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Review paper

Use of platelet-rich plasma in orthopaedics and traumatology

Paweł Niewczas
1
,
Andrzej Kotela
1
,
Paweł Łęgosz
1
,
Katarzyna Pirko-Kotela
2
,
Sylwia Sarzyńska
1
,
Małgorzata Starczyńska
3

  1. Department of Orthopaedics and Traumatology of Musculoskeletal System, 1st Faculty of Medicine, Medical University of Warsaw, Warsaw, Poland
  2. Department of Internal Medicine and Endocrinology, 1st Faculty of Medicine, Medical University of Warsaw, Warsaw, Poland
  3. Department of Manual Therapy, Institute of Physiotherapy, Faculty of Medicine and Health Science, Jan Kochanowski University, Kielce, Poland
Medical Studies/Studia Medyczne 2016; 32 (1): 63–68
Online publish date: 2016/04/05
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Introduction

Platelet-rich plasma (PRP) is a concentration of blood platelets suspended in a small volume of plasma. The first author who tried to define platelet-rich plasma was Marx [1], who suggested the concentration of 1 million platelets in 1 µl of plasma (i.e. a level 4–5-fold higher than that found in the peripheral blood). However, Anitua et al. [2] wrote about a platelet count of 300,000 in 1 µl of plasma, which he named plasma rich in growth factors (PRGF). The definition of platelet-rich plasma remains controversial.
The first information about the use of platelet-rich plasma during cardiac surgery was published in 1987 by Ferrari et al. [3]. Since then, a number of clinical studies have been conducted and the range of indications has been constantly extending. In 1998, Marx et al. [4] presented study results concerning the use of PRP in mandibular continuity reconstruction, which showed higher bone density after the application of platelet-rich gel. At present, platelet-rich plasma is used in such medical fields as maxillofacial surgery, cardiac surgery, orthopaedics, sports medicine, dentistry [5, 6], aesthetic medicine [7] and general surgery [8].
Platelet-rich plasma is obtained by centrifuging the patient’s whole blood [9]. As a result, blood cell counts are divided into three fractions: platelet-poor plasma, platelet-rich plasma (sometimes referred to as the buffy coat) and red blood cells. The next step is to separate the red blood cells from platelet-poor plasma and the buffy coat fractions. The other fractions are centrifuged using various speeds and times of spin. Platelets are isolated in a small volume of plasma. There are several industrial methods of obtaining PRP from the patient’s blood which differ in terms of centrifugation parameters, type of blood containers or the anticoagulants used. Numerous studies have been conducted, but the best method of PRP preparation is yet to be determined [9].
The essence of platelet-rich plasma therapy consists in growth factors (GF). Three types of granules can be distinguished in the structure of platelets. The granules contain different substances [2]. Platelet -granules are comprised of haemostatic factors and regulators of inflammatory processes and wound healing. Substances stored in dense granules are thrombocyte-activating factors. Platelets also contain lysosomal granules, which secrete acid hydrolases. Platelet activation results in growth factor release. Platelet growth factors include platelet-derived growth factor (PDGF), transforming growth factor  (TGF-), vascular endothelial growth factor (VEGF), epidermal growth factor (EGF) and insulin-like growth factor 1 (IGF-1) [10]. The functions of these growth factors are presented in Table 1 [10, 11]. It should be noted that the mechanism of action of platelet-rich plasma does not differ from the physiological healing process, but allows for obtaining higher concentrations of growth factors. As a result, the process of tissue regeneration is accelerated.
Recently, platelet-rich plasma therapy has been gaining in popularity. The number of reports concerning the effectiveness of PRP therapy is growing. These trials are mainly based on small groups of patients; case reports are also presented. However, there is still a dearth of randomised clinical trials with large groups of patients, even though this is the basis of evidence-based medicine (EBM). Meta-analyses of the data are also hindered due to the lack of standardisation of PRP preparation, the use of additional therapies (rehabilitation, drug therapy), differences in the anatomical structures examined and various methods of treatment efficacy assessment. Consequently, guidelines of PRP preparation should be developed and indications for its use should be established.
This paper presents a review of the literature concerning the use of platelet-rich plasma in orthopaedics and traumatology.

