Background. Surgical site infection following spine surgery is associated with increased morbidity, mortality and increased cost for the health care system. The reported pooled incidence is 3%. Perioperative antibiotic prophylaxis is a key factor in lowering the risk of acquiring an infection. Previous studies have assessed perioperative cefuroxime concentrations in the anterior column of the cervical spine with an anterior surgical approach. However, the majority of surgeries are performed in the posterior column and often involve the lumbar spine. Accordingly, the objective was to compare the perioperative tissue concentrations of cefuroxime in the anterior and posterior column of the same lumbar vertebra using microdialysis in an experimental porcine model. Method. The lumbar vertebral column was exposed in 8 female pigs. Microdialysis catheters were placed for sampling in the anterior column (vertebral body) and posterior column (posterior arch) within the same vertebra (L5). Cefuroxime (1.5 g) was administered intravenously over 10 min. Microdialysates and plasma samples were continuously obtained over 8 hours. Cefuroxime concentrations were quantified by Ultra High Performance Liquid Chromatography Tandem Mass Spectrometry. Microdialysis is a catheter-based pharmacokinetic tool, that allows dynamic sampling of unbound and pharmacologic active fraction of drugs e.g., cefuroxime. The primary endpoint was the time with cefuroxime above the clinical breakpoint minimal inhibitory concentration (T>MIC) for Staphylococcus aureus of 4 µg/mL as this has been suggested as the best predictor of efficacy for cefuroxime. The secondary endpoint was tissue penetration (AUC. tissue. /AUC. plasma. ). Results. Mean T>MIC 4 µg/mL (95% confidence interval) was 123 min (105–141) in plasma, 97 min (79–115) in the anterior column and 93 min (75–111) in the posterior column. Tissue penetration (95% confidence interval) was incomplete for both the anterior column 0.48 (0.40–0.56) and posterior column 0.40 (0.33–0.48). Conclusions. Open lumbar spine surgery often involves extensive soft tissue dissection, stripping and retraction of the paraspinal muscles which may impair the local blood flow exposing the lumbar vertebra to postoperative infections. A single intravenous administration of 1.5 g cefuroxime resulted in comparable T>MIC between the anterior and posterior column of the lumbar spine. Mean cefuroxime concentrations decreased below the clinical breakpoint MIC for S. aureus of 4 µg/mL after 123 min (plasma), 97 min (anterior column) and 93 min (posterior column). This is shorter than the duration of most lumbar spine surgeries, and therefore alternative dosing regimens should be considered in posterior open lumbar spine surgeries lasting more than 1.5 hours

Background and aim. Implant-associated osteomyelitis is one of the most feared complications following orthopedic surgery. Although the risk is low it is crucial to achieve adequate antibiotic concentrations proximate to the implant for a sufficient amount of time to protect the implant surface and ensure tissue integration. The aim of this study was to assess steady-state piperacillin concentrations in the proximity of an orthopedic implant inserted in cancellous bone. Method. Six female pigs received an intravenous bolus infusion of 4 g/0.5 g piperacillin/tazobactam over 30 min every 6 h. Steady state was assumed achieved in the third dosing interval (12–18 h). Microdialysis catheters were placed in a cannulated screw in the proximal tibial cancellous bone, in cancellous bone next to the screw, and in cancellous bone on the contralateral tibia. Dialysates were collected from time 12 to 18 h and plasma samples were collected as reference. Results. Time above the minimal inhibitory concentration (fT>MIC) was evaluated for MIC of 8 (low target) and 16 μg/mL (high target). For the low piperacillin target (8 μg/mL), comparable mean fT>MIC across all the investigated compartments (mean range: 54–74%) was found. For the high target (16 μg/mL), fT>MIC was shorter inside the cannulated screw (mean: 16%) than in the cancellous bone next to the screw and plasma (mean range: 49–54%), and similar between the two cancellous bone compartments. Conclusions. To reach more aggressive piperacillin fT>MIC targets in relation to the implant, alternative dosing regimens such as continuous infusion may be considered

