Skip to main content
Intended for healthcare professionals
Restricted access
Research article
First published online November 4, 2010

Comparison of Growth Factor and Platelet Concentration From Commercial Platelet-Rich Plasma Separation Systems

Tiffany N. Castillo, Michael A. Pouliot, MD, Hyeon Joo Kim, PhD, and Jason L. Dragoo, MD [email protected]View all authors and affiliations
Volume 39, Issue 2
https://doi.org/10.1177/0363546510387517

Abstract

Background: Clinical studies claim that platelet-rich plasma (PRP) shortens recovery times because of its high concentration of growth factors that may enhance the tissue repair process. Most of these studies obtained PRP using different separation systems, and few analyzed the content of the PRP used as treatment.
Purpose: This study characterized the composition of single-donor PRP produced by 3 commercially available PRP separation systems.
Study Design: Controlled laboratory study.
Methods: Five healthy humans donated 100 mL of blood, which was processed to produce PRP using 3 PRP concentration systems (MTF Cascade, Arteriocyte Magellan, Biomet GPS III). Platelet, white blood cell (WBC), red blood cell, and fibrinogen concentrations were analyzed by automated systems in a clinical laboratory, whereas ELISA determined the concentrations of platelet-derived growth factor αβ and ββ (PDGF-αβ, PDGF-ββ), transforming growth factor β1 (TGF-β1), and vascular endothelial growth factor (VEGF).
Results: There was no significant difference in mean PRP platelet, red blood cell, active TGF-β1, or fibrinogen concentrations among PRP separation systems. There was a significant difference in platelet capture efficiency. The highest platelet capture efficiency was obtained with Cascade, which was comparable with Magellan but significantly higher than GPS III. There was a significant difference among all systems in the concentrations of WBC, PDGF-αβ, PDGF-ββ, and VEGF. The Cascade system concentrated leukocyte-poor PRP, compared with leukocyte-rich PRP from the GPS III and Magellan systems.
Conclusion: The GPS III and Magellan concentrate leukocyte-rich PRP, which results in increased concentrations of WBCs, PDGF-αβ, PDGF-ββ, and VEGF as compared with the leukocyte-poor PRP from Cascade. Overall, there was no significant difference among systems in the platelet concentration, red blood cell, active TGF-β1, or fibrinogen levels.
Clinical Relevance: Products from commercially available PRP separation systems produce differing concentrations of growth factors and WBCs. Further research is necessary to determine the clinical relevance of these findings.

Get full access to this article

View all access and purchase options for this article.

Get Access

References

1. Ahamed J, Burg N, Yoshinaga K, Janczak CA, Rifkin DB, Coller BS. In vitro and in vivo evidence for shear-induced activation of latent transforming growth factor-beta1. Blood. 2008;112(9):3650-3660.
Crossref
PubMed
ISI
Google Scholar
2. Anitua E, Andia I, Sanchez M, et al. Autologous preparations rich in growth factors promote proliferation and induce VEGF and HGF production by human tendon cells in culture. J Orthop Res. 2005;23(2):281-286.
Crossref
PubMed
ISI
Google Scholar
3. Berg U, Gustafsson T, Sundberg CJ, et al. Local changes in the insulin-like growth factor system in human skeletal muscle assessed by microdialysis and arterio-venous differences technique. Growth Horm IGF Res. 2006;16(4):217-223.
Crossref
PubMed
ISI
Google Scholar
4. Berghoff WJ, Pietrzak WS, Rhodes RD. Platelet-rich plasma application during closure following total knee arthroplasty. Orthopedics. 2006;29(7):590-598.
Crossref
PubMed
ISI
Google Scholar
5. Blobe GC, Schiemann WP, Lodish HF. Role of transforming growth factor beta in human disease. N Engl J Med. 2000;342(18):1350-1358.
Crossref
PubMed
ISI
Google Scholar
6. Creaney L, Hamilton B. Growth factor delivery methods in the management of sports injuries: the state of play. Br J Sports Med. 2008;42(5):314-320.
Crossref
PubMed
ISI
Google Scholar
7. De Carli A, Volpi P, Pelosini I, et al. New therapeutic approaches for management of sport-induced muscle strains. Adv Ther. 2009;26(12):1072-1083.
Crossref
PubMed
ISI
Google Scholar
8. de Mos M, van der Windt AE, Jahr H, et al. Can platelet-rich plasma enhance tendon repair? A cell culture study. Am J Sports Med. 2008;36(6):1171-1178.
Crossref
PubMed
ISI
Google Scholar
9. de Vos RJ, Weir A, van Schie HT, et al. Platelet-rich plasma injection for chronic Achilles tendinopathy: a randomized controlled trial. JAMA. 13;303(2):144-149.
Crossref
Google Scholar
10. Dohan Ehrenfest DM, Rasmusson L, Albrektsson T. Classification of platelet concentrates: from pure platelet-rich plasma (P-PRP) to leukocyte- and platelet-rich fibrin (L-PRF). Trends Biotechnol. 2009;27(3):158-167.
Crossref
PubMed
ISI
Google Scholar
11. Ekdahl M, Wang JH, Ronga M, Fu FH. Graft healing in anterior cruciate ligament reconstruction. Knee Surg Sports Traumatol Arthrosc. 2008;16(10):935-947.
Crossref
PubMed
ISI
Google Scholar
12. Eppley BL, Woodell JE, Higgins J. Platelet quantification and growth factor analysis from platelet-rich plasma: implications for wound healing. Plast Reconstr Surg. 2004;114(6):1502-1508.
Crossref
PubMed
ISI
Google Scholar
13. Everts PA, Brown Mahoney C, Hoffmann JJ, et al. Platelet-rich plasma preparation using three devices: implications for platelet activation and platelet growth factor release. Growth Factors. 2006;24(3):165-171.
Crossref
PubMed
ISI
Google Scholar
14. Gandhi A, Doumas C, O’Connor JP, Parsons JR, Lin SS. The effects of local platelet rich plasma delivery on diabetic fracture healing. Bone. 2006;38(4):540-546.
Crossref
PubMed
ISI
Google Scholar
15. Grageda E. Platelet-rich plasma and bone graft materials: a review and a standardized research protocol. Implant Dent. 2004;13(4):301-309.
Crossref
PubMed
Google Scholar
16. Hall MP, Band PA, Meislin RJ, Jazrawi LM, Cardone DA. Platelet-rich plasma: current concepts and application in sports medicine. J Am Acad Orthop Surg. 2009;17(10):602-608.
Crossref
PubMed
ISI
Google Scholar
17. Hammond JW, Hinton RY, Curl LA, Muriel JM, Lovering RM. Use of autologous platelet-rich plasma to treat muscle strain injuries. Am J Sports Med. 2009;37(6):1135-1142.
Crossref
PubMed
ISI
Google Scholar
18. Heldin CH, Eriksson U, Ostman A. New members of the platelet-derived growth factor family of mitogens. Arch Biochem Biophys. 2002;398(2):284-290.
Crossref
PubMed
ISI
Google Scholar
19. Kevy SV, Jacobson MS. Comparison of methods for point of care preparation of autologous platelet gel. J Extra Corpor Technol. 2004;36(1):28-35.
PubMed
Google Scholar
20. Man D, Plosker H, Winland-Brown JE. The use of autologous platelet-rich plasma (platelet gel) and autologous platelet-poor plasma (fibrin glue) in cosmetic surgery. Plast Reconstr Surg. 2001;107(1):229-237.
Crossref
PubMed
ISI
Google Scholar
21. Marlovits S, Mousavi M, Gabler C, Erdos J, Vecsei V. A new simplified technique for producing platelet-rich plasma: a short technical note. Eur Spine J. 2004;13(suppl 1):S102-S106.
Crossref
PubMed
ISI
Google Scholar
22. Marx RE. Platelet-rich plasma: evidence to support its use. J Oral Maxillofac Surg. 2004;62(4):489-496.
Crossref
PubMed
ISI
Google Scholar
23. Matras H. [Effect of various fibrin preparations on reimplantations in the rat skin]. Osterr Z Stomatol. 1970;67(9):338-359.
PubMed
Google Scholar
24. Menetrey J, Kasemkijwattana C, Day CS, et al. Growth factors improve muscle healing in vivo. J Bone Joint Surg Br. 2000;82(1):131-137.
Crossref
PubMed
Google Scholar
25. Moojen DJ, Everts PA, Schure RM, et al. Antimicrobial activity of platelet-leukocyte gel against Staphylococcus aureus. J Orthop Res. 2008;26(3):404-410.
Crossref
PubMed
ISI
Google Scholar
26. Radice F, Yanez R, Gutierrez V, Rosales J, Pinedo M, Coda S. Comparison of magnetic resonance imaging findings in anterior cruciate ligament grafts with and without autologous platelet-derived growth factors. Arthroscopy. 2010;26(1):50-57.
Crossref
PubMed
ISI
Google Scholar
27. Sanchez M, Anitua E, Azofra J, Andia I, Padilla S, Mujika I. Comparison of surgically repaired Achilles tendon tears using platelet-rich fibrin matrices. Am J Sports Med. 2007;35(2):245-251.
Crossref
PubMed
ISI
Google Scholar
28. Sanchez M, Anitua E, Cugat R, et al. Nonunions treated with autologous preparation rich in growth factors. J Orthop Trauma. 2009;23(1):52-59.
Crossref
PubMed
ISI
Google Scholar
29. Silva A, Sampaio R. Anatomic ACL reconstruction: does the platelet-rich plasma accelerate tendon healing? Knee Surg Sports Traumatol Arthrosc. 2009;17(6):676-682.
Crossref
PubMed
ISI
Google Scholar
30. Slater M, Patava J, Kingham K, Mason RS. Involvement of platelets in stimulating osteogenic activity. J Orthop Res. 1995;13(5):655-663.
Crossref
PubMed
ISI
Google Scholar
31. Tamimi FM, Montalvo S, Tresguerres I, Blanco Jerez L. A comparative study of 2 methods for obtaining platelet-rich plasma. J Oral Maxillofac Surg. 2007;65(6):1084-1093.
Crossref
PubMed
ISI
Google Scholar
32. Weibrich G, Kleis WK, Hafner G, Hitzler WE. Growth factor levels in platelet-rich plasma and correlations with donor age, sex, and platelet count. J Craniomaxillofac Surg. 2002;30(2):97-102.
Crossref
PubMed
ISI
Google Scholar
33. Werner S, Grose R. Regulation of wound healing by growth factors and cytokines. Physiol Rev. 2003;83(3):835-870.
Crossref
PubMed
ISI
Google Scholar
34. Werther K, Christensen IJ, Nielsen HJ. Determination of vascular endothelial growth factor (VEGF) in circulating blood: significance of VEGF in various leukocytes and platelets. Scand J Clin Lab Invest. 2002;62(5):343-350.
Crossref
PubMed
ISI
Google Scholar
35. Whitman DH, Berry RL, Green DM. Platelet gel: an autologous alternative to fibrin glue with applications in oral and maxillofacial surgery. J Oral Maxillofac Surg. 1997;55(11):1294-1299.
Crossref
PubMed
ISI
Google Scholar
36. Zimmermann R, Jakubietz R, Jakubietz M, et al. Different preparation methods to obtain platelet components as a source of growth factors for local application. Transfusion. 2001;41(10):1217-1224.
Crossref
PubMed
ISI
Google Scholar

