Cage Group Research Articles

Biomechanical analysis of a newly designed and 3D printed plate-locking interbody cage: an observational study of finite element analysis

Anterior cervical interbody fusion (ACDF) has become a classic surgical procedure for the treatment of cervical degenerative diseases, and various interbody cages are widely used in this procedure. We used 3D printing technology to produce a new type of plate-locking cage, anticipating to achieve high fusion rate with the high biomechanical stability. This study is to compare the biomechanical characteristics between a newly designed interbody cage and a conventional Zero-profile cage during ACDF using finite element analysis. The CT images of a 35-year-old healthy male were extracted and saved in DICOM format. Mimics Research 19.0, Geomagic Wrap 2017, NX12. 0, Abaqus 6.14 were used to construct the finite element models, then, titanium plate, titanium screw, cages, and the residual parts of both groups were assembled with reference to the surgical approach of ACDF (C4/5), following the successful establishment of both surgical models, a total of six boundary and loading conditions were tested, including flexion, extension, left and right bending, and left and right axial torsion. It is found that the plate stress peak of the new cage group decreased 73.78 MPa, 70.00%; 77.17 MPa, 70.67%; 59.77 MPa, 64.97%; 49.94 MPa, 58.28%; 44.55 MPa, 68.38%; 46.14 MPa, 68.00% in flexion, extension, left bending, right bending, left axial torsion and right axial torsion, respectively. There were no obvious increases of C5 upper endoplate stress peak between these two surgical models (< 50%), except 11.68 MPa, 153.08%; 6.55 MPa, 51.45%; in flexion and extension. The 3D-printed porous plate-locking cage was shown to be biomechanically stable compared to the conventional Zero-profile cage, and it is worth noticing that the stress on the plate of the new cage is less than that on screw of the conventional cage, which indicates that the risk of fracture, loosening, and prolapse of the new cage is less likely to occur.

A wireless optogenetic setup in freely moving mice for evaluation of cortical spreading depolarization in a chronic disease model.

Spreading depolarization (SD) is an electrophysiological phenomenon of massive neuronal depolarization that occurs in a multitude of brain injuries. Clinical studies and experimental data have linked the occurrence of SDs with secondary brain damage. However, there is a translational gap because of methodological limitations between clinical and experimental approaches focusing on short-term effects. Moreover, usage of highly invasive SD triggers has put into question to what extent SDs themselves or the induction method had caused emergence of tissue damage. To overcome this gap, we here show the successful realization of an experimental approach for long-term SD induction in a wireless setup of minimal invasive optogenetic stimulation in freely behaving mice. The proposed method allows for reliable SD induction over the course of three weeks. SD characteristics induced with the wireless setup were comparable to SDs elicited by KCl or cable-bound optogenetic systems. Immunohistological analysis of c-Fos expression revealed neuronal depolarization across the stimulated hemisphere, whereas TUNEL staining revealed no stimulation related apoptosis. Optogenetic SD induction so far relied on cable- or fiber-bound systems which restrict experimental possibilities. The proposed model relies on wireless stimulation that allows SD induction in the home cage. In contrast to existing systems, the wireless setup also allows cage enrichment and group housing, therefore allowing behavioral analyses. This experimental setup has excellent potential to investigate the question of possible long-term SD effects in mouse models of different acute pathologies like traumatic brain injury or migraine.

Comparison of clinical and radiological outcomes of three-column lumbar osteotomies with and without interbody cages for adult spinal deformity.