Aim. Pyogenic spondylodiscitis remains a therapeutic challenge, as demonstrated by divergent treatment guidelines. The combination of moxifloxacin and rifampicin may be an attractive treatment option for cases caused by staphylococci; however, previous studies have reported a reduction in plasma concentrations of moxifloxacin when co-administered with rifampicin. The magnitude of this reduction in spinal tissues is not known. We aimed to investigate the interaction of rifampicin on moxifloxacin tissue concentrations in vertebral cancellous bone, intervertebral disc and subcutaneous adipose tissue in steady-state conditions using microdialysis in a porcine model. Method. Twenty female pigs were randomized into two groups of ten pigs: Group A received moxifloxacin 400 mg orally once daily for three days preoperatively. Group B received moxifloxacin 400 mg orally for three days preoperatively combined with rifampicin 450 mg twice daily for seven days preoperatively. Measurements were obtained from plasma, vertebral cancellous bone, intervertebral disc and subcutaneous adipose tissue for 24 h. Microdialysis was applied for sampling in solid tissues. Results. Co-administration of moxifloxacin and rifampicin demonstrated a reduction of free moxifloxacin concentrations in spinal tissues. The peak drug concentration (C. max. ) and the area under the concentration-time curve (AUC. 0–24. ) in all tissue compartments decreased in the range of 66–79% and 65–76%, respectively. Conclusions. Using microdialysis, we demonstrated a significant reduction of moxifloxacin C. max. and AUC. 0–24. in the spinal tissues when co-administered with rifampicin. Further studies are warranted to understand the clinical implications of this finding for the treatment of pyogenic spondylodiscitis

Aim. Tourniquet is widely used in extremity surgery. In order to prevent surgical site infection, correct timing of antimicrobial prophylaxis and tourniquet inflation is important. We aimed to evaluate the time for which the free drug concentration of cefuroxime is maintained above the minimal inhibitory concentration (T>MIC) in subcutaneous tissue and calcaneal cancellous bone during three clinically relevant tourniquet application scenarios. Method. Twenty-four female pigs were included. Microdialysis catheters were placed for sampling of cefuroxime concentrations bilaterally in calcaneal cancellous bone and subcutaneous tissue, and a tourniquet cuff was applied on a randomly picked leg of each pig. Subsequently, the pigs were randomized into three groups to receive 1.5 g of cefuroxime by intravenous injection 15 min prior to tourniquet inflation (Group A), 45 min prior to tourniquet inflation (Group B), and at the tourniquet release (Group C). The tourniquet duration was 90 min in all groups. Dialysates and venous blood samples were collected eight-hours postcefuroxime administration. Results. Cefuroxime concentrations were maintained above the clinical breakpoint MIC for Staphylococcus aureus (4 µg/mL) in calcaneal cancellous bone and subcutaneous tissue throughout the 90 min tourniquet duration in Group A and B. Cefuroxime administration at tourniquet release (Group C) resulted in concentrations above 4 µg/mL for a minimum of 3.5 hours in the tissues on the tourniquet side. There were no significant differences in the T>MIC (4 µg/mL) in subcutaneous tissue or calcaneal cancellous bone between the three groups. However, Group A tended toward shorter T>MIC in tourniquet calcaneal cancellous bone compared to Group C (p=0.08). Conclusions. Administration of cefuroxime (1.5 g) in the 15–45 min window prior to tourniquet inflation resulted in sufficient calcaneal cancellous bone and subcutaneous tissue concentrations throughout the 90 min tourniquet application. If the target is to maintain postoperative cefuroxime concentrations above relevant MIC values, our results suggest that a second dose of cefuroxime should be administered at tourniquet release