Cite article

Cite article

Cite article

OR

Download to reference manager

If you have citation software installed, you can download article citation data to the citation manager of your choice

Share options

Share

Share this article

Share with email
EMAIL ARTICLE LINK
Share on social media

Share access to this article

Sharing links are not relevant where the article is open access and not available if you do not have a subscription.

For more information view the Sage Journals article sharing page.

Information, rights and permissions

Information

Published In

Volume 39, Issue 2
Pages: 266 - 271
Article first published online: November 4, 2010
Issue published: February 2011

Keywords

  1. platelet-rich plasma
  2. growth factors
  3. platelet-rich plasma separation system

Rights and permissions

© 2011 The Author(s).
PubMed: 21051428

Authors

Affiliations

Tiffany N. Castillo
Department of Orthopaedic Surgery, Stanford University, Palo Alto, California
View all articles by this author
Michael A. Pouliot, MD
Department of Orthopaedic Surgery, Stanford University, Palo Alto, California
View all articles by this author
Hyeon Joo Kim, PhD
Department of Orthopaedic Surgery, Stanford University, Palo Alto, California
View all articles by this author
Jason L. Dragoo, MD
Department of Orthopaedic Surgery, Stanford University, Palo Alto, California
[email protected]
View all articles by this author
Investigation performed at Stanford University, Department of Orthopaedic Surgery, Palo Alto, California

Notes

Jason L. Dragoo, MD, Assistant Professor, Department of Orthopaedic Surgery, Stanford University, 450 Broadway, MC 6342, Redwood City, CA 94063 (e-mail: [email protected]).

Metrics and citations

Metrics

Journals metrics

This article was published in The American Journal of Sports Medicine.

VIEW ALL JOURNAL METRICS

Article usage*

Total views and downloads: 1664

*Article usage tracking started in December 2016

Altmetric

See the impact this article is making through the number of times it’s been read, and the Altmetric Score.
Learn more about the Altmetric Scores


