Purpose The tensile strength of the isolated Medial Patellofemoral Ligament (MPFL) is unknown. The strength required of reparative or reconstructive procedures to re-constitute this major patella stabilising structure are therefore unknown. Method 10 fresh cadaveric right (6 female 4 male) knees, mean age 71.6 (SD 16.6) years, were prepared to isolate the MPFL between the patella and the Medial Femoral Condyle (MFC). The tensile strength and mode of failure were then determined. The ligament was then repaired using a suture and the tensile strength of this determined. The ligament was then reconstructed in three ways including: Biodegradable corkscrew anchors and two tendon techniques with interference screws. One method used a blind tunnel into the MFC, while the other passed through a tunnel in the femoral condyles. Both methods passed through tunnels in the patella. Results The mean ultimate tensile strength of the isolated MPFL was 207.9 (SD 90.1) Newtons. Seven specimens failed through a mid-substance tear while three pulled off the MFC. The mean strength of the suture repair was 36.7 (SD 26.5) Newton. The biodegradable bone anchor gave a mean strength of 142.3 (SD 38.5) Newton. The blind tunnel hamstring reconstruction’s had a mean strength of 126 (SD 20.8) Newton. The double tunnel hamstring reconstruction’s failed at a mean of 195.0 (SD 65.6) Newton. Conclusion The force required to rupture an isolated MPFL appears to be approximately 210 Newton. Suture repair is insufficient to reconstitute this. Reconstruction with bone anchors or hamstring tendon techniques come close to this

The purpose of this study was to clarify the effect of delay of the reattachment of the supraspinatus tendon into a bony trough to the strength of the repaired tendon-bone complex. The supraspinatus tendon of rabbits were transected and reattached into bony troughs at the greater tuberosity immediately and six weeks after transection. The tensile strength of the tendon-bone complex, harvested twelve weeks after reattachment, were measured. The tensile strength showed no difference between immediate and delayed reattached shoulders. Six weeks delay of supraspinatus tendon repair seems not to weaken the tensile strength of repaired tendon-bone complex. The purpose of this study was to clarify the effect of timing of surgery on the strength of the supraspinatus tendon-bone complex after the reimplantation of the tendon into a bony trough. In eight rabbits, the supraspinatus tendon was transected and reinserted into a bony trough at the greater tuberosity (early reattachment group). In seven rabbits, the supraspinatus tendon was reinserted six weeks after transection (delayed reattachment group). In both groups, the rabbits were sacrificed twelve weeks after reattachment, and the tensile strength of the tendon-bone complex was measured. The contralateral shoulders served as controls. None of the operated tendons failed at the site of reimplantation. The ratio of tensile strength of the operated tendon-bone complex to the controls showed no difference between two groups (Immediate reattachment group: 79.9± 1 S.E. 16.5%, delayed reattachment group: 80.4± 12.6%, P> 0.05). This is the first experimental study to compare the tensile strength of supraspinatus tendon-bone complex repaired after different time intervals. Stress-shielded tendon & bone tend to decrease their tensile strength. Given the six weeks duration of detachment, a weaker tensile strength of delayed reattachment group was expected than of the early reattachment group. The fact that both groups did not show a difference might be due to the recovery of tensile strength of tendon & bone in twelve weeks after reattachment. Six weeks delay of repair of supraspinatus tendon does not weaken the tensile strength of repaired tendon-bone complex. Fundings This study has been supported in part by a grant from the American Shoulder and Elbow Surgeons

Introduction. Demineralised Bone Matrix (DBM) is widely used in Orthopaedics and dentistry as a bone graft substitute and may be used to augment bone formation in load bearing applications. In this study we examine the effect of gamma irradiation and freeze drying on the tensile strength of Demineralised Cortical Bone (DCB). Methods. Tibias were harvested from mature ewes and cut into bony strips. Demineralisation was done using 0.6M HCL and confirmed by X-ray. Specimens were washed until a pH of 7.0 +/_ 0.2 was achieved in the washing solutions. Specimens were allocated into 4 groups; group (A) non freeze dried non gamma irradiated, group (B) freeze dried non gamma irradiated, group (C) non freeze dried gamma irradiated mention the level of gamma irradiation and group (D) freeze dried and gamma irradiated. The maximum tensile force and stress were measured. Statistical analysis using the Mann-Whitney U test was carried out. Results. The Median of maximum tensile force for group (A) was 218N, group (B) was 306N, group (C) was 263N and for group (D) was 676N. Group (D) results were statistically higher (p=< 0.05) compared to group (A) and (C), while there was no statistical significance compared to group (B). Conclusion. Previously published studies suggested the possibility of using DCB as ACL graft substitute. We examined the effect of gamma radiation as the most common sterilisation technique in medical field and the freeze drying as a possible technique for long term storage on the tensile strength of the DCB. Freeze drying significantly increases the tensile strength of the DCB while gamma irradiation has no significant effect. Our results indicate that freeze dried gamma irradiated DCB can be used as a ligament substitute