Correcting sagittal malalignment in adult spinal deformity (ASD) is a challenging task, often requiring complex surgical interventions like pedicle subtraction osteotomies (PSOs). Different types of three-column osteotomies (3COs), including Schwab 3, Schwab 4, Schwab 4 with interbody cages, and the "sandwich" technique, aim to optimize alignment and fusion outcomes. The role of interbody cages in enhancing fusion and segmental correction remains unclear. This study aimed to compare outcomes among these 4 3CO techniques, evaluating the impact of cage use at the osteotomy site on postoperative radiographic imaging and clinical outcomes. This is a multicenter retrospective study utilizing data from a prospective multicenter database of patients undergoing complex ASD surgery. Ninety-seven patients who underwent 1 of 4 3CO techniques for thoracolumbar ASD correction with at least 2 years of follow-up were included. The sample consisted of 29 patients who underwent Schwab 3 osteotomy, 20 Schwab 4, 28 Schwab 4 with interbody cages, and 20 who underwent "sandwich" osteotomy. The Scoliosis Research Society-22 revised (SRS22r) questionnaire evaluating pain, activity, appearance, mental health, and satisfaction was used to evaluate patient reported outcomes and radiographic measures including segmental lordosis and fusion rates determined by 3 blinded reviewers were used to evaluate physiologic outcomes. This study analyzed demographic data, radiographic outcomes, patient-reported outcomes, complications, and fusion rates over a 2-year follow-up period. Fusion status was determined via serial radiographs and evaluated independently by 3 blinded reviewers. Univariate and multivariate statistical analyses were performed to assess differences among the groups and the impact of interbody cage use on outcomes. Patients undergoing "sandwich" osteotomy exhibited worse preoperative leg pain scores and lower SRS22r activity (p=.015), appearance (p=.007), and mental health domain scores (p=.0015). No differences in complications were found among groups (p>.05). Patients who underwent osteotomy with a cage were more likely to have had previous spine fusion (91.7% vs. 71.4%, p=.010). Additionally, these patients had lower preoperative SRS22r mental domain (2.9±1 vs. 3.5±1, p=.009), satisfaction (2.3±1 vs. 2.7±1.2, p=.034), and SRS22r total scores (2.3±0.6 vs. 2.6±0.6, p=.0026) but demonstrated the greatest improvement in the mental health domain (0.9±0.7 vs. 0.3±0.9, p=.002). Cage use was associated with a larger mean change in segmental lordosis at the osteotomy site (32.9±9.6 vs. 28.7±9.5, p=.038). Fusion rates were significantly higher in the cage group (79.2% vs. 55.1%, p=.0012). Regression analysis identified cage use as an independent predictor for fusion (odds ratio, 3.338; 95% confidence interval, 1.108-10.054, p=.032). Interbody cage use at the osteotomy site during 3COs for ASD correction was associated with improved fusion rates and greater segmental lordosis without increasing complication rates. Incorporating cages may provide enhanced alignment and fusion outcomes in complex ASD surgeries.

Evaluation of Healthcare Outcomes of Patients Treated with 3D-Printed-Titanium and PEEK Cages During Fusion Procedures in the Lumbar Spine.

The objective of this observational, real-world study was to describe reoperation, revision, index healthcare utilization and hospital costs among patients treated with PEEK (polyetheretherketone) or 3D-printed-titanium cages during lumbar/lumbosacral posterior fusion procedures, either TLIF (transforaminal lumbar interbody fusion) or PLIF (posterior lumbar interbody fusion). Statistical comparisons were not conducted. This was a descriptive, retrospective, observational study. Patients with PEEK (OPAL™, DePuy Synthes, Raynham, MA) or 3D-printed-titanium (CONDUIT™ TLIF (transforaminal lumbar interbody fusion)/PLIF (posterior lumbar interbody fusion) Cage/EIT™ Cellular Titanium TLIF/PLIF Cage (DePuy Synthes, Raynham, MA)) spinal cages were identified in the Premier Healthcare Database between 1/1/2007 and 9/30/2022. Patients were required to have posterior approaches of the lumbar/lumbosacral spine and DDD, stenosis, back pain, instability, spondylolisthesis, or pseudarthrosis/failed prior surgery. Patient and procedure, healthcare utilization and hospital cost data were collected at the index surgery, and patients were followed up to 3 months for reoperation and 12 months for revision. All data were summarized descriptively, and no statistical comparisons were made between cage groups. A total of 5118 PEEK and 1189 3D-printed-titanium cage patients were included in this study. Among 3D-printed-titanium cages, 804had PLIF and 345had Curved TLIF cage types. Most PEEK cage patients were 18-64 years (61.9%), and 3D-printed-titanium was evenly distributed across age categories. The mean index hospital cost was ~$40,000, LOS was ~3 days, and discharge status to home/home health was ~85% for both; surgery time was 267minutes for PEEK and 280minutes for 3D-printed-titanium. The 0-3 month reoperation cumulative incidence was 1.0% for PEEK and 1.3% for 3D-printed-titanium. For revision, incidence within 0-3, 4-6, and 7-12 months was 1.2%, 0.6%, and 1.7% for PEEK and 1.6%, 0.5%, and 1.2% for 3D-printed-titanium. The mean costs per patient associated with reoperation and revision for the entire cohort were $220 and $1228 for PEEK and $290 and $1754 for 3D-printed-titanium. This study provides real-world economic insights into an area where practice data are sparse, within hospital settings for PEEK and 3D-printed-titanium spinal cages. A key study limitation is the descriptive design in which potential confounding factors that may affect the outcome estimates are not addressed.

Influence of a Lordotic Cage Profile on Global and Segmental Lordosis in the Context of Lumbar TLIF Surgeries: A Retrospective Radiological Analysis.