Use of platelet-rich plasma in enthesopathy and tendinopathy treatment

Tendon and enthesis disorders constitute a widespread problem commonly encountered by doctors. The disorders arise as a result of accumulating microinjuries caused by flexing of muscles and ligaments. Overload of these structures also leads to chronic osteoarthritis. In the first phase of the disease, elimination of the overload allows for effective tissue regeneration. Further overload leads to the degeneration and impairment of tissue repair mechanisms, resulting in chronic degenerative tendinopathy. Conservative treatment includes limb elevation, eccentric training or topical administration of steroids, but the effectiveness of these methods is negligible. Consequently, specialists search for new methods of treatment of tendinopathy and enthesopathy. Platelet-rich plasma therapy is one of these methods.
The use of platelet-rich plasma therapy has been gaining in popularity, and the number of reports concerning the effectiveness of PRP in the treatment of enthesopathy and tendinopathy has been increasing. The therapy is applied mainly in patients who do not respond to conservative treatment in order to avoid surgery and shorten the convalescence period.
Gautam et al. [12] compared the results of PRP and corticosteroid (CS) injections in the treatment of lateral epicondylitis (LE) in a randomised trial. A total of 30 patients were randomised to receive PRP or corticosteroid injections. The patients were assessed using a visual analogue scale (VAS) for pain, the Disabilities of the Arm, Shoulder and Hand (DASH) score, the Oxford Elbow Score, the modified Mayo Clinic performance index for the elbow (modified Mayo score) and hand grip strength. Ultrasound scans were performed to evaluate the tear at the common extensor origin, oedema at the common extensor origin, cortical erosion and thickness of the tendon. During a 6-month follow-up, the scores improved significantly in both the PRP and CS group. However, in the CS group, the scores peaked at 3 months and then decreased, indicating recurrence of symptoms in 46.7% of the CS patients. Another study carried out by Behera et al. [13] was a comparison of PRP injections versus bupivacaine injections for recalcitrant lateral epicondylar tendinopathy. The trial enrolled 25 patients whose condition was assessed with a VAS for pain, the modified Mayo clinic performance index for elbow (MMCPIE) and the Nirschl score for activity-related pain at 1, 3, 6 and 12 months. The study showed that after 1 month, the percentage of improvement was lower in the PRP than the bupivacaine group (17.7% vs. 26.5% in VAS for pain, 24% vs. 27.6% in MMCPIE score and 20.7% vs. 31.1% in Nirschl score). Different results showing better outcomes of PRP injections were achieved after 3, 6 and 12 months.
Kearney et al. [14] conducted a study which evaluated the differences between patients with Achilles tendinopathy treated with a PRP injection compared with an eccentric loading programme. A total of 20 patients were randomised to receive a PRP injection or an eccentric loading programme. The outcomes were measured with the Victorian Institute of Sport Assessment – Achilles questionnaire (VISA-A) at baseline, 6 weeks, 3 months and 6 months. The mean VISA-A score for the injection group was 76.0 (range: 58.3–93.7), and in the exercise group the value was 57.4 (range: 38.1–76.7). However, the authors point out that the outcome of this study is questionable as the study group was too small; consequently, the study should be repeated with a larger group of patients. The effectiveness of PRP in the treatment of Achilles tendinopathy was also presented in a clinical study carried out by de Vos et al. [15]. The tendon structure was evaluated by ultrasonographic tissue characterisation and colour Doppler ultrasound was used to measure the degree of neovascularisation. A significant improvement was found after 24 weeks both in the PRP group and the placebo group, but the between-group difference was not significant. It was concluded that injecting PRP in the treatment of chronic Achilles tendinopathy does not contribute to an improved tendon structure or alter the degree of neovascularisation. The treatment failure was probably caused by the fact that PRP was present at the site of the lesion for a shorter time as the fluid might have diffused rapidly out of the tendon due to the internal hydrostatic pressure. These data should be verified by further research.

Use of platelet-rich plasma in osteoarthritis treatment

Osteoarthritis (OA) is one of the most frequent dysfunctions of the musculoskeletal system. Many biological and mechanical factors interrupt the physiological process of cartilage and subchondral bone regeneration and cause joint damage [16]. The disorder is characterised by pain in the affected joint and limited mobility [17]. Neither conservative (exercise and lifestyle modification) nor pharmacological treatment is effective. The use of platelet-rich plasma may be an alternative method of osteoarthritis treatment.
The availability of data confirming the effectiveness of PRP therapy in the treatment of osteoarthritis is increasing. The results concern mainly the knee. Patel et al. [18] compared the outcomes of PRP therapy for knee osteoarthritis with placebo. A total of 78 patients (156 knees) with bilateral OA were divided randomly into three groups. Group A (52 knees) received a single injection of PRP, group B (50 knees) received 2 injections of PRP and group C (46 knees) received a single injection of normal saline. The condition of the patients was evaluated with the Western Ontario and McMaster Universities Osteoarthritis Index (WOMAC) questionnaire and a VAS scale for pain at baseline, 6 weeks, 3 months and 6 months after treatment. In group A, a statistically significant improvement was found in all WOMAC parameters (average total score at baseline of 49.86 vs. average total score at 6 months after treatment of 27.18). Similar results were observed in group B (average total score at baseline of 53.20 vs. final follow-up at 6 months after treatment of 30.48). Group C did not show any improvement.
Platelet-rich plasma therapy has been compared with different methods of osteoarthritis treatment. Angoorani et al. [19] conducted a trial which collated the effect of PRP with transcutaneous electrical nerve stimulation (TENS) and exercise in the treatment of patients with knee osteoarthritis. Fifty-four patients with knee OA were randomly assigned to two groups: group A (27 patients) received 2 injections of PRP 4 weeks apart, and group B (27 patients) received 10 sessions of TENS and exercise. Clinical outcomes were evaluated with the Knee Injury and Osteoarthritis Outcome Score (KOOS) questionnaire and a VAS scale. The results were better in group A than in group B. Battaglia et al. [20] found long-term advantages of PRP and hyaluronic acid therapy for hip osteoarthritis; the outcomes were similar in both groups. However, it should be noted that a significant improvement was observed within 3 months after the treatment. Despite a slightly progressive decrease during further follow-up, the final clinical scores remained higher compared with baseline, with no significant differences between PRP and hyaluronic acid.