Abstract

Purpose: Many different rotator cuff repairs have been advocated in previous publications without experimental evidence. Our aim was to mechanically test the static tensile properties and cyclical loading to failure of a single row lateral anchor repair and a double row medial and lateral anchor repair.

Method: Fresh frozen cadaveric shoulders were mounted on a rig and a mini-open deltoid split used to visualise the supraspinatus. A standardised full thickness incision of 2 cms was made with a scalpel across the supraspinatus tendon. After the deltoid was repaired and specimens randomised, an arthroscopic rotator cuff repair was performed by the two senior authors in which the medial border of the tear was apposed to the lateral border using either a double or single row technique with a ‘Twinfix AB’ suture anchor. Once the repair had been performed, the gross specimens were dissected down to the rotator cuff musculature and the repair inspected. Those with associated cuff pathology were excluded from the experiment. Specimens were then mounted on a custom made rig to statically load each tendon simulating physiological loading of a repaired cuff defect in a post-operative 300 abducted position. The increase in tear size was then measured against time for 1 hour or to a point at which the mean tendon gap formation exceeded 5mm. Each specimen was then transferred to an Instron tensile testing machine to cyclically load to failure the supraspinatus musculotendinous unit. Each specimen was freeze clamped proximally in a specially designed clamp, whilst the humeral shaft was mounted at an angle of 300 of abduction.

Results: The two groups had a distinct difference in tensile properties with the single row fixation developing a 5mm gap in under 30 minutes. After 1 hour, the gap formed in the double row specimens was less than 5mm. In cyclical loading, the single row failed at a lower load compared with the double row. In some double row specimens the tendon failed mid substance above 250N, rather than at the anchor-suture or suture-tendon interface.

Conclusions: Our results suggest that the double row mattress technique has superior loading properties when tested with a simulated physiological load comparative to the normal post-operative setting.

This technique is a novel superior based muscle sparing approach. Acetabular reaming in all hip approaches requires femoral retraction. This technique is performed through a hole in the lateral femoral cortex without the need to retract the femur. A 5 mm hole is drilled in the lateral femur using a jig attached to the broach handle, similar to a femoral nail. Specialised instruments have been developed, including a broach with a hole going through it at the angle of the neck of the prosthesis, to allow the rotation of the reaming rod whilst protecting the femur. A special C-arm is used to push on the reaming basket. The angle of the acetabulum is directly related to the position of the broach inside the femoral canal and the position of the leg. A specialised instrument allows changing of offset and length without dislocating the hip during trialling. Some instrumentation has been used in surgery but ongoing cadaver work is being performed for proof of concept. The ability to ream through the femur has been proven during surgery. The potential risk to the bone has been assessed using finite analysis as minimal. The stress levels for any diameter maintained within a safety factor >4 compared to the ultimate tensile strength of cortical bone. The described technique allows for transfemoral acetabular reaming without retraction of the femur. It is minimally invasive and simple, requiring minimal assistance. We are incorporating use with a universal robot system as well as developing an electromagnetic navigation system. Assessment of the accuracy of these significantly cheaper systems is ongoing but promising. This approach is as minimally invasive as is possible, safe, requires minimal assistance and has a number of other potential advantages with addition of other new navigation and simple robotic attachments