Articles citing this one

Receive email alerts when this article is cited

Web of Science: 362 view articles Opens in new tab

Crossref: 361

  1. Platelet-rich Plasma Superiority over Hyaluronic Acid as a Conservativ...
    Go to citation Crossref Google Scholar
  2. ОБЗОР СОХРАНЕНИЯ ОБЪЕМА АЛВЕОЛЯРНОЙ КОСТИ ПОСЛЕ УДАЛЕНИЯ ЗУБА
    Go to citation Crossref Google Scholar
  3. An Overview of PRP-Delivering Scaffolds for Bone and Cartilage Tissue ...
    Go to citation Crossref Google Scholar
  4. Platelet‐rich plasma does not accelerate the healing of damaged muscle...
    Go to citation Crossref Google Scholar
  5. THE INTRA-ARTICULAR PURE-PLATELET RICH PLASMA AS A DISEASE-MODIFYING T...
    Go to citation Crossref Google Scholar
  6. Optimizing Platelet-Rich Plasma: Spin Time and Sample Source
    Go to citation Crossref Google Scholar
  7. SAS-PRP Study: A Real-Life Satisfaction Assessment in Patients with Ca...
    Go to citation Crossref Google Scholar
  8. Platelet-Rich Plasma Injections for the Treatment of Ankle Osteoarthri...
    Go to citation Crossref Google ScholarPub Med
  9. Platelet-rich plasma in the pathologic processes of tendinopathy: a re...
    Go to citation Crossref Google Scholar
  10. Influential Studies in Orthopaedic Platelet-Rich Plasma Research Are R...
    Go to citation Crossref Google Scholar
  11. Effect of Autologous Conditioned Plasma Injections in Patients With Kn...
    Go to citation Crossref Google Scholar
  12. The Role of Platelet-Rich Plasma Therapy in Joint Arthroplasty A Mini-...
    Go to citation Crossref Google Scholar
  13. Comparison of the effects of platelet-rich plasma and corticosteroid i...
    Go to citation Crossref Google Scholar
  14. Composition of Platelet-Rich Plasma Prepared From Knee Osteoarthritic ...
    Go to citation Crossref Google Scholar
  15. Clinical Efficacy of Intra‐Articular Injection with P‐PR...
    Go to citation Crossref Google Scholar
  16. Global research trends on platelet-rich plasma for tendon and ligament...
    Go to citation Crossref Google Scholar
  17. Advances in the Clinical Application of Platelet-Rich Plasma in the Fo...
    Go to citation Crossref Google Scholar
  18. Blood Products
    Go to citation Crossref Google Scholar
  19. The Influence of Body Mass Index on Growth Factor Composition in the P...
    Go to citation Crossref Google Scholar
  20. Pure Platelet and Leukocyte–Platelet-Rich Plasma for Regenerative Medi...
    Go to citation Crossref Google Scholar
  21. Platelet-rich Plasma in Patients with Symptomatic Osteoarthritis Knee:...
    Go to citation Crossref Google Scholar
  22. Creating 2 Unique Platelet-rich Plasma Products From a Single Batch of...
    Go to citation Crossref Google Scholar
  23. Leukocyte and Platelet-Rich Plasma (L-PRP) in Tendon Models: A Systema...
    Go to citation Crossref Google Scholar
  24. Intra-articular injections of platelet-rich plasma decrease pain and i...
    Go to citation Crossref Google Scholar
  25. A Preclinical Study of Bone Marrow Buffy Coat Components and Cartilage...
    Go to citation Crossref Google Scholar
  26. Platelet-rich plasma injection for acute Achilles tendon rupture
    Go to citation Crossref Google Scholar
  27. Current Trends in Orthobiologics: An 11-Year Review of the Orthopaedic...
    Go to citation Crossref Google ScholarPub Med
  28. Orthobiologics in orthopedic applications: a report from the TMI Havem...
    Go to citation Crossref Google Scholar
  29. Optimization of a Two-Step Centrifugation Protocol for Bovine Platelet...
    Go to citation Crossref Google Scholar
  30. Leukocyte-Rich Platelet-Rich Plasma as an Effective Source of Molecule...
    Go to citation Crossref Google Scholar
  31. Von der Grundlagenforschung zur täglichen Praxis: „Platelet-rich plasm...
    Go to citation Crossref Google Scholar
  32. Injection of Leukocyte-Poor Platelet-Rich Plasma for Moderate-to-Large...
    Go to citation Crossref Google Scholar
  33. Does Bone Marrow Edema Influence the Clinical Results of Intra-Articul...
    Go to citation Crossref Google Scholar
  34. Platelet-Rich Plasma as an Orthobiologic
    Go to citation Crossref Google Scholar
  35. High-Throughput Proteomic Analysis of Human Dermal Fibroblast Response...
    Go to citation Crossref Google Scholar
  36. Content of blood cell components, inflammatory cytokines and growth fa...
    Go to citation Crossref Google Scholar
  37. Progress of Platelet Derivatives for Cartilage Tissue Engineering
    Go to citation Crossref Google Scholar
  38. The effect of the anticoagulant on the cellular composition and growth...
    Go to citation Crossref Google Scholar
  39. Autologous Fibrin Sealants Have Comparable Graft Fixation to an Alloge...
    Go to citation Crossref Google Scholar
  40. Assessment of Characteristics and Methodological Quality of the Top 50...
    Go to citation Crossref Google ScholarPub Med
  41. Evaluation of a Standardized Protocol for Plasma Rich in Growth Factor...
    Go to citation Crossref Google Scholar
  42. Influence of Sexual Dimorphism, Aging, and Differential Cell Capture E...
    Go to citation Crossref Google Scholar
  43. Cellular components and TGF-β1 content of a closed Tube system for Pla...
    Go to citation Crossref Google Scholar
  44. Age‐based inter‐subject variability in platelet and white blood cell c...
    Go to citation Crossref Google Scholar
  45. Platelet-rich plasma treatment alleviates osteoarthritis-related pain,...
    Go to citation Crossref Google Scholar
  46. Progress in the use of plasma rich in growth factors in ophthalmology:...
    Go to citation Crossref Google Scholar
  47. How to Manage the Active Patient with Osteoarthritis:
    Go to citation Crossref Google Scholar
  48. Effectiveness of Hematoma Aspiration and Platelet-rich Plasma Muscle I...
    Go to citation Crossref Google Scholar
  49. A Unified Platelet-rich Plasma Preparation Protocol Using a Customizab...
    Go to citation Crossref Google Scholar
  50. No Effect of Platelet-Rich Plasma Injections as an Adjuvant to Autolog...
    Go to citation Crossref Google ScholarPub Med
  51. Platelet-Rich Plasma Does Not Inhibit Inflammation or Promote Regenera...
    Go to citation Crossref Google ScholarPub Med
  52. Method to obtain PRP and L-PRP for the use in routine medical practice...
    Go to citation Crossref Google Scholar
  53. Research trends of platelet-rich plasma application in orthopaedics fr...
    Go to citation Crossref Google Scholar
  54. Effect of Platelet-Rich Plasma Injections vs Placebo on Ankle Symptoms...
    Go to citation Crossref Google Scholar
  55. Food and Drug Administration’s Position on Commonly Injected Biologic ...
    Go to citation Crossref Google ScholarPub Med
  56. Effect of Leukocyte-Platelet Rich Fibrin (L-PRF) on Tissue Regeneratio...
    Go to citation Crossref Google Scholar
  57. New design to remove leukocytes from platelet-rich plasma (PRP) based ...
    Go to citation Crossref Google Scholar
  58. The Effect of a Single Freeze–Thaw Cycle on Matrix Metalloproteinases ...
    Go to citation Crossref Google Scholar
  59. The platelet-rich plasma lysate use in the treatment of persistent epi...