Tourniquet is widely used in extremity surgery. In order to prevent surgical site infection, correct timing of antimicrobial prophylaxis and tourniquet inflation is important. We aimed to evaluate the time for which the free drug concentration of cefuroxime is maintained above the minimal inhibitory concentration (T>MIC) in subcutaneous tissue and calcaneal cancellous bone during three clinically relevant tourniquet application scenarios. Twenty-four female pigs were included. Microdialysis catheters were placed for sampling of cefuroxime concentrations bilaterally in calcaneal cancellous bone and subcutaneous tissue, and a tourniquet cuff was applied on a randomly picked leg of each pig. Subsequently, the pigs were randomized into three groups to receive 1.5 g of cefuroxime by intravenous injection 15 min prior to tourniquet inflation (Group A), 45 min prior to tourniquet inflation (Group B), and at the tourniquet release (Group C). The tourniquet duration was 90 min in all groups. Dialysates and venous blood samples were collected eight-hours postcefuroxime administration. Cefuroxime concentrations were maintained above the clinical breakpoint MIC for Staphylococcus aureus (4 μg/mL) in calcaneal cancellous bone and subcutaneous tissue throughout the 90 min tourniquet duration in Group A and B. Cefuroxime administration at tourniquet release (Group C) resulted in concentrations above 4 μg/mL for a minimum of 3.5 hours in the tissues on the tourniquet side. There were no significant differences in the T>MIC (4 μg/mL) in subcutaneous tissue or calcaneal cancellous bone between the three groups. However, Group A tended toward shorter T>MIC in tourniquet calcaneal cancellous bone compared to Group C (p=0.08). We conclude that administration of cefuroxime (1.5 g) in the 15–45 min window prior to tourniquet inflation resulted in sufficient calcaneal cancellous bone and subcutaneous tissue concentrations throughout the 90 min tourniquet application. If the target is to maintain postoperative cefuroxime concentrations above relevant MIC values, our results suggest that a second dose of cefuroxime should be administered at tourniquet release

Aim. Flucloxacillin is conventionally administered intravenously for perioperative prophylaxis, while oral administration is typical for bacterial inoculation prophylaxis following smaller traumatic wounds. We aimed to assess the time, for which the free flucloxacillin concentration was maintained above the minimum inhibitory concentration (fT>MIC) for meticillin-susceptible Staphylococcus aureus in soft and bone tissue, after intravenous and oral administration, using microdialysis in a porcine model. Method. 16 pigs were randomly allocated to either intravenous (Group IV) or oral (Group PO) flucloxacillin 1 g every 6 h during 24 h. Microdialysis was used for sampling in cancellous and cortical bone, subcutaneous tissue, and the knee joint. In addition, plasma was sampled. The flucloxacillin fT>MIC was evaluated using a low MIC target (0.5 μg/mL) and a high MIC target (2.0 μg/mL). Results. Intravenous administration resulted in longer fT>MIC (0.5 μg/mL) compared to oral administration, except for cortical bone. In Group IV all pigs reached a concentration of 0.5 μg/mL in all compartments. The mean fT>MIC (0.5 μg/mL) was 149 min in subcutaneous tissue and 61–106 min in bone tissue. In Group PO 0/8 pigs reached a concentration of 0.5 μg/mL in all compartments. For the high MIC target (2.0 μg/mL), fT>MIC was close to 0 min in both groups across compartments. Conclusions. Although intravenous administration of flucloxacillin 1g provided higher fT>MIC for the low MIC target compared to oral administration, concentrations were surprisingly low, particularly for bone tissue. Achievement of sufficient bone and soft tissue flucloxacillin concentrations may require a dose increase or continuous administration. Acknowledgement. The study was supported by the following grants: Sofus Carl Emil Friis Foundation, Aase & Ejnar Danielsens Foundation, the Augustinus Foundation, Direkt⊘r Emil Hertz og hustru Inger Hertz Foundation, and the Novo Nordisk Foundation