Although autografts represent the gold standard for anterior cruciate ligament (ACL) reconstruction, tissue-engineered ACLs provide a prospect to minimize donor site morbidity and limited graft availability. This given study characterizes the ligamentogenesis in embroidered poly(L-lactide-co-ε-caprolactone) (P(LA-CL)) / polylactic acid (PLA) constructs using a dynamic nude mice xenograft model. (P(LA-CL))/PLA scaffolds remained either untreated (co) or were functionalized by gas fluorination (F), collagen foam cross-linked with hexamethylene diisocyanate (HMDI) (coll), or gas fluorination combined with the foam (F+coll). Cell free constructs or those seeded for 1 week with lapine ACL ligamentocytes were implanted into nude mice for 12 weeks. Following explantation, biomechanical properties, cell vitality and content, histopathology of scaffolds (including organs: liver, kidney, spleen), sulphated glycosaminoglycan (sGAG) contents and biomechanical properties were assessed. Implantation of the scaffolds did not negatively affect mice weight development and organs, indicating biocompatibility. All scaffolds maintained their size and shape for the duration of the implantation. A high cell viability was detected in the scaffolds prior to and following implantation. Coll or F+coll scaffolds seeded with cells yielded superior macroscopic properties when compared to the controls. Mild signs of inflammation (foreign-body giant cells, hyperemia) were limited to scaffolds without collagen. Microscopical score values and sGAG content did not differ significantly. Although remaining stable in vivo, elastic modulus, maximum force, tensile strength and strain at Fmax were significantly lower in the in vivo compared to the samples cultured 1 week in vitro, but did not differ between scaffold subtypes, except for a higher maximum force in F+coll compared with F samples (in vivo). Scaffold functionalization with fluorinated collagen foam provides a promising approach for ACL tissue engineering. (shared first authorship). Acknowledgement: The study was supported by DFG grants SCHU1979/9-1 and SCHU1979/14-1

Decellularised porcine superflexor tendon (pSFT) has been demonstrated to be a suitable scaffold for anterior cruciate ligament reconstruction[1]. While the role of collagen in tendons is well known, the mechanical role of glycosaminoglycans (GAGs) is less clear and may be altered by the decellularisation process. To determine the effects of decellularisation on pSFT GAG content and mechanical function and to investigate the consequences of GAG loss in tensile and compressive loading. pSFTs were decellularised following previous techniques [2]. For GAG removal, native pSFTs were treated with chondroitinase ABC (ChABC; 0.1U/mL, 72h). Cell and GAG removal was validated using histology and quantitative assays. Native, decellularised and ChABC treated groups (n=6) were biomechanically characterised. In tension, specimens underwent stress relaxation and strength testing using previous protocols [1]. Stress relaxation data was fitted to a modified Maxwell-Weichert model to determine time-dependent (E1 & E2) and time-independent moduli (E0). The toe and linear region moduli (Etoe, Elinear), in addition to tensile strength (UTS) and failure strain were determined from strength testing. In compression, specimens underwent confined loading conditions (ramp at 10 s-1 to 10% strain and hold). The aggregate modulus (HA) and zero-strain permeability (k0) were determined using previous techniques [3]. Data was analysed by one-way ANOVA with Tukey post-hoc test to determine significant differences between test groups (p<0.05). Quantitative assays showed no GAG reduction post-decellularisation, but a significant reduction after ChABC treatment. HA was only significantly reduced in the ChABC group. k0 was significantly higher for the ChABC group compared to decellularised. E0 was significantly reduced in the decellularised group compared to native and ChABC groups, while E1 and E2 were not different between groups. Etoe, Elinear, UTS and failure strain were not different between groups. Decellularisation does not affect GAG content or impair mechanical function in pSFT. GAG loss adversely affects pSFT compressive properties, revealing major mechanical contribution under compression, but no significant role under tension

The suture properties associated with a successful tendon repair are: high tensile strength, little tissue response, good handling characteristics and minimal plastic deformation. Plastic deformation contributes to gap formation at a tendon repair site. Gaps greater than 4mm are prone to failing. This study investigates whether the plastic deformation demonstrated by two commonly used suture materials can be reduced by manual pre-tensioning. Twenty sutures of both Prolene 3/0 (Ethicon, UK) and Ethibond 3/0 (Excel, Johnson and Johnson, UK) were tested. Half of the sutures in each group were manually pre-tensioned prior to knot tying and half were knotted without pre-tensioning. All knots were standard surgical knots with six throws. The suture lengths were measured before and after a standardised cyclical loading regime on an Instron tensile tester. The regime was designed to represent the finger flexion forces produced in a typical rehabilitation programme. All sutures were subsequently tested to their ultimate tensile strength. After cyclical loading the pre-tensioned sutures demonstrated a mean increase in suture length of 0.7% (range 0.1-1.9%). The sutures not pre-tensioned showed a mean increase of 5.4% (range 3.3-7%). This equates to 87% less plastic deformation (p <0.05 Students' T-test) upon pre-tensioning. There were no differences with Ethibond. Pre-tensioning had no effect on ultimate tensile strength for either group. Manual pre-tensioning reduces plastic deformation in Prolene 3/0 sutures without affecting the ultimate tensile strength. This simple technique could theoretically diminish gap formation at the site of a tendon repair

