternative bone substitutes to support new 
bone growth.

c o n f l i c t o f i n t e r e s t
The authors declare no conflicts of interest. 

f u n d i n g

This study was supported by a research grant from 
the International Islamic University Malaysia (#FRGS 
0207-69).

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