Background/Objectives: Cage implantation decompresses neural elements, stabilizes segments, and promotes fusion, with sagittal balance influenced by cage size, geometry, and position. This retrospective study compared the effects of lumbar interbody cages with 10° and 15° lordotic angles on global and segmental lordosis in patients undergoing transforaminal lumbar interbody fusion (TLIF). Methods: Data from 215 patients who underwent 259 TLIF procedures between 2018 and 2022 were analyzed. All the surgeries were performed by a single senior orthopedic spine surgeon, and cages were selected by the surgeon based on patients' clinical and anatomical factors. Radiographic assessments included measurements of global and segmental lordosis. Results: Patients who received 15° cages demonstrated significantly greater segmental lordosis compared to those who received 10° cages in both bisegmental and monosegmental procedures (p < 0.001). While the global lordosis in the 10°-cage group remained unchanged postoperatively (p = 0.687), bisegmental procedures showed a small but statistically significant increase (p = 0.035). Moreover, global lordosis did not significantly differ between the 10°- and 15°-cage groups. Conclusions: Cage geometry significantly influenced segmental lordosis, with 15° cages achieving overall more superior radiographic results compared to 10° cages. However, global lordosis was unaffected by cage angle, thereby highlighting the multifaceted nature of factors that influence overall spinal alignment. These findings provide valuable insights into lumbar spine surgery, thus emphasizing the need for comprehensive preoperative planning and consideration of individual patient characteristics.

Expandable Versus Static Cages for Transforaminal Lumbar Interbody Fusion in Degenerative Lumbar Spondylosis

Objective: Expandable cages have been used in lumbar interbody fusion in recent years. These cages allow a customizable fit within the intervertebral space, enabling surgeons to restore alignment and disc height. Various types of expandable cages are currently available. However, the benefits of expandable titanium cages remain unclear, with limited evidence.Methods: This prospective, single-center cohort study enrolled patients undergoing transforaminal lumbar interbody fusion with expandable or static cages by a single surgeon. Titanium expandable cages were used in the intervention group, while polyetheretherketone static cages were applied in the control group. The clinical and radiological outcomes were evaluated preoperatively and at 1, 3, and 6 months postoperatively. The fusion rate assessed by dynamic radiography was significantly higher for the expandable cage group than in the static cage group at a 6-month follow-up (95% vs. 65%). The radiological outcomes, including disc height index, segmental lordosis, and lumbar lordosis, were similar in the 2 groups. There was no significant difference in the subsidence rate.Results: There were 20 patients in each group, with similar patient characteristics. The visual analogue scales for back and leg pain significantly improved in both groups. There were no significant differences between the groups in clinical outcomes.Conclusion: The expanded cages led to comparable outcomes. The subsidence rate of the titanium expandable cages was similar to that of the static cages. The newly designed expandable cage may accelerate fusion by reducing iatrogenic injuries to the endplate.

Comparison of Mid-Long Term Results of Cervical Cage and Cervical Disc Prosthesis in Patients with Single Level Cervical Disc Herniation

The continuous advancements in technologies have helped in maintaining the biomechanical properties of spine, focusing on functional segment preservation. Therefore, the current study has focused on the comparison of mid-long term results of cervical cage and cervical disc prosthesis (CDP) within patients with single level cervical disc herniation. For this study, a total of 51 cases with cervical disc herniation were taken into account. 25 of these underwent CDP, while 26 underwent cervical cage. A mean follow-up period of 7.3 years was considered for this study. These surgeries were performed from 2021 to 2022 in hospital, located in Turkey. It was ensured that all the incorporated patients in this study has no prior history of any surgery. The demographics were found to be comparable. Radiographic examinations and clinical outcomes were attained. At the same time, degenerative changes, cervical motion of spine and radicular pain were noted in both groups. The mean age in CDP group was found to be 46 years, while it was 43 years in cage group. Recurrent cervical pain was observed in only one patient in CDP group, while it was observed in eight individuals in cage group in the mean period of 7.3 years. In conclusion, CDP was found to be an effective treatment than cervical cage in patients with cervical disc herniation.

Coumarin-Derived Caging Groups in the Spotlight: Tailoring Physiochemical and Photophysical Properties.