Introduction. Successful tendon repairs are reliant on the suture material having high tensile strength, no or little tissue response, good handling characteristics and little elastic/plastic deformation. Plastic deformation contributes to gap formation at a tendon repair site. Previous research has shown a gap greater than 4mm is likely to fail. Pre-tensioning is a commonly used method to improve the handling properties of sutures. This study investigates whether the plastic deformation demonstrated by two suture materials used in flexor tendon repair is affected by manual pre-tensioning. Material/Methods. Twenty lengths of 3/0 Prolene (Ethicon, UK) and 3/0 Ethibond Excel (Ethicon, UK) were selected. Half of the sutures in each group were manually pre-tensioned (longitudinal stretch of 15N for 3s) prior to knot tying (standard surgical knot with six throws) and half were knotted without pre-tensioning. The suture lengths were measured before and after a standardised cyclical loading regime on a tensile tester. The regime was designed to represent the finger flexion forces produced in an active rehabilitation programme after tendon repair. All sutures were subsequently tested to their ultimate tensile strength. Results. After cyclical loading the Prolene sutures not pre-tensioned showed a mean increase in suture length of 5.4% (range 3.3-7%). The pre-tensioned Prolene sutures demonstrated a mean increase of 0.7% (range 0.1-1.9%). This equates to 87% less plastic deformation (p < 0.05 Students' T-test) with pre-tensioning. There were no differences with Ethibond. Pre-tensioning had no effect on ultimate tensile strength for either group. Conclusion. Manual pre-tensioning reduces plastic deformation in Prolene 3/0 sutures without affecting the ultimate tensile strength. This simple technique could theoretically diminish gap formation at the site of a tendon repair

Introduction: The suture properties associated with a successful tendon repair are: high tensile strength, little tissue response, good handling characteristics and minimal plastic deformation. Plastic deformation contributes to gap formation at a tendon repair site. Gaps greater than 4mm are likely to fail. This study investigates whether the plastic deformation demonstrated by two commonly used suture materials can be reduced by manual pre-tensioning. Methods: Twenty sutures of both Prolene 3/0 (Ethicon, UK) and Ethibond 3/0 (Excel, Johnson and Johnson, UK) were tested. Half of the sutures in each group were manually pre-tensioned prior to knot tying and half were knotted without pre-tensioning. All knots were standard surgical knots with six throws. The suture lengths were measured before and after a standardised cyclical loading regime on an Instron tensile tester. The regime was designed to represent the finger flexion forces produced in a typical rehabilitation programme. All sutures were subsequently tested to their ultimate tensile strength. Results: After cyclical loading the pre-tensioned sutures demonstrated a mean increase in suture length of 0.7% (range 0.1–1.9%). The sutures not pre-tensioned showed a mean increase of 5.4% (range 3.3–7%). This equates to 87% less plastic deformation (p < 0.05 Students’ T-test) upon pre-tensioning. There were no differences with Ethibond. Pre-tensioning had no effect on ultimate tensile strength for either group. Conclusions: Manual pre-tensioning reduces plastic deformation in Prolene 3/0 sutures without affecting the ultimate tensile strength. This simple technique could theoretically diminish gap formation at the site of a tendon repair