Use of platelet-rich plasma in muscle and ligament injuries

Approximately 30% of injuries are associated with the muscular system, and muscle injuries are one of the most common types of sport-related trauma, causing 10–55% of all damage [21, 22]. Muscle injuries are becoming a global problem, and there is a need to invent new methods of tissue repair stimulation [23]. Platelet-rich plasma therapy is an example of a tissue repair method. Quarteiro et al. [24] evaluated the effect of PRP on the repair of muscle injuries in rats. The authors produced injuries in the gastrocnemius muscles of each hind limb of 30 rats. These injuries did not receive any treatment in 6 rats, while in 24 rats normal saline was injected into the injury site in the left leg and PRP was administered into the injury site in the right leg. Samples of the treated and untreated tissue were evaluated 7 and 21 days after the procedures. The quantity of collagen in the injury sites treated with PRP was significantly lower than that in the other injuries 7 days after the procedure. The collagen levels in both groups were equal on the 21st day. There was a significant increase in the quantity of collagen between the 7th and 21st day in the injuries treated with PRP. The inflammatory process was shown to be more intense in the injuries treated with PRP than in the injuries of the other treatment groups. The authors concluded that PRP has little influence on the primary steps of muscle tissue healing.
Apart from a large number of animal studies, clinical study results have also been presented. Jose Martinez-Zapata et al. [25] conducted a multicentre, randomised, double-blind clinical trial in 71 patients with muscle tears in the legs and haematoma. The haematoma was evacuated in all patients. Thirty-three patients were randomised to a single dose of autologous PRP and the other 38 patients to simulated PRP administration. The primary end-point of the study was the time to complete recovery of the muscle. The secondary end-points were pain, relapses, ultrasound parameters and adverse events. The time from the introduction of the treatment to complete recovery was 31.63 days in the PRP group and 38.43 days in the control group. The authors concluded that the PRP therapy did not significantly improve the time necessary to heal as compared with the control group. Pain decreased over time in both groups without statistical differences between them. Similar conclusions were drawn by Reurink et al. [26]. They carried out a trial in 80 patients who received two injections of PRP or isotonic saline placebo. The study results did not show any differences in the median time to recovery between the groups. On the other hand, Hamid et al. [27] achieved recovery in the PRP group 2 weeks earlier than in the other group, which is a significant difference.
The use of PRP in the treatment of ligament damage is mainly focused on the anterior cruciate ligament (ACL). Dhillon et al. [28] evaluated the effect of human ACL cell growth of 11 patients during ACL reconstruction surgery. The ACL remnants were collected, and the cells were isolated, identified and cultured and then divided into six groups. Groups A-D had fetal bovine serum (FBS) added to them along with different concentrations of PRP and platelet-poor plasma (PPP). Groups E and F received 5% and 10% PRP, respectively, but lacked FBS. The study showed that the addition of PRP increased the viability of ACL cells in 4 out of 11 donor samples and promoted cell proliferation in 8 out of 11 samples. The difference between the effectiveness of 5% and 10% PRP was not statistically significant. However, there was no statistically significant effect of either PRP or PPP on the prevention of cell death (apoptosis rate).
In vitro trial results are not correlated with clinical practice. In a study conducted by Komzák et al. [29], 20 patients underwent ACL reconstruction surgery with PRP application to the bone tunnel for a graft and to the articular cavity, while another 20 subjects had the same surgery without PRP administration. The patients were examined by MRI at 3 and 12 months after surgery, and the knee functional status was evaluated with scoring systems (Cincinnati score, IKDC score). Three months after surgery, bone swelling was found in 18 out of 20 patients in both the PRP and the control group. At 12 months, bone swelling was recorded in 7 out of 20 patients in the PRP group and in 9 patients from the control group. The mean Cincinnati score at 3 months was 72.7 in the PRP group and 73.4 in the control group. The functional score after 12 months improved to 97.5 in the PRP group and to 95.1 in the control group. The IKDC scores at 3 and 12 months were also similar in both groups. The outcomes led to the conclusion that the use of PRP in ACL reconstruction does not accelerate graft remodelling and bone ingrowth into the tendon. Similar conclusions were presented by Silva et al. [30]. Patients after ACL reconstruction surgery were divided into the PRP and non-PRP group and evaluated with MRI 3 months after the procedure. There were no significant differences between the PRP and non-PRP group.
Different study results were presented by Radice et al. [31]. They found that with the use of PRP gel, complete homogeneity of the ACL graft was seen earlier (179 days) as compared with the non-PRP gel group (369 days). These conclusions should be analysed in further studies comparing PRP therapy with PRP gel therapy in facilitating ligament injury healing.