The development of light-responsive molecular tools enables spatiotemporal control of biochemical processes with superior precision. Amongst these molecular tools, photolabile caging groups are employed to prevent critical binding interactions between a bioactive molecule and its corresponding target. Only upon irradiation with light, the bioactive is released in its 'active' form and is now readily available to bind to its target. Coumarin-derived caging groups constitute one of the most popular classes of photolabile protecting groups, due to their facile synthetic accessibility, ease of tuning photophysical properties via structural modification and rapid photolysis reactions. Herein, we highlight the recent progress made on the development of coumarin-derived caging groups, in which the red-shifting of absorption spectra, improving aqueous solubility and tailoring sub-cellular localisation has been of particular interest.

Influencing and Regulating the Estrous Cycle in Outbred CD1 Laboratory Mice (Mus musculus)

AbstractThe Whitten effect is a widely used tool for manipulating the mouse estrous cycle and generating reproductively active females within the laboratory setting. Typically, peak numbers of sexually receptive mice occur following exposure to male pheromones, resulting in a higher number of successful copulations on the third day after exposure. Although this method has improved efficiencies, the percentage of females mated and subsequently deemed to be pregnant/pseudopregnant remains relatively low, around 50%. In experiment 1, we aimed to 1) further understand cyclicity; 2) determine whether the initial cycle stage plays an importance on day 3 receptivity; and 3) identify any repetitive patterns/cycle stabilization. Mice (n = 27) were assigned to group cages according to cycle stage (proestrus, estrus, metestrus, diestrus). Experiment 2 was developed to determine an optimum treatment to promote receptivity by exposure to various pheromone stimuli. Mice (n = 45) were randomly assigned to 5 treatment groups (PBS-treated sham soiled bedding, male soiled bedding, live male, pregnant females, and lactating females). In both experiments, daily vaginal cytology was performed for 21 days to determine the cycle stage. Results from experiment 1 indicate that the initial cycle stage did not contribute to day 3 receptivity, although synchronization within several groups/cages was noted, and that the greatest numbers of estrous animals were obtained on days 6 and 7. Experiment 2 revealed that exposure to live males and lactating females both significantly improved receptivity compared with the PBS, male soiled bedding, and pregnant female groups. These results indicate that current strategies used for routine synchronization could be further improved through alternative housing regimens without compromising animal welfare.

Feasibility of the Non-Window-Type 3D-Printed Porous Titanium Cage in Posterior Lumbar Interbody Fusion: A Randomized Controlled Multicenter Trial.

Three-dimensionally printed titanium (3D-Ti) cages can be divided into 2 types: window-type cages, which have a void for bone graft, and non-window-type cages without a void. Few studies have investigated the necessity of a void for bone graft in fusion surgery. Therefore, the present study assessed the clinical and radiographic outcomes of window and non-window-type 3D-Ti cages in single-level posterior lumbar interbody fusion. A total of 70 patients were randomly assigned to receive either a window or non-window cage; 61 patients (87%) completed final follow-up (32 from the window cage group, 29 from the non-window cage group). Radiographic outcomes, including fusion rates, subsidence, and intra-cage osseointegration patterns, were assessed. Intra-cage osseointegration was measured using the intra-cage bridging bone score for the window cage group and the surface osseointegration ratio score for the non-window cage group. Additionally, we looked for the presence of the trabecular bone remodeling (TBR) sign on computed tomography (CT) images. Of the 61 patients, 58 achieved interbody fusion, resulting in a 95.1% fusion rate. The fusion rate in the non-window cage group was comparable to, and not significantly different from, that in the window cage group (96.6% and 93.8%, p > 0.99). The subsidence rate showed no significant difference between the window and non-window cage groups (15.6% and 3.4%, respectively; p = 0.262). The intra-cage osseointegration scores showed a significant difference between the groups (p = 0.007), with the non-window cage group having a higher proportion of cases with a score of 4 compared with the window cage group. The TBR sign was observed in 87.9% of patients who achieved interbody fusion, with a higher rate in the non-window cage group across the entire cohort although the difference was not significant (89.7% versus 78.1%, p = 0.385). Non-window-type 3D-Ti cages showed equivalent clinical outcomes compared with window-type cages and comparable interbody fusion rates. These results suggest that the potential advantages of 3D-Ti cages could be optimized in the absence of a void for bone graft by providing a larger contact surface for osseointegration. Therapeutic Level II. See Instructions for Authors for a complete description of levels of evidence.