Summary Statement. A novel biomimetic polydioxanone tendon patch with woven and electrospun components is biocompatible, recapitulates native tendon architecture and creates a tissue-healing microenvironment directed by a subpopulation of regenerative macrophages. The woven component provides tensile strength while the tendon heals. Introduction. There is great interest in the use of biomimetic devices to augment tendon repairs. Ideally, implants improve healing without causing adverse local or systemic reactions. Biocompatibility remains a critical issue prior to implantation into humans, as some implants elicit a foreign body response (FBR) involving inflammation, poor wound healing and even fistulae formation. Additionally, the effect on articular cartilage locally or systemically with placement of a juxta-articular implant has not been examined. The purpose of this study is to test the in vivo biocompatibility of a novel hybrid woven and electrospun polydioxanone patch in a rat tendon transection model. Patients and Methods. Sixty Lewis rats were divided into 4 groups in which the infraspinatus was surgically transected 3 mm from its insertion. Tendons were repaired with a woven and electrospun polydioxanone patch (PDOe) and 5-0 Prolene sutures. Vicryl and Silk patches or a simple Prolene suture repair served as comparators. Animals were sacrificed at 1, 2, 4, 6 and 12 weeks to examine the biocompatibility of the implants. Immunohistochemistry was used to examine macrophage subpopulations and hematoxylin and eosin staining was used to assess foreign-body giant cells and both analyzed with a one-way ANOVA with significance set at p<.05. Articular cartilage was scrutinised with semi-quantitative analysis. Hind paw inflammatory indices were used to determine the systemic effects and biomechanical testing the tensile strength of the materials over time. Results. The PDOe patch remained grossly quiescent at all time-points. There was a severe inflammatory reaction to Vicryl at one and 2-week time-points with gross exudate. Silk patches were associated with larger fibrous capsules at each time point. There were no adverse systemic effects and articular cartilage remained normal with no differences between materials to controls. Immunohistochemistry showed a significantly higher ratio of regenerative to inflammatory macrophages for the PDOe patch compared to other constructs at each time-point and similar to controls. Silk and Vicryl patches had a greater than 10-fold increase in foreign-body giant cells compared to the PDOe patch and controls (p<.05) suggesting incorporation rather than rejection and walling off of the biomaterial. Tensile strength of the PDOe patch increased in the first 2 weeks to greater than 90 N and gradually declined to a mean of 22 N at 12 weeks. Discussion/Conclusion. The novel PDOe patch appears to be biocompatible and illicit very little FBR in this rat tendon injury model. Importantly, there was no joint reaction to the biomaterial which has not been addressed previously. We believe the electrospun component of the patch recapitulates native tendon architecture creating a tissue healing microenvironment directed by a regenerative macrophage subpopulation. These results corroborate earlier in vitro work that showed incorporation of tenocytes within the electrospun scaffold. The woven component of the scaffold provides tensile strength as the tendon heals and begins to degrade after healing is underway making it less likely to elicit a FBR. Based on these and earlier in vitro data we believe this implant shows excellent biocompatibility and is ready to proceed to human trials

Anterior cruciate ligament (ACL) reconstruction is the current standard of care for ACL tears. However, the results are not consistently successful, autografts or allografts have certain disadvantages, and synthetic grafts have had poor clinical results. The aim of this study was to determine the efficacy of tissue engineering decellularized tibialis tendons by recellularization and culture in a dynamic tissue bioreactor. To determine if recellularization of decellularized tendons combined with mechanical stimulation in a bioreactor could replicate the mechanical properties of the native ACL and be successfully used for ACL reconstruction in vivo. Porcine tibialis tendons were decellularized and then recellularized with human adult bone marrow-derived stem cells. Tendons were cultured in a tissue bioreactor that provided biaxial cyclic loading for up to 7 days. To reproduce mechanical stresses similar to hose experienced by the ACL within the knee joint, the tendons were subjected to simultaneous tension and torsion in the bioreactor. Expression of tendon-specific genes, and newly synthesized collagen and glycosaminoglycan (GAG) were used to quantify the efficacy of recellularization and dynamic bioreactor culture. The mechanical strength of recellularized constructs was measured after dynamic stimulation. Finally, the tissue-engineered tendons were used to reconstruct the ACL in mini-pigs and mechanical strength was assessed after three months. Dynamic bioreactor culture significantly increased the expression of tendon-specific genes, the quantity of newly synthesized collagen and GAG, and the tensile strength of recellularized tendons. After in vivo reconstruction, the tensile strength of the tissue-engineered tendons increased significantly up to 3 months after surgery and were within 80% of the native strength of the ACL. Our translational study indicates that the recellularization and dynamic mechanical stimuli can significantly enhance matrix synthesis and mechanical strength of decellularized porcine tibialis tendons. This approach to tissue engineering can be very useful for ACL reconstruction and may overcome some of the disadvantages of autografts and allografts