Use of platelet-rich plasma in bone lesion treatment

The regenerative ability of bone is relatively efficient. Bone injuries are healed by bone union. This process is initiated by inflammation resulting from haematoma at the site of injury. Normal bone union requires meeting the criteria of the so-called Lynch triad. The Lynch triad consists of the following: a processable tissue matrix, live cells responsible for bone regeneration and signal particles of the healing process, which modulate the activity of inflammatory cells. The signal particles include growth factors, and platelet-rich plasma is a rich source of these molecules. The idea of using PRP in bone lesion treatment is based on the hypothesis that the administration of growth factors at the site of injury may initiate the regeneration process. Consequently, the number of clinical trials evaluating the use of PRP in the treatment of delayed long bone union is increasing.
The effectiveness of PRP therapy in the treatment of delayed bone union was assessed by Gołos et al. [32]. Their analysis encompassed 132 patients diagnosed with delayed bone union and treated with PRP. Bone union after PRP administration was found in 108 (81.8%) patients. The treatment was most effective in patients with delayed union of the proximal tibia, and the lowest efficacy was observed in subjects with delayed union of the proximal humeral bone. These study results confirmed the effectiveness of PRP therapy in the treatment of delayed union of long bones. Similar outcomes were described by Stanton [33], who achieved bone union in 90% of patients. Unlike these authors, Say et al. [34] did not achieve satisfactory outcomes (the efficacy was only 30%). Due to the contradictory study results, more trials should be conducted to confirm or refute the effectiveness of the therapy.

Antibacterial effect of platelet-rich plasma therapy

Bone lesion treatment is often complicated by bone infection. PRP gel therapy is also useful in this situation. Bielecki et al. [35] analysed the antibacterial effect of platelet-rich gel in vitro by using platelet-rich plasma samples from 20 volunteers. Susceptibility to platelet-rich gel was determined by the disc diffusion method. Antimicrobial activity was assessed by measuring the zones of inhibition. Platelet-rich gel inhibited the growth of Staphylococcus aureus and Escherichia coli. There was no activity against Klebsiella pneumoniae, Enterococcus faecalis or Pseudomonas aeruginosa. In addition, platelet-rich gel seemed to stimulate the in vitro growth of P. aeruginosa.
Promising study outcomes were described by Szypuła et al. [36]. They presented 4 case studies of patients suffering from chronic purulent inflammation of bone which could not be successfully treated with surgery or antibiotics. After the use of PRP, bone union was achieved in all patients and there were no signs of inflammation. According to the authors’ hypothesis, the effectiveness of this type of treatment results from platelet growth factor activity (particularly PDGF). Although the outcomes of PRP therapy in bone infection are very good, further research is necessary, especially with respect to the explanation of the mechanism of antibacterial effects of PRP.

Summary

Platelet-rich plasma therapy has been used in many fields of medicine, including orthopaedics and traumatology. The number of publications and reports evaluating the effectiveness of PRP therapy is constantly increasing. However, there are still few trials involving large treatment and control groups, and meta-analyses of the available data are difficult as the data are inhomogeneous. Further research should be conducted even if numerous separate studies show unsatisfactory results for particular disorders. Platelet-rich plasma preparations are not standardised; the treatment efficacy may be influenced by a number of factors which remain to be determined; new, more effective methods of treatment of many disorders are required due to the ever-increasing expectations of society; consequently, studies on PRP efficacy should continue and new indications should be established. The most important issue associated with PRP therapy is probably the preparation of international guidelines concerning the use of PRP in each indication and selection of the method of PRP preparation.

Conflict of interest

The authors declare no conflict of interest.

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Address for correspondence:

Andrzej Kotela
Department of Orthopaedics and Traumatology of Musculoskeletal System
1st Faculty of Medicine
Medical University of Warsaw
ul. Wołoska 137, 02-507 Warsaw, Poland
Phone: +48 661 166 440
E-mail: andrzejkotela@op.pl
Copyright: © 2016 Jan Kochanowski University in Kielce This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
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