The Effects of Rearing Systems on Incubation, Egg Production and Quality Traits in Pharaoh Quails

This study was conducted to determine the effect of rearing quails in different rearing systems on egg production, egg quality characteristics, and incubation results. The 360 quails were distributed equally to 3 different rearing groups (cage, enriched cage, and floor) in a male:female mixed at the age of 3 weeks. The eggs were individually weighed and recorded one by one daily (5487 eggs) for 3 months. To determine egg quality and incubation characteristics, 750 eggs were broken, and 3284 eggs were incubated, respectively. The results showed that female quail in the floor group have lower body weight at 6 weeks old (177.19 g), and they reached sexual maturity (age of first egg laying) later (65.36 day, P&lt;0.01), The lowest egg production (61.14%) occurred in the floor group during the 3-month egg production period (P&lt;0.05). The lowest average egg weight (9.07 g) was determined in the floor group (P&lt;0.05). It was determined that the eggs of quails raised in the enriched group had a rounder shape index because they have larger widths (P&lt;0.01). While the highest average yolk height (11.24 mm) was determined in the enriched cage group (P&lt;0.01), the highest averages of albumen length (72.41 mm) and lowest averages of yolk index (48.43%) were determined in the cage group (P&lt;0.01). The lowest average values (113.17) in Haugh unit were detected in the floor group (P&lt;0.05). The highest fertility rate (98.44%) was in Floor♂:Cage♀, the highest hatchability of fertile egg rate (94.67%) was obtained from Enriched♂:Cage♀, and the highest hatchability (89.10%) was obtained from Floor♂:Cage♀ pairing (P&lt;0.05). The lowest fertility rate (88.00%) was obtained from the Enriched♂:Floor♀, the lowest hatchability of fertile egg rate (86.01%) was obtained from the Enriched♂:Enriched♀, and the lowest hatchability (75.62%) was obtained from the Enriched♂: Enriched♀ groups. As a result, it has been revealed that the effect of various rearing systems is different on egg production, egg quality traits, and hatching results in quails. Thus, it has been shown that different programs at the rearing period to be applied to the male and female quails can achieve better incubation results and reproductive success.

Dynamic performance analysis of grid mooring system for gravity cages

ABSTRACT Gravity cage model is utilised to assess the influence of different mooring variables, (buoy buoyancy, frame line length and depth) on the dynamic performance and mooring tension of its grid mooring system. Numerical model's validity is confirmed using Morison equation and lumped mass method, followed by an analysis of how these variables impact cage motion and mooring tension under diverse environmental conditions. The findings indicate that enlarging the frame line length can equalise tension distribution within the mooring system and minimise peak tension. Optimum buoyancy is pivotal for maintaining equilibrium between maximum tension and cage displacement under wave-load conditions. When waves and currents work together, insufficient buoyancy and excessively deep frame lines may cause significant gaps between the cage and water surface, potentially leading to fish escape. Finally, further research comparing the tension distribution of each anchor line in a 2×1 cage group with the cages’ displacement.

Screening of Organic Acid Type and Dosage in Drinking Water for Young Rabbits.

Organic acids (OAs) are employed in animal feed to regulate gastrointestinal disorders and diarrhoea thanks to their ability to modulate the gastrointestinal environment and their antimicrobial capacity. However, there is not enough evidence regarding the most adequate OA and its effectiveness in rabbit farming. Therefore, the aim of this study was to screen and evaluate the response of young rabbits to six OAs, administered via drinking water, at three different concentrations (pH levels). Organic acids (acetic, ACET; formic, FOR; propionic, PROP; lactic, LAC; citric, CIT; and butyric, BUT) were tested at three concentrations (pH 3, 4, and 5). A negative control (CON; non-acidified water) was also included. We used 240 weaned rabbits (28 days old) divided into 2 batches. In each batch, animals were randomly allocated to 1 of the 19 experimental treatments and were housed in group cages of 6 animals per cage, treatment, and batch. Among the 240 rabbits, an additional cage with 6 animals was included to determine the initial physiological state of the animals. All animals were fed with commercial pelleted feed throughout the whole experiment. The duration of the study was 7 days, until 35 days of age. At 31 and 35 days of age, in each batch, three animals per day and treatment were slaughtered. The pH of the digestive contents in the fundus, antrum, duodenum, jejunum, ileum, and cecum, as well as the gastric pepsin enzyme activity, was measured. Water and feed consumption per cage and individual body weight (BW) were recorded daily. The type and dosage of OAs affected water intake. ACET 3, PROP 3, and BUT 3 reduced water intake compared to CON, negatively impacting feed intake and weight gain. FOR and CIT acids led to the highest BW and weight gain at 35 days, compared to PROP, LAC, and BUT (p < 0.05); showing ACET intermediate values. While OAs had limited effects on gastric and small intestine pH, acidified water at pH 4 and 5 lowered ileum and caecum pH (p < 0.05) compared to pH 3. Acidified water at pH 4 showed the highest (p < 0.05) pepsin activity compared to pH 3 and pH 5. Considering the limited sample size and short-term assessment period of our screening test, the OAs with the highest potential for use in post-weaning rabbits were FOR, ACET, and CIT at pH 4. The selected combinations did not exhibit any early adverse effects in young rabbits. These results should be further confirmed in a broader population of animals. It would also be advisable to extend the application of OAs over longer periods to evaluate their effects throughout the entire growing period of rabbits.