Abstract. Objectives. Direct ink writing (DIW) has gained considerable attention in production of personalized medical implants. Laponite nanoclay is added in polycaprolactone (PCL) to improve printability and bioactivity for bone implants. The 3D structure of DIW printed PCL/Laponite products was qualitatively evaluated using micro-CT. Methods. PCL/LP composite ink was formulated by dissolving 50% m/v PCL in dichloromethane with Laponite loading of up to 30%. The rheological properties of the inks were determined using Discovery HR-2 rheometer. A custom-made direct ink writer was used to fabricate both porous scaffold with 0°/90° lay-down pattern, and solid dumbbell-shaped specimens (ASTM D638 Type IV) with two printing orientations, 0° and 90° to the loading direction in tensile testing. The 3D structure of specimens was assessed using a micro-CT. Independent t-tests were performed with significance level at p<0.05. Results. The addition of Laponite in PCL ink has significantly enhanced viscosity for shape fidelity and shear-thinning property facilitating extrusion for DIW. Uniform distribution of Laponite was illustrated by micro-CT. For the 32-layer scaffold, interconnectivity of pores is observed at all 3 planes. The variation of height and width of layers is within 6% except the bottom 2 layers which are significantly lower and wider than other layers for mechanical support. For solid specimens, no ditches/interfaces between filaments are observed in 90° orientation while they are distinctive in 0° orientation because deposited filaments contact each other sooner in 90° orientation. 90° specimens also have lower air gap fraction (0.8 vs 5.4 %) and significantly higher Young's modulus (235 vs 195 MPa) and tensile strength (12.0 vs 9.5 MPa). Conclusions. The mechanical properties and printability of PCL/Laponite composites can be improved by controlling printing parameters; Micro-CT is an important tool to investigate the structure and properties of 3D printed products for bone tissue engineering

Background. Carbon fibre (CF) instrumentation is known to be radiolucent and has a tensile strength similar to metal. A specific use could be primary or oligometastatic cancer where regular surveillance imaging and Stereotactic Radiotherapy are required. CT images are inherently more prone to artefacts which affect Hounsfield unit (HU) measurements. Titanium (Ti) screws scatter more artefacts. Until now it has been difficult to quantify how advantageous the radiolucency of carbon fibre pedicle screws compared to titanium or metallic screws actually is. Methodology. In this retrospective study, conducted on patients from 2018 to 2020 in SGH, we measured the HU to compare the artifact produced by CF versus Ti pedicle screws and rods implanted in age and sex matched group of patients with oligometastatic spinal disease. Results. Eleven patients were included in each group. We compared the change of HU between preoperative and postoperative cases of both CF & Ti screws, which clearly shows Ti screws scatter lot more artefacts than CF screws. We are proposing a CT artefact grading system from grade 0 to grade 4 based on the percentage change of HU for unequivocal understanding of the CT artefacts. Conclusion. This study clearly shows the artefacts produced by the metallic implants are significantly higher than the carbon fibre implants. Considering the efficacy of the RT and the increased life expectancy as a consequence, carbon instrumentation MAY BE superior to titanium or metallic instrumentation. The artefact grading system will help the clinicians in describing and planning where the artefacts need to be factorized

Abstract. Objectives. Tendon and ligament injury poses an increasingly large burden to society. With surgical repair and grafting susceptible to high failure rates, tissue engineering provides novel avenues for treatment. This systematic review explores in vivo evidence whether mesenchymal stem cell-derived extracellular vesicles (MSC-EVs) can facilitate tendon and ligament repair in animal models. Methods. On May 26th 2021, a systematic search was performed on PubMed, Web of Science, Cochrane Library, Embase, using search terms ‘mesenchymal stem cell’ or ‘multipotent stem cell’ AND ‘extracellular vesicles’ or ‘exosomes’ AND ‘tendon’ or ‘ligament’ or ‘connective tissue’. Risk of bias was assessed using SYstematic Review Center for Laboratory animal Experimentation (SYRCLE) tool. Studies administering EVs isolated from human or animal-derived MSCs into in vivo models of tendon/ligament injury were included. In vitro, ex vivo, in silico studies were excluded, and studies without a control group were excluded. Data on isolation and characterisation of MSCs and EVs, and in vivo findings in animal models were extracted. Results. Out of 383 relevant studies, 11 case-control studies were included for data extraction, including a total of 448 animal subjects (range 10–90). Six studies utilised bone marrow-derived MSCs. All studies characterised their MSCs via flow cytometry, which expressed CD44 and CD90, and isolated EVs via ultracentrifugation (average diameter 125nm). Five studies utilised histological scoring systems, all of which reported a lower score with EV treatment, suggesting improved healing ability. Four studies reported increased anti-inflammatory cytokine expression (IL-10, TGF-β1); three studies reported decreased endogenous M1/M2 macrophage ratio with EV treatment. Eight studies reported increased maximum stiffness, breaking load, tensile strength in EV-treated tendons. Conclusion. MSC-EVs are effective therapeutic agents for tendon/ligament pathologies, attenuating the initial inflammatory response, and accelerating tendon matrix regeneration. Future randomised controlled trials are needed to definitely demonstrate MSC-EVs superiority in management of tendon/ligament injury