Aim. Prompt and sufficient broad spectrum empirical antibiotic treatment is key to prevent infection following open tibial fractures. Succeeding co-administration, we dynamically assessed the time for which vancomycin and meropenem concentrations were above relevant epidemiological cut-off minimal inhibitory concentrations (T>MIC) in tibial compartments for the bacteria most frequently encountered in open fractures. Low and high MIC-targets were applied: 1 and 4 µg/mL for vancomycin and 0.125 and 2 µg/mL for meropenem. Materials and methods. 8 pigs received a single dose of 1000 mg vancomycin and 1000 mg meropenem simultaneously over 100 min and 10 min, respectively. Microdialysis catheters were placed for sampling over 8 h in tibial cancellous bone, cortical bone, and adjacent subcutaneous adipose tissue. Venous blood samples were collected as references. Results. Across the targeted epidemiological cut-off values, vancomycin displayed longer T>MIC in all the investigated compartments in comparison to meropenem. For both drugs, cortical bone exhibited the shortest T>MIC. For the low MIC targets and across compartments, T>MIC ranged between 208–499 min (46–100%) for vancomycin and 189–406 min (42–90%) for meropenem. For the high MIC targets, T>MIC ranged between 30–446 min (7–99%) for vancomycin and 45–181 min (10–40%) for meropenem. Conclusion. The differences in the T>MIC between the low and high targets illustrates how the interpretation of these results is highly susceptible to the defined MIC target. To encompass any trauma, contaminating or individual tissue differences, a more aggressive dosing approach may be considered to achieve longer T>MIC in all the exposed tissues and thereby lowering the risk of acquiring an infection after open tibial fractures

Aim. Local treatment with gentamicin may be an important tool in the prevention and treatment of surgical site infections in high-risk procedures and patients. The aim of this study was to evaluate the pharmacokinetic profile of gentamicin in bone and surrounding tissue, released from a controlled application of a GentaColl sponge in a porcine model. Method. In 8 female pigs, a GentaColl sponge of 10×10 cm (1.3 mg gentamicin/cm. 2. ) was placed in a cancellous bone cavity in the proximal tibia. Microdialysis was used for sampling of gentamicin concentrations over 48 hours from the cavity with the implanted GentaColl sponge, cancellous bone parallel to the cavity over and under the epiphyseal plate, cortical bone, the intramedullary canal, subcutaneous tissue, and the joint cavity of the knee. Venous blood samples were obtained as reference. Results. The main finding was a mean peak drug concentration (95-CI) of gentamicin in the cancellous bone cavity containing the implanted GentaColl sponge of 11,315 (9,049–13,581) μg/ml, persisting above 1000 μg/ml until approximately 40 hours after application. Moreover, the concentrations were low (< 1 μg/ml) in the surrounding tissues as well as in plasma. Conclusions. The mean peak gentamicin concentration from the cancellous bone cavity after a controlled application of a GentaColl sponge was high and may be adequate for the prevention of biofilm formation. However, high MIC strains and uncontrolled application of the GentaColl sponge may jeopardize this conclusion

Aims. Prompt and sufficient broad-spectrum empirical antibiotic treatment is key to preventing infection following open tibial fractures. Succeeding co-administration, we dynamically assessed the time for which vancomycin and meropenem concentrations were above relevant epidemiological cut-off (ECOFF) minimal inhibitory concentrations (T > MIC) in tibial compartments for the bacteria most frequently encountered in open fractures. Low and high MIC targets were applied: 1 and 4 µg/ml for vancomycin, and 0.125 and 2 µg/ml for meropenem. Methods. Eight pigs received a single dose of 1,000 mg vancomycin and 1,000 mg meropenem simultaneously over 100 minutes and 10 minutes, respectively. Microdialysis catheters were placed for sampling over eight hours in tibial cancellous bone, cortical bone, and adjacent subcutaneous adipose tissue. Venous blood samples were collected as references. Results. Across the targeted ECOFF values, vancomycin displayed longer T > MIC in all the investigated compartments in comparison to meropenem. For both drugs, cortical bone exhibited the shortest T > MIC. For the low MIC targets and across compartments, mean T > MIC ranged between 208 and 449 minutes (46% to 100%) for vancomycin and between