Biomechanical Behavior of Injected Cement Spacers versus Traditional Cages in Low-Density Lumbar Spine under Compression Loading.

Background and Objectives: Osteoporosis renders the use of traditional interbody cages potentially dangerous given the high risk of damage in the bone-implant interface. Instead, injected cement spacers can be applied as interbody devices; however, this technique has been mainly used in cervical spine surgery. This study aimed at investigating the biomechanical behavior of cement spacers versus traditional cages in lumbar spine surgery. Materials and Methods: Destructive monotonic axial compression testing was performed on 20 human cadaveric low-density lumbar segments from elderly donors (14 f/6 m, 70.3 ± 12.0 y) treated with either injected cement spacers (n = 10) or traditional cages (n = 10) without posterior instrumentation. Stiffness, failure load and displacement were compared. The effects of bone density, vertebral geometry and spacer contact area were evaluated. Results: Cement spacers demonstrated higher stiffness, significantly smaller displacement (p < 0.001) and a similar failure load compared to traditional cages. In the cage group, stiffness and failure load depended strongly on bone density and vertebral height, whereas failure displacement depended on vertebral anterior height. No such correlations were identified with cement spacers. Conclusions: Cement spacers used in lumbar interbody stabilization provided similar compression strength, significantly smaller failure displacement and a stiffer construct than traditional cages that provided benefits mainly for large and strong vertebrae. Cement stabilization was less sensitive to density and could be more beneficial also for segments with smaller and less dense vertebrae. In contrast to the injection of cement spacers, the optimal insertion of cages into the irregular intervertebral space is challenging and risks damaging bone. Further studies are required to corroborate these findings and the treatment selection thresholds.

Identification of Metabolites in Muscles of Lueyang Black-Bone Chickens: A Comparative Analysis of Caged and Cage-Free Rearing Modes Using Untargeted Metabolomic Techniques.

The Lueyang black-bone chicken is a specific native chicken strain in China. This study aimed to investigate the effects of different rearing systems on the meat quality of Lueyang black-bone chickens. Six hundred Lueyang black-bone hens were randomly divided into two groups at 7 weeks of age and raised in cage and cage-free systems for 20 weeks. The carcass yield, meat quality, and total metabolites were measured in both the leg and breast muscles. By comparison, the carcass yield of hens in the cage-free (CF) group (1.26 ± 0.09 kg) was significantly lower than that in the caged rearing (CR) group (1.52 ± 0.15 kg). However, the shear force of leg muscles in the CF group (27.98 ± 2.43 N) was significantly greater than that in the CR group (24.15 ± 1.93 N). In addition, six samples from each group were randomly selected and their metabolites were detected by the non-targeted metabolomics technique. Among these metabolites, 408 and 354 significantly differentially abundant metabolites were identified in breast and leg muscles, which were mainly involved in glycerophospholipid metabolism, unsaturated fatty acid biosynthesis, arginine and proline metabolism, and nucleotide metabolism. We found that the levels of 19 phospholipids, mainly phosphatidylcholines and lysophosphatidylcholines, were significantly greater in the CF group than in the CR group. Additionally, the contents of eight unsaturated fatty acids, linoleic acid, and linolenic acid were dramatically greater in the CF group than in the caged group. The accumulation of 4-hydroxy-proline, glutamate, and adenosine 3'-monophosphate (AMP) was enhanced in the CF group. Moreover, many more volatile organic compounds were identified in the muscles of the cage-free group, enhancing the flavor of the chicken meat. In conclusion, the cage-free rearing mode facilitates the accumulation of nutrients and flavor substances in the chicken meat and is a better rearing system for Lueyang black-bone chickens.

Body Weight and Morphometric Characteristics of KUB Chicken at 60 Days of Age

Kampung Unggul Balitnak Chicken (KUB) is a highly favored Indonesian native chicken breed among breeders because of its rapid development rate and ability to thrive in many situations. This study aimed to investigate KUB chickens' growth performance and morphometric parameters at 60 days of age, a crucial phase for determining their suitability as commercial broilers. Using an intensive rearing system, 100 KUB chickens were reared for 60 days in group cages. Body weight measurements were recorded weekly, and morphometric traits were measured after the study period. The study's findings indicated that the mean body weight of KUB chickens at 60 days of age was 710.53±16.76 grams, suggesting a favorable growth rate. In addition, the morphometric analysis revealed favorable physical characteristics, including an average chest length of 100.55±3.70 mm, chest width of 47.47±3.12 mm, wing length of 165.93±4.34 mm, back length of 164.9±4.26 mm, back height of 205.51±3.99 mm, shank length of 63.23±3.69 mm, and shank circumference of 35.76±1.48 mm. The results indicate that KUB chickens exhibit desirable body weight and morphometric traits at 60 days old, proving their suitability in commercial broiler farming. To summarize, this study offers significant information regarding the growth performance and physical characteristics of KUB chickens during a critical phase of their development. The findings highlight the breed's capacity to serve as a practical choice for commercial broiler production, enhancing the variety and long-term viability of the poultry sector in Indonesia.

Poster 364: Tendon-Bone Interface Healing Improvement by Moderate Treadmill Exercise Following an Anterior Cruciate Ligament Reconstruction in a Murine Model

Objectives: Recent studies have been using the anterior cruciate ligament reconstruction (ACLR) mouse model to study the tendon-bone healing process and the development of post-traumatic osteoarthritis. While it is known that mechanical load has an important effect on ACL graft healing, a limited number of studies have investigated the impact of treadmill exercise. No study has yet examined the effects of different exercise regimens following an ACLR in mice. The purpose of this study is to explore the effect of different mechanical loading stimuli on the tendon-bone interface (TBI) healing process following ACLR in mice. We hypothesized that moderate loading would positively affect TBI healing after ACLR. Methods: The study protocol was approved by our Institutional Animal Care and Use Committee (IACUC 2020-0024). A total of 58 C57BL/6 (12 weeks old) male mice underwent to an ACL reconstruction in the right knee as previously described. The first 30 mice were assigned into 5 different exercise groups (n=6 per group) and used to evaluate different exercise regimens (Study Arm 1- Fig. 1A). After identifying the optimal exercise regimen, an additional 28 mice were included in the study (Study arm 2 - Fig. 1B). All mice were acclimated on the treadmill following a 5-day acclimation protocol prior to surgery. Starting 7 days post-surgery, the treadmill exercise was performed 5 days/week for a total of 3 weeks. All animals were euthanized at 4 weeks post-surgery. Micro-CT imaging was performed using a Scanco mCT 45 system (Scanco Medical). The bone tunnel was identified, a region of interest (ROI) was defined as the bone tunnel diameter (0.64mm), and bone volume fraction (bone volume/total volume), bone mineral density, and trabecular number were evaluated in the tibial tunnel. Biomechanical Testing was performed in a materials-testing machine (EnduraTEC ELF 3200) (Fig. 2). The knee joints were carefully dissected to isolate the ACL graft. Custom fixtures were designed to ensure that the ACL was aligned in the direction of loading. The specimens were subjected to load until failure at a rate of 5.0 mm/min and the load-to-failure (N) data were recorded. The tendon-to-bone tunnel healing (TBTH) was further evaluated using a well-established histological scoring system [4]. Paraffin-embedded samples were cut into sagittal and axial planes. Hematoxylin and eosin as well as Picrosirius red staining were performed, followed by examination and photography using both brightfield and polarized light microscopy. Statistical analysis was performed by a Wilcoxon signed-rank test in GraphPad Prism 6 software. Statistical significance was defined as a p-value of less than 0.05 (P&lt;0.05). Results: In study arm 1 no significant difference was observed in micro-CT analysis and histological assessment (sagittal slices of the entire tibia) among the groups. Although the sample size was limited, the most relevant trend was observed in the 10m/min, 50min treadmill group compared to the free cage group. Further analysis of micro-CT and biomechanical testing in study arm 2 revealed no significant differences between the groups. However, histological evaluation (axial slices of the femoral/tibial intra-articular/extra-articular parts; Fig. 3) demonstrated significantly higher TBTH scores in the treadmill group compared to the free cage activity group. This difference was most pronounced in the extra-articular region of the femoral tunnel (4.1 vs. 8.4, *P=0.02), as well as in the intra-articular part of the tibial tunnel (6.9 vs. 18.0, **P&lt;0.01). Furthermore, significantly higher TBTH scores were observed in the extra-articular part of the tibia compared to those of the femur, both in the free cage (4.1 vs. 17.3, **P&lt;0.01) and the treadmill group (8.4 vs. 19.3, **P&lt;0.01). Additionally, within the treadmill group, the extra-articular part of the tibia exhibited a significantly higher TBTH score compared to that of the femur (6.6 vs. 18.0, **P&lt;0.01). Conclusions: The most important finding of this study is that TBI healing exhibited better outcomes in the extra-articular part of the femur and the intra-articular part of the tibia among the treadmill group compared to those in the free cage group. These findings suggest that moderate treadmill exercise following ACLR has a positive impact on TBI healing in both the femoral and tibial tunnels, confirming our hypothesis. The lack of a significant difference in the biomechanical test between the groups could potentially be attributed to incomplete healing of the graft in the femoral tunnel across all groups. Failure during biomechanical testing was most often observed on the femoral side. Further studies are warranted to achieve a more robust sample size, investigate alternative loading regimen such as periods of immobilization followed by remobilization, and higher intensity treadmill running (20m/min) to evaluate TBI healing following ACLR. A moderate load rehabilitation protocol might potentially result in improved healing of the tendon graft-to-bone interface following ACLR.

Integrative metabolomics and transcriptomics analysis revealed specific genes and metabolites affecting meat quality of chickens under different rearing systems

Different rearing systems have varying effect on animal welfare and meat quality of poultry. Currently, there are no established standards for the rearing systems of Chinese indigenous chickens. Our study aimed to investigate the effects of different rearing systems on the meat quality, gene profiles, and metabolites of Chinese indigenous chickens (Nanchuan chicken). 10-wk-old Nanchuan chickens (n=360) were randomly divided into 3 groups (cage, net, and free-range groups), with 6 replicates per group (20 chickens per replicate). The experiment lasted for 12 wk. At 154-days-old, 36 healthy chickens (6 males and 6 females per group) were randomly selected, euthanized, and their breast muscles were collected to assess the meat quality parameters and histomorphological characteristics. Additionally, breast muscles from 18 random hens (3 males and 3 females per group) were used for metabolomics and RNA-seq analysis. The results showed that rearing systems significantly affected the meat quality and myofiber characteristics. The meat quality of breast muscles from free-range chickens was superior to that of caged chickens, characterized by more tender meat and smaller myofiber cross-sectional areas. Integrative metabolomics and transcriptomics analysis revealed that the differentially expressed genes of chicken breast muscles were primarily involved in the myofiber differentiation. Mechanically, the improved meat quality of breast muscle in free-range chickens were mainly associated with enhanced skeletal muscle differentiation facilitated by fibromodulin, increased levels of up-regulated Acetyl-L-carnitine and Propionylcarnitine level, and decreased levels of Nonanoic acid and Elaidic acid abundance (Graphical abstract). This provides a comprehensive understanding of the most effective and sustainable breeding, production, and rearing systems for Chinese indigenous chickens. It also contributes to the current knowledge of the molecular mechanisms underlying the effects of rearing systems on growth performance and meat quality of chickens.

Enzyme-Activatable Near-Infrared Hemicyanines as Modular Scaffolds for in vivo Photodynamic Therapy.

Photodynamic therapy is an anti-cancer treatment that requires illumination of photosensitizers to induce local cell death. Current near-infrared organic photosensitizers are built from large and non-modular structures that cannot be tuned to improve safety and minimize off-target toxicity. This work describes a novel chemical platform to generate enzyme-activatable near-infrared photosensitizers. We optimized the Se-bridged hemicyanine scaffold to include caging groups and biocompatible moieties, and generated cathepsin-triggered photosensitizers for effective ablation of human glioblastoma cells. Furthermore, we demonstrated that enzyme-activatable Se-bridged hemicyanines are effective photosensitizers for the safe ablation of microtumors in vivo, creating new avenues in the chemical design of targeted anti-cancer photodynamic therapy agents.

Enzyme‐Activatable Near‐Infrared Hemicyanines as Modular Scaffolds for in vivo Photodynamic Therapy

AbstractPhotodynamic therapy is an anti‐cancer treatment that requires illumination of photosensitizers to induce local cell death. Current near‐infrared organic photosensitizers are built from large and non‐modular structures that cannot be tuned to improve safety and minimize off‐target toxicity. This work describes a novel chemical platform to generate enzyme‐activatable near‐infrared photosensitizers. We optimized the Se‐bridged hemicyanine scaffold to include caging groups and biocompatible moieties, and generated cathepsin‐triggered photosensitizers for effective ablation of human glioblastoma cells. Furthermore, we demonstrated that enzyme‐activatable Se‐bridged hemicyanines are effective photosensitizers for the safe ablation of microtumors in vivo, creating new avenues in the chemical design of targeted anti‐cancer photodynamic therapy agents.