Restoration of hand function following division of a flexor tendon remains a significant challenge. We describe a new method of tendon repair. The first suture is placed in the standard fashion, the second suture is inserted with a round bodied needle to avoid damage to the first repair. This is placed at right angles to the first repair and enters the tendon at the furthest point from the cut tendon end. This suture is then tied with the knot on the surface of the tendon, using 4/0 Ti.cron. The repair is completed with a circumferential continuous epitenon suture, using 6/0 Prolene. This method produces a repair with a four-strand core suture and is referred to throughout this paper as the Evans repair. Flexor digitorum profundus tendons harvested from pigs were used as the experimental model. They were divided at the mid-point and then repaired using either a ‘modified Kessler’ 4/0 Ethibond core suture, a ‘modified Kessler’ 4/0 Ti.cron core suture or the Evans double core suture. The specimens were then tested to failure on an Instron materials testing machine. This produced a figure for the ultimate tensile strength of each repair. The average tensile strength for the Ethibond Kessler repair was 33 (range, 27–36) Newtons and that of the Ti.cron Kessler repair was 31 (range 21–43) Newtons. The average tensile strength for the Evans repair was 52 (range 43–60) Newtons, and it is significantly stronger than the two standard Kessler repairs (p< 0.001, Student’s t-test). Even the weakest of the Evans repairs was as strong as the strongest of the standard Kessler repairs

Dura mater is a thick membrane that is the outermost of the three layers of the meninges that surround the brain and spinal cord. Appropriate dural healing is crucial to prevent cerebrospinal fluid leaks but the entire process has been barely understood so far. Understanding of dural healing and tissue neoformation over the dural grafts, which are usually used for duraplasty, is still partial. Therefore, implantation of decellular dura mater (DM) to recipient from different donor and vitalization with recipient”s mesenchymal stem cells for the treatment of tissue on transplantation process is significant approach. This approach prevents immunological reactions and provides long-term stabilization. According to this study, it is believed that this approach will provide DM healing and become crucial in DM transplantation. The aim of this study was to develop a new construct by tissue engineering of the human DM based on a decellular allograft. Thus human DM collected from forensic medicine and decellularized using the detergent sodium dodecyl sulfate (SDS) in the multiple process of physical, enzimatic and chemical steps. Decellularization were exposing the tissue to freeze-thaw cycles, incubation in hypotonic tris-HCl buffer, 0.1% (w/v) SDS in hypotonic buffer and hypertonic buffer followed by disinfection using 0.1% (v/v) peracetic acid and final washing in phosphate-buffered saline. As a result of all these processes, cellular components of DM were removed by preserving the extracellular matrix without any significant loss in mechanical properties. Based on the histological analysis of the decellularized DM revealed the absence of visible whole cells. Collagen and glycosaminoglycan (GAG) contents of decellular DM evaluated histological staining by Masson Trichrome and Alcian blue respectively. Also biochemical tests were carried out by spectrophotometry (Quickzym Biosciences, The Netherlands) and total GAG content were analyzed by 1.9 dimethylmethylene blue assay. The histoarchitecture was unchanged, and there were no significant changes of total collagen and GAG content. Biomechanical properties were determined by tensile tests, which has confirmed the retention of biomechanical properties following decellularization. The mean tensile strengths were 7,424±4,20 MPa for control group, 5,254±2,068 MPa for decellularization group. There was no statistically significant difference between tensile strength (p=0,277) and tissue thickness (p=0, 520) for both group. In conclusion, this study has developed biomechanically functional decellularized DM scaffold for use in DM repair. In addition, this study is a part of the progressing study and additional studies investigating the biocompatibility performance of the decellularized DM scaffold and there is need for in vivo studies. Keywords. Dura mater, Decellularization, Allografts, Scaffolds, Tissue Engineering