    Go to citation Crossref Google Scholar
  60. ICRS virtual convention 2021: Orthoregenerative therapy from basic sci...
    Go to citation Crossref Google Scholar
  61. Time-Dependent Cytokine-Release of Platelet-Rich Plasma in 3-Chamber C...
    Go to citation Crossref Google Scholar
  62. Apheresis Platelet Rich-Plasma for Regenerative Medicine: An In Vitro ...
    Go to citation Crossref Google Scholar
  63. Reparative and Maladaptive Inflammation in Tendon Healing
    Go to citation Crossref Google Scholar
  64. DOES THE PLATELET CONCENTRATION IN PLATELET RICH PLASMA INFLUENCE THE ...
    Go to citation Crossref Google Scholar
  65. Biologic therapies for foot and ankle injuries
    Go to citation Crossref Google Scholar
  66. Efficacy of Intraoperative Platelet-Rich Plasma Augmentation and Posto...
    Go to citation Crossref Google ScholarPub Med
  67. Commercial blood cell separation systems versus tube centrifugation me...
    Go to citation Crossref Google Scholar
  68. Platlet-Rich Plasma – Review of Literature
    Go to citation Crossref Google Scholar
  69. Emerging Biological Treatment Methods for Ankle Joint and Soft Tissue ...
    Go to citation Crossref Google Scholar
  70. Effect of Platelet-Rich Plasma on M1/M2 Macrophage Polarization
    Go to citation Crossref Google Scholar
  71. Technical and biological review of authorized medical devices for plat...
    Go to citation Crossref Google Scholar
  72. Characteristics of L-PRP preparations for treating Achilles tendon rup...
    Go to citation Crossref Google Scholar
  73. Clinical Efficacy of Platelet-Rich Plasma Injection and Its Associatio...
    Go to citation Crossref Google ScholarPub Med
  74. Biology of Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  75. How much platelet-rich plasma can be soak-loaded onto beta-tricalcium ...
    Go to citation Crossref Google Scholar
  76. Factors affecting the quantity and quality of platelet-rich plasma and...
    Go to citation Crossref Google Scholar
  77. Platelet-Rich Plasma versus Corticosteroid Injection for the Treatment...
    Go to citation Crossref Google Scholar
  78. Technical Procedures for Preparation and Administration of Platelet-Ri...
    Go to citation Crossref Google Scholar
  79. Biologics
    Go to citation Crossref Google Scholar
  80. Efficacy of platelet-rich plasma as an adjuvant to surgical carpal lig...
    Go to citation Crossref Google Scholar
  81. Platelet-rich plasma for the treatment of knee osteoarthritis: an expe...
    Go to citation Crossref Google Scholar
  82. Parecoxib alleviates the inflammatory effect of leukocyte-rich platele...
    Go to citation Crossref Google Scholar
  83. Pure platelet-rich plasma facilitates the repair of damaged cartilage ...
    Go to citation Crossref Google Scholar
  84. High Intensity Interval Exercise Increases Platelet and Transforming G...
    Go to citation Crossref Google Scholar
  85. The Stryker Regenkit PRP Kit Does Not Concentrate Canine Platelets
    Go to citation Crossref Google Scholar
  86. Enhanced In Vivo Vascularization of 3D‐Printed Cell Encapsulation Devi...
    Go to citation Crossref Google Scholar
  87. Platelet-Rich Plasma Combined with Alendronate Reduces Pain and Inflam...
    Go to citation Crossref Google Scholar
  88. Tratamiento ortobiológico con plasma rico en plaquetas. Revisión siste...
    Go to citation Crossref Google Scholar
  89. Rationale for the Use of Orthobiologics in Sports Medicine
    Go to citation Crossref Google Scholar
  90. Validation and Characterization of Platelet-Rich Plasma in the Feline:...
    Go to citation Crossref Google Scholar
  91. Efficacy of a Semi Automated Commercial Closed System for Autologous L...
    Go to citation Crossref Google Scholar
  92. Photoaging Skin Therapy with PRP and ADSC: A Comparative Study
    Go to citation Crossref Google Scholar
  93. Platelet yield and yield consistency for six single-spin methods of pl...
    Go to citation Crossref Google Scholar
  94. Exosomes Isolated From Platelet-Rich Plasma and Mesenchymal Stem Cells...
    Go to citation Crossref Google ScholarPub Med
  95. Patient-Perceived Recovery and Outcomes after Bipolar Radiofrequency C...
    Go to citation Crossref Google Scholar
  96. Quantification of Growth Factors and Fibronectin in Diverse Preparatio...
    Go to citation Crossref Google Scholar
  97. Platelet and Leukocyte Concentration in Equine Autologous Conditioned ...
    Go to citation Crossref Google Scholar
  98. The effect of perioperative platelet-rich plasma injections on postope...
    Go to citation Crossref Google Scholar
  99. Intratendon delivery of leukocyte‐rich platelet‐rich plasma at early s...
    Go to citation Crossref Google Scholar
  100. Ensayo clínico fase III para evaluar la eficacia y seguridad del uso d...
    Go to citation Crossref Google Scholar
  101. Randomized, double-blind, controlled trial, phase III, to evaluate the...
    Go to citation Crossref Google Scholar
  102. Growth factor concentrations in platelet‐rich plasma for androgenetic ...
    Go to citation Crossref Google Scholar
  103. Platelet Concentrates in Musculoskeletal Medicine
    Go to citation Crossref Google Scholar
  104. Platelet-Rich Plasma for Sport-Active Patients with Knee Osteoarthriti...
    Go to citation Crossref Google Scholar
  105. The Future of Regenerative Medicine
    Go to citation Crossref Google Scholar
  106. Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  107. The Role of Orthobiologics in the Management of Tendon and Fascia Inju...
    Go to citation Crossref Google Scholar
  108. The Role of Orthobiologics in the Management of Cartilage and Meniscal...
    Go to citation Crossref Google Scholar
  109. Platelet Rich Plasma: Preparation Methods
    Go to citation Crossref Google Scholar
  110. No effect of platelet-rich plasma as adjuvant to bone marrow stimulati...
    Go to citation Crossref Google Scholar
  111. Management of osteoarthritis - biological approaches: current concepts
    Go to citation Crossref Google Scholar
  112. Comparison of platelet-rich plasma prepared using two methods: Manual ...
    Go to citation Crossref Google Scholar
  113. Glenohumeral Osteoarthritis: The Role for Orthobiologic Therapies
    Go to citation Crossref Google Scholar
  114. In vitro effect of autologous platelet‐rich plasma on H ...
    Go to citation Crossref Google Scholar
  115. CGF treatment of leg ulcers: A randomized controlled trial
    Go to citation Crossref Google Scholar
  116. Growth factor levels in leukocyte-poor platelet-rich plasma and correl...
    Go to citation Crossref Google Scholar
  117. Optimization of leukocyte-poor platelet-rich plasma preparation: a val...
    Go to citation Crossref Google Scholar
  118. Advances in surgical applications of growth factors for wound healing
    Go to citation Crossref Google Scholar
  119. Platelet rich plasma injection for acute Achilles tendon rupture: PATH...
    Go to citation Crossref Google Scholar
  120. The clot thickens: Autologous and allogeneic fibrin sealants are mecha...
    Go to citation Crossref Google Scholar
  121. Variability of the Composition of Growth Factors and Cytokines in Plat...
    Go to citation Crossref Google Scholar
  122. Platelet-Rich Plasma as a Treatment for Androgenetic Alopecia
    Go to citation Crossref Google Scholar
  123. Multiple platelet-rich plasma preparations can solubilize freeze-dried...
    Go to citation Crossref Google Scholar
  124. The Clinical Use of Biologics in the Knee Lesions: Does the Patient Be...
    Go to citation Crossref Google Scholar
  125. The Impact of Duration and Force of Centrifugation on Platelet Content...
    Go to citation Crossref Google Scholar
  126. The Effectiveness of Autologous Platelet-Rich Plasma for Osteoarthriti...
    Go to citation Crossref Google Scholar
  127. Platelet‐Rich Plasma (PRP) From Older Males With Knee Osteoarthritis D...
    Go to citation Crossref Google Scholar
  128. Use of a high platelet-to-RBC ratio of 2:1 is more effective in correc...
    Go to citation Crossref Google Scholar
  129. Review of concentration yields in commercially available platelet-rich...
    Go to citation Crossref Google Scholar
  130. Minimally invasive endoscopic maxillary sinus lifting and immediate im...
    Go to citation Crossref Google Scholar
  131. Evaluating strategies and outcomes following rotator cuff tears
    Go to citation Crossref Google Scholar
  132. Nonoperative Treatment of Rotator Cuff Disease With Platelet-Rich Plas...
    Go to citation Crossref Google Scholar
  133. Platelet-Rich Plasma Use in Musculoskeletal Disorders
    Go to citation Crossref Google Scholar
  134. Cellular Components and Growth Factor Content of Platelet-Rich Plasma ...
    Go to citation Crossref Google ScholarPub Med
  135. Platelet-Rich Fibrin Scaffolds for Cartilage and Tendon Regenerative M...
    Go to citation Crossref Google Scholar
  136. An important and overlooked parameter in platelet rich plasma preparat...
    Go to citation Crossref Google Scholar
  137. EVALUATION OF CENTRIFUGING REGIMES FOR THE PURPOSE OF OPTIMIZING THE P...
    Go to citation Crossref Google Scholar
  138. Platelet-Rich Plasma Promotes Migration, Proliferation, and the Gene E...
    Go to citation Crossref Google ScholarPub Med
  139. Comparative study of different anticoagulants and coagulants in the ev...
    Go to citation Crossref Google Scholar
  140. Single Injection of High Volume of Autologous Pure PRP Provides a Sign...
    Go to citation Crossref Google Scholar
  141. The Role of Orthobiologics in the Management of Osteoarthritis and Foc...
    Go to citation Crossref Google Scholar
  142. Clinical findings, synovial fluid cytology and growth factor concentra...
    Go to citation Crossref Google Scholar
  143. Concentrations of Blood Components in Commercial Platelet-Rich Plasma ...
    Go to citation Crossref Google ScholarPub Med
  144. Platelet rich plasma for photodamaged skin: A pilot study
    Go to citation Crossref Google Scholar
  145. Optimizing Clinical Use of Biologics in Orthopaedic Surgery: Consensus...
    Go to citation Crossref Google Scholar
  146. Platelet-rich plasma in osteoarthritis treatment: review of current ev...
    Go to citation Crossref Google ScholarPub Med
  147. Eye Platelet-Rich Plasma (E-PRP) for Corneal Regeneration
    Go to citation Crossref Google Scholar
  148. The Role of Platelet-Rich Plasma and Growth Factors in Rotator Cuff Re...
    Go to citation Crossref Google Scholar
  149. Biologics in Sports Medicine—Introduction
    Go to citation Crossref Google Scholar
  150. Exercise-Mobilized Platelet-Rich Plasma: Short-Term Exercise Increases...
    Go to citation Crossref Google Scholar
  151. The Influence of Naproxen on Biological Factors in Leukocyte-Rich Plat...
    Go to citation Crossref Google Scholar
  152. Editorial Commentary: Platelet-Rich Plasma Details Are Critical to Out...
    Go to citation Crossref Google Scholar
  153. Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  154. Ortho-Biologics for Osteoarthritis
    Go to citation Crossref Google Scholar
  155. Current Updates in Treatment of Osteochondral Lesions of the Talus
    Go to citation Crossref Google Scholar
  156. Platelet-Rich Plasma for Degenerative Knee Joints: What is the Evidenc...
    Go to citation Crossref Google Scholar
  157. The Economics and Regulation of PRP in the Evolving Field of Orthopedi...
    Go to citation Crossref Google Scholar
  158. Platelet-Rich Plasma and Cartilage Repair
    Go to citation Crossref Google Scholar
  159. Platelet-rich plasma in the foot and ankle
    Go to citation Crossref Google Scholar
  160. Current Clinical Recommendations for Use of Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  161. The efficacy and safety of platelet-rich fibrin for rotator cuff tears...
    Go to citation Crossref Google Scholar
  162. Biologics in orthopaedics
    Go to citation Crossref Google Scholar
  163. Development and evaluation of a spray applicator for platelet-rich pla...
    Go to citation Crossref Google Scholar
  164. Lasers, Microneedling, and Platelet-Rich Plasma for Skin Rejuvenation ...
    Go to citation Crossref Google Scholar
  165. Platelet-Rich Plasma for Hair Loss
    Go to citation Crossref Google Scholar
  166. Regarding “Meta-analysis Comparing Autologous Blood-Derived Products (...
    Go to citation Crossref Google Scholar
  167. Platelet-rich plasma in fibrin matrix to augment rotator cuff repair: ...
    Go to citation Crossref Google Scholar
  168. Sustained or higher levels of growth factors in platelet-rich plasma d...
    Go to citation Crossref Google Scholar
  169. Treatment of the Shoulder Impingement Syndrome with PRP Injection
    Go to citation Crossref Google Scholar
  170. Role of White Blood Cells in Blood- and Bone Marrow-Based Autologous T...
    Go to citation Crossref Google Scholar
  171. Effect of Intraoperative Platelet-Rich Plasma Treatment on Postoperati...
    Go to citation Crossref Google ScholarPub Med
  172. Platelet-Rich Plasma and Hyaluronic Acid Are Not Synergistic When Used...
    Go to citation Crossref Google ScholarPub Med
  173. Clinical Efficacy of Platelet-Rich Plasma in the Treatment of Neurotro...
    Go to citation Crossref Google Scholar
  174. Biological Treatment for Osteoarthritis of the Knee: Moving from Bench...
    Go to citation Crossref Google Scholar
  175. Injection Therapies for Rotator Cuff Disease
    Go to citation Crossref Google Scholar
  176. Management of Rotator Cuff Injuries in the Elite Athlete
    Go to citation Crossref Google Scholar
  177. Comparative Analysis of Cellular and Growth Factor Composition in Bone...
    Go to citation Crossref Google Scholar
  178. Men and Women Differ in the Biochemical Composition of Platelet-Rich P...
    Go to citation Crossref Google ScholarPub Med
  179. Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  180. PRP Therapy
    Go to citation Crossref Google Scholar
  181. Marrow Stimulation and Augmentation
    Go to citation Crossref Google Scholar
  182. Does Platelet-Rich Plasma Lead to Earlier Return to Sport When Compare...
    Go to citation Crossref Google Scholar
  183. The effect of corticosteroid versus platelet-rich plasma injection the...
    Go to citation Crossref Google Scholar
  184. Chitosan inhibits platelet-mediated clot retraction, increases platele...
    Go to citation Crossref Google Scholar
  185. Comparative Analysis of Different Platelet Lysates and Platelet Rich P...
    Go to citation Crossref Google Scholar
  186. Optimisation of a double-centrifugation method for preparation of cani...
    Go to citation Crossref Google Scholar
  187. A Systematic Review of Autologous Platelet-Rich Plasma and Fat Graft P...
    Go to citation Crossref Google Scholar
  188. Current perspectives on biological approaches for osteoarthritis
    Go to citation Crossref Google Scholar
  189. Sustained release of multicomponent platelet‐rich plasma proteins from...
    Go to citation Crossref Google Scholar
  190. Leukocyte-reduced platelet-rich plasma stimulates the in vitro prolife...
    Go to citation Crossref Google Scholar
  191. Theoretical prediction and validation of cell recovery rates in prepar...
    Go to citation Crossref Google Scholar
  192. Platelet-Rich Plasma for Primary Treatment of Partial Ulnar Collateral...
    Go to citation Crossref Google ScholarPub Med
  193. The combined use of ozone therapy and autologous platelet-rich plasma ...
    Go to citation Crossref Google Scholar
  194. A Call for Standardization in Platelet-Rich Plasma Preparation Protoco...
    Go to citation Crossref Google Scholar
  195. Platelet rich plasma for treatment of non-scarring hair loss: systemat...
    Go to citation Crossref Google Scholar
  196. Erythrocyte sedimentation rate and fibrinogen concentration of whole b...
    Go to citation Crossref Google Scholar
  197. Optimization of pure platelet-rich plasma preparation: A comparative s...
    Go to citation Crossref Google Scholar
  198. Platelet-Rich Plasma in Orthopaedic Surgery
    Go to citation Crossref Google Scholar
  199. Intratendon Delivery of Leukocyte-Poor Platelet-Rich Plasma Improves H...
    Go to citation Crossref Google ScholarPub Med
  200. Platelet Derived Biomaterials for Therapeutic Use: Review of Technical...
    Go to citation Crossref Google Scholar
  201. Evaluation of Platelet-Rich Plasma and Neutrophil Antimicrobial Extrac...
    Go to citation Crossref Google Scholar
  202. Autologous Pure Platelet-Rich Plasma Dermal Injections for Facial Skin...
    Go to citation Crossref Google Scholar
  203. Minimum Information for Studies Evaluating Biologics in Orthopaedics (...
    Go to citation Crossref Google Scholar
  204. Need for Proper Classification of PRP: Letter to the Editor
    Go to citation Crossref Google ScholarPub Med
  205. Comparative evaluation of the effects of platelet-rich plasma formulat...
    Go to citation Crossref Google Scholar
  206. Platelet-rich plasma for tissue regeneration can be stored at room tem...
    Go to citation Crossref Google Scholar
  207. Platelet-Rich Plasma Powder: A New Preparation Method for the Standard...
    Go to citation Crossref Google ScholarPub Med
  208. Platelet-Rich Plasma: Formulations, Preparations, Constituents, and Th...
    Go to citation Crossref Google Scholar
  209. Plasma rico em plaquetas: estudo comparativo entre a dupla centrifugaç...
    Go to citation Crossref Google Scholar
  210. Growth Factors in the Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  211. Commercial Separation Systems Designed for Preparation of Platelet-Ric...
    Go to citation Crossref Google ScholarPub Med
  212. Analysis of Platelet-Rich Plasma Extraction...
    Go to citation Crossref Google ScholarPub Med
  213. “Biologic” Treatment for Meniscal Repair
    Go to citation Crossref Google Scholar
  214. The Use of PRP in Athletes with Muscular Lesions or Classification of ...
    Go to citation Crossref Google Scholar
  215. Current State for Clinical Use of Stem Cells and Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  216. Optimisation of platelet concentrates therapy: Composition, localisati...
    Go to citation Crossref Google Scholar
  217. Platelets Inhibit Migration of Canine Osteosarcoma Cells
    Go to citation Crossref Google Scholar
  218. Quantitative Assessment of Optimal Bone Marrow Site for the Isolation ...
    Go to citation Crossref Google Scholar
  219. Current management of talar osteochondral lesions
    Go to citation Crossref Google Scholar
  220. Biologic Treatments for Sports Injuries II Think Tank—Current Concepts...
    Go to citation Crossref Google ScholarPub Med
  221. Effect of platelet mediator concentrate (PMC) on Achilles tenocytes: a...
    Go to citation Crossref Google Scholar
  222. Advantages of pure platelet-rich plasma compared with leukocyte- and p...
    Go to citation Crossref Google Scholar
  223. Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  224. Reconstruction of Alar Nasal Cartilage Defects Using a Tissue Engineer...
    Go to citation Crossref Google Scholar
  225. Leukocyte concentration and composition in platelet-rich plasma (PRP) ...
    Go to citation Crossref Google Scholar
  226. Analysis of cytokine profile and growth factors in platelet-rich plasm...
    Go to citation Crossref Google Scholar
  227. Regenerative Medicine for Multimodal Management of Canine Osteoarthrit...
    Go to citation Crossref Google Scholar
  228. Platelet-Rich Plasma Activates Proinflammatory Signaling Pathways and ...
    Go to citation Crossref Google ScholarPub Med
  229. The Properties of 3 Different Plasma Formulations and Their Effects on...
    Go to citation Crossref Google ScholarPub Med
  230. Platelet-Rich Plasma in a Murine Model...
    Go to citation Crossref Google ScholarPub Med
  231. Circumventing Biology
    Go to citation Crossref Google ScholarPub Med
  232. Response to “Efficacy of platelet-rich plasma in arthroscopic repair o...
    Go to citation Crossref Google Scholar
  233. Generation of Autologous Platelet-Rich Plasma by the Ultrasonic Standi...
    Go to citation Crossref Google Scholar
  234. Cytokine, chemokine, and growth factor profile of platelet-rich plasma
    Go to citation Crossref Google Scholar
  235. Modifikation der Zentrifugation zur Reduktion der Leukozytenzahl in Pl...
    Go to citation Crossref Google Scholar
  236. Overview on Small Molecule Biologic and Gene-Based Treatments in Sport...
    Go to citation Crossref Google Scholar
  237. A new strategy to tackle severe knee osteoarthritis: Combination of in...
    Go to citation Crossref Google Scholar
  238. Platelet-Rich Plasma versus Steroid Injection for Subacromial Impingem...
    Go to citation Crossref Google ScholarPub Med
  239. Effect of Leukocyte Concentration on the Efficacy of Platelet-Rich Pla...
    Go to citation Crossref Google ScholarPub Med
  240. Platelet-rich plasma: Renewed scientific understanding must guide appr...
    Go to citation Crossref Google Scholar
  241. Rotator cuff healing after needling of a calcific deposit using platel...
    Go to citation Crossref Google Scholar
  242. DEPA classification: a proposal for standardising PRP use and a retros...
    Go to citation Crossref Google Scholar
  243. The effect of leukocyte-reduced platelet-rich plasma on the proliferat...
    Go to citation Crossref Google Scholar
  244. Canine Platelet-Rich Plasma Systems: A Prospective Analysis
    Go to citation Crossref Google Scholar
  245. Platelet-Rich Plasma May Improve Osteochondral Donor Site Healing in a...
    Go to citation Crossref Google ScholarPub Med
  246. Contents and Formulations of Platelet Rich Plasma
    Go to citation Crossref Google Scholar
  247. Platelet Rich Plasma in Foot and Ankle Surgery
    Go to citation Crossref Google Scholar
  248. The Systemic Effects of Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  249. Dental Stem Cells and Growth Factors
    Go to citation Crossref Google Scholar
  250. Biological Augments in Rotator Cuff Repair
    Go to citation Crossref Google Scholar
  251. Platelet-Rich Plasma Obtained with Different Anticoagulants and Their ...
    Go to citation Crossref Google Scholar
  252. Ultrasound-guided procedures to treat sport-related muscle injuries
    Go to citation Crossref Google Scholar
  253. Advantages of Pure Platelet-Rich Plasma Compared with Leukocyte- and P...
    Go to citation Crossref Google Scholar
  254. Clinical Safety and Efficacy of Platelet-Rich Plasma in Wound Healing
    Go to citation Crossref Google Scholar
  255. Comparison of the Cellular Composition and Cytokine-Release Kinetics o...
    Go to citation Crossref Google ScholarPub Med
  256. Hamstrings anterior cruciate ligament reconstruction with and without ...
    Go to citation Crossref Google Scholar
  257. Platelet-Rich Plasma in the Animal Long-Bone Model: An Analysis of Bas...
    Go to citation Crossref Google Scholar
  258. What is the preclinical evidence on platelet rich plasma and intervert...
    Go to citation Crossref Google Scholar
  259. Platelet-rich Plasma: Wirkprinzip und Behandlung von Erkrankungen des ...
    Go to citation Crossref Google Scholar
  260. Autologous platelet-rich plasma
    Go to citation Crossref Google Scholar
  261. Rationale, secondary outcome scores and 1-year follow-up of a randomis...
    Go to citation Crossref Google Scholar
  262. Exercise and the platelet activator calcium chloride both influence th...
    Go to citation Crossref Google Scholar
  263. Platelet-Rich Plasma Increases Anti-inflammatory Markers in a Human Co...
    Go to citation Crossref Google ScholarPub Med
  264. Platelet-rich plasma for muscle injuries: game over or time out?
    Go to citation Crossref Google Scholar
  265. Biologic adjuvants and bone: current use in orthopedic surgery
    Go to citation Crossref Google Scholar
  266. Equine autologous platelet concentrates: A comparative study between d...
    Go to citation Crossref Google Scholar
  267. Preparation and Application of an Innovative Thrombocyte/Leukocyte-Enr...
    Go to citation Crossref Google Scholar
  268. Clinical Efficacy of Growth Factors to Enhance Tissue Repair in Oral a...
    Go to citation Crossref Google Scholar
  269. Comparison of Platelet Counting Technologies in Equine Platelet Concen...
    Go to citation Crossref Google Scholar
  270. Platelet-rich plasma and other cellular strategies in orthopedic surge...
    Go to citation Crossref Google Scholar
  271. PRP bei sportmedizinischen Indikationen – eine Literaturübersicht
    Go to citation Crossref Google Scholar
  272. Clinical Evaluation of Intralesional Injection of Platelet-Rich Plasma...
    Go to citation Crossref Google Scholar
  273. Management of Rotator Cuff Tears
    Go to citation Crossref Google Scholar
  274. Site-Specific Targeting of Platelet-Rich Plasma via Superparamagnetic ...
    Go to citation Crossref Google ScholarPub Med
  275. Injections Including Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  276. Platelet-Rich Plasma: From Laboratory to the Clinic
    Go to citation Crossref Google Scholar
  277. Role of Biologicals in Meniscus Surgery
    Go to citation Crossref Google Scholar
  278. Regenerative medicine modalities for nondiscal spinal disorders
    Go to citation Crossref Google Scholar
  279. New and Emerging Strategies in Platelet-Rich Plasma Application in Mus...
    Go to citation Crossref Google Scholar
  280. Effectiveness of platelet-rich plasma in the treatment of moderate kne...
    Go to citation Crossref Google Scholar
  281. Characteristics of canine platelet-rich plasma prepared with five comm...
    Go to citation Crossref Google Scholar
  282. Distinct Effects of Platelet-Rich Plasma and BMP13 on Rotator Cuff Ten...
    Go to citation Crossref Google ScholarPub Med
  283. Comparison of Postinjection Protocols After Intratendinous Achilles Pl...
    Go to citation Crossref Google Scholar
  284. Circadian Variation of Growth Factor Levels in Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  285. A Single Platelet-Rich Plasma Injection for Chronic Midsubstance Achil...
    Go to citation Crossref Google ScholarPub Med
  286. Comparison between two different platelet-rich plasma preparations and...
    Go to citation Crossref Google Scholar
  287. Is Platelet-Rich Plasma Injection an Effective Choice in Cases of Non-...
    Go to citation Crossref Google Scholar
  288. The Use of Platelet-Rich Plasma for the Treatment of Osteoarthritis
    Go to citation Crossref Google Scholar
  289. The type of platelet-rich plasma may influence the safety of the appro...
    Go to citation Crossref Google Scholar
  290. Platelet and growth factor concentrations in activated platelet-rich p...
    Go to citation Crossref Google Scholar
  291. Achilles tendinopathy recovery after a single autologous PRP injection...
    Go to citation Crossref Google Scholar
  292. Characterization and Comparison of 5 Platelet-Rich Plasma Preparations...
    Go to citation Crossref Google Scholar
  293. Restoration of the Meniscus: Form and Function
    Go to citation Crossref Google ScholarPub Med
  294. Does Autologous Leukocyte-Platelet–Rich Plasma Improve Tendon Healing ...
    Go to citation Crossref Google Scholar
  295. Increasing Platelet Concentrations in Leukocyte-Reduced Platelet-Rich ...
    Go to citation Crossref Google ScholarPub Med
  296. Biologic Enhancement of Healing in Ham Injuries
    Go to citation Crossref Google Scholar
  297. Platelet-Rich Plasma: From Laboratory to the Clinic
    Go to citation Crossref Google Scholar
  298. Platelet-Rich Plasma (PRP) in Ligament and Tendon Repair
    Go to citation Crossref Google Scholar
  299. Enhancing Disc Repair by Growth Factors and Other Modalities
    Go to citation Crossref Google Scholar
  300. Considerations on the Use of Platelet-Rich Plasma, Specifically for Bu...
    Go to citation Crossref Google Scholar
  301. A manual method to obtain platelet rich plasma
    Go to citation Crossref Google Scholar
  302. Comparison of the effect of intra‐tendon applications of recombinant h...
    Go to citation Crossref Google Scholar
  303. Utilizzo dei fattori di crescita nelle lesioni del tendine rotuleo
    Go to citation Crossref Google Scholar
  304. Platelet-rich plasma for managing pain and inflammation in osteoarthri...
    Go to citation Crossref Google Scholar
  305. The Use of PRP in Ligament and Meniscal Healing
    Go to citation Crossref Google Scholar
  306. Variability of Platelet-rich Plasma Preparations
    Go to citation Crossref Google Scholar
  307. Platelet-Rich Plasma for Rotator Cuff Repair
    Go to citation Crossref Google Scholar
  308. The Basic Science of Platelet-rich Plasma (PRP)
    Go to citation Crossref Google Scholar
  309. Platelet-rich Plasma in Orthopaedic Applications: Evidence-based Recom...
    Go to citation Crossref Google Scholar
  310. Gelatin gel as a carrier of platelet-derived growth factors
    Go to citation Crossref Google ScholarPub Med
  311. Application of Platelet-Rich Plasma to Disorders of the Knee Joint
    Go to citation Crossref Google ScholarPub Med
  312. Release kinetics of platelet-derived and plasma-derived growth factors...
    Go to citation Crossref Google Scholar
  313. Platelet-rich plasma preparation for regenerative medicine: optimizati...
    Go to citation Crossref Google Scholar
  314. Safety and efficient ex vivo expansion of ...
    Go to citation Crossref Google Scholar
  315. Bone Marrow Aspiration Concentrate and Platelet Rich Plasma for Osteoc...
    Go to citation Crossref Google Scholar
  316. Review Article: Regenerative Techniques for Repair of Rotator Cuff Tea...
    Go to citation Crossref Google ScholarPub Med
  317. Platelet-Rich Plasma Injection Is More Effective than Hyaluronic Acid ...
    Go to citation Crossref Google Scholar
  318. Platelet-Rich Plasma in the Pathologic Processes of Cartilage: Review ...
    Go to citation Crossref Google Scholar
  319. Treatment of Partial Ulnar Collateral Ligament Tears in the Elbow With...
    Go to citation Crossref Google ScholarPub Med
  320. Use of an Antifibrotic Agent Improves the Effect of Platelet-Rich Plas...
    Go to citation Crossref Google Scholar
  321. Evaluation of coagulation factors and platelet function from an off-li...
    Go to citation Crossref Google ScholarPub Med
  322. PDGF and VEGF Levels in Platelet-Rich Plasma 
    Go to citation Crossref Google Scholar
  323. Dose-response effect of an intra-tendon application of recombinant hum...
    Go to citation Crossref Google Scholar
  324. Platelet-Rich Fibrin Matrix in the Management of Arthroscopic Repair o...
    Go to citation Crossref Google ScholarPub Med
  325. Can platelet-rich plasma (PRP) improve bone healing? A comparison betw...
    Go to citation Crossref Google Scholar
  326. The Systemic Effects of Platelet-Rich Plasma Injection
    Go to citation Crossref Google ScholarPub Med
  327. The Effects of Platelets and Their Concentration on ACL Healing
    Go to citation Crossref Google Scholar
  328. The Role of Inflammation and Blood Cells in Wound Healing
    Go to citation Crossref Google Scholar
  329. Platelet-rich plasma for the treatment of lateral epicondylitis: sonog...
    Go to citation Crossref Google Scholar
  330. The role of platelets in the treatment of Achilles tendon injuries
    Go to citation Crossref Google Scholar
  331. Platelet-Rich Plasma Increases Matrix Metalloproteinases in Cultures o...
    Go to citation Crossref Google Scholar
  332. Improving the Clinical Evidence of Bone Graft Substitute Technology in...
    Go to citation Crossref Google ScholarPub Med
  333. Variabilité des compositions cellulaire et moléculaire des extraits de...
    Go to citation Crossref Google Scholar
  334. Advances in sports nutrition, exercise and medicine: Olympic issues, t...
    Go to citation Crossref Google Scholar
  335. Platelet-rich plasma intra-articular injections for cartilage degenera...
    Go to citation Crossref Google Scholar
  336. Recommendations and Considerations for the Use of Biologics in Orthope...
    Go to citation Crossref Google Scholar
  337. Platelet-rich plasma injections for tendinopathy and osteoarthritis
    Go to citation Crossref Google Scholar
  338. The Role of Platelet-Rich Plasma in Inducing Musculoskeletal Tissue He...
    Go to citation Crossref Google ScholarPub Med
  339. Effects of Platelet-Rich Plasma Composition on Anabolic and Catabolic ...
    Go to citation Crossref Google ScholarPub Med
  340. Platelet-Rich Plasma: The PAW Classification System
    Go to citation Crossref Google Scholar
  341. Comparison of the Acute Inflammatory Response of Two Commercial Platel...
    Go to citation Crossref Google ScholarPub Med
  342. Platelet-Rich Plasma in Orthopaedic Surgery and Sports Medicine: Pearl...
    Go to citation Crossref Google Scholar
  343. Platelet-Rich Plasma Injections and Surgery: Short-Term Outcomes and L...
    Go to citation Crossref Google Scholar
  344. Platelet-Rich Plasma Nonoperative Injection Therapy—A Review of Indica...
    Go to citation Crossref Google Scholar
  345. Regenerative Tendon and Ligament Healing: Opportunities with Recombina...
    Go to citation Crossref Google Scholar
  346. Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  347. Contents and Formulations of Platelet-Rich Plasma
    Go to citation Crossref Google Scholar
  348. Platelet-Rich Plasma: Preparation and Formulation
    Go to citation Crossref Google Scholar
  349. Optimized Preparation Method of Platelet-Concentrated Plasma and Nonco...
    Go to citation Crossref Google Scholar
  350. Role of Platelet-rich Plasma in Foot and Ankle Surgery
    Go to citation Crossref Google Scholar
  351. Efficacy of Autologous Platelet-Rich Plasma Use for Orthopaedic Indica...
    Go to citation Crossref Google Scholar
  352. Effects of Platelet-Rich Fibrin Matrix on Repair Integrity of At-Risk ...
    Go to citation Crossref Google ScholarPub Med
  353. Cascade ® Autologous System Platelet-Rich ...
    Go to citation Crossref Google Scholar
  354. Clinical and Magnetic Resonance Imaging Outcomes following Platelet Ri...
    Go to citation Crossref Google ScholarPub Med
  355. Update on platelet-rich plasma
    Go to citation Crossref Google Scholar
  356. What Is Platelet-Rich Plasma?
    Go to citation Crossref Google Scholar
  357. The Role of Platelet-rich Plasma in Rotator Cuff Repair
    Go to citation Crossref Google Scholar
  358. Platelet-Rich Plasma Products in Sports Medicine
    Go to citation Crossref Google Scholar
  359. Hot Ortho-Biologic Topics at AAOS 2011†
    Go to citation Crossref Google Scholar
  360. Regenerative medicine in the field of pain medicine: Prolotherapy, pla...
    Go to citation Crossref Google Scholar
  361. Treatment Options in Knee Osteoarthritis: Total Knee Arthroplasty Vers...
    Go to citation Crossref Google Scholar

Figures and tables

Figures & Media

Tables

View Options

Get access

Access options

If you have access to journal content via a personal subscription, university, library, employer or society, select from the options below:

AOSSM members can access this journal content using society membership credentials.

MEMBERSHIP LOGIN

AOSSM members can access this journal content using society membership credentials.

MEMBERSHIP LOGIN

Alternatively, view purchase options below:

Purchase 24 hour online access to view and download content.

Subscribe to this journal

Access journal content via a DeepDyve subscription or find out more about this option.

Start 2 week free trial
Need help?

View options

PDF/ePub

View PDF/ePub

Full Text

View Full Text
View full text|Download PDF

Also from Sage