Aim: The purpose of this paper was to describe the biological reaction imposed by a prosthetic ligament. Materials-Methods: Polyester-carbon synthetic matrices were implanted into 29 rabbits. The implants were transected centrally and reconstructed with resorbable suture material. At regular intervals from 4th day to 29 weeks, tissue samples from the ingrown implants were obtained for histology and mechanical testing. Light microscopy, DNA cytometry, immunohistochemical analysis of the collagen types, transmission and scanning electron microscopy were carried out. Ultimate tensile strength (UTL), elongation to failure (EF) and structural stiffness (SS) were determined at intervals of 8, 16 and 29 weeks. Results: The ingrowth of tissue into the scaffold provided a significant increase in tensile strength, which improved with time. The UTL significantly increased from 18.86 N ±14.69 at 8 weeks to 51.4 N ±14.64 at 29 weeks. Light microscopy showed no infl ammation or foreign body reaction. At 4th day the first fibroblast cells settled on the matrix. The DNA cytometry showed an increase of the number of the fibroblast cell mitoses up to 16 days. After 2 weeks a mesh of connective tissue was formed around the scaffold, but the number of fibroblast cells remained constant. At 4 weeks the connective tissue started to infiltrate in between the artificial fibres. Type I, III and V collagens were identified. Electron microscopically the collagen weave was irregular with a mean fibril diameter of 28.4 ± 5.2 nm of a monophasic distribution. Collagen type I accumulated progressively and more and more dense collagenous fascicles appeared in the mesh in the proximity of the artificial fibres. Conclusion: The subcutaneous tissue may act as a bio-reactor and the skin fibroblast seeding of a synthetic matrix appears to be transformed a dense connective tissue during the first 4 weeks, providing tensile strength improvement to the tissue envelope with time

Objectives. All-suture anchors are increasingly used in rotator cuff repair procedures. Potential benefits include decreased bone damage. However, there is limited published evidence for the relative strength of fixation for all-suture anchors compared with traditional anchors. Materials and Methods. A total of four commercially available all-suture anchors, the ‘Y-Knot’ (ConMed), Q-FIX (Smith & Nephew), ICONIX (Stryker) and JuggerKnot (Zimmer Biomet) and a traditional anchor control TWINFIX Ultra PK Suture Anchor (Smith & Nephew) were tested in cadaveric human humeral head rotator cuff repair models (n = 24). This construct underwent cyclic loading applied by a mechanical testing rig (Zwick/Roell). Ultimate load to failure, gap formation at 50, 100, 150 and 200 cycles, and failure mechanism were recorded. Significance was set at p < 0.05. Results. Overall, mean maximum tensile strength values were significantly higher for the traditional anchor (181.0 N, standard error (. se). 17.6) compared with the all-suture anchors (mean 133.1 N . se. 16.7) (p = 0.04). The JuggerKnot anchor had greatest displacement at 50, 100 and 150 cycles, and at failure, reaching statistical significance over the control at 100 and 150 cycles (22.6 mm . se. 2.5 versus 12.5 mm . se. 0.3; and 29.6 mm . se. 4.8 versus 17.0 mm . se. 0.7). Every all-suture anchor tested showed substantial (> 5 mm) displacement between 50 and 100 cycles (6.2 to 14.3). All-suture anchors predominantly failed due to anchor pull-out (95% versus 25% of traditional anchors), whereas a higher proportion of traditional anchors failed secondary to suture breakage. Conclusion. We demonstrate decreased failure load, increased total displacement, and variable failure mechanisms in all-suture anchors, compared with traditional anchors designed for rotator cuff repair. These findings will aid the surgeon’s choice of implant, in the context of the clinical scenario. Cite this article: N. S. Nagra, N. Zargar, R. D. J. Smith, A. J. Carr. Mechanical properties of all-suture anchors for rotator cuff repair. Bone Joint Res 2017;6:82–89. DOI: 10.1302/2046-3758.62.BJR-2016-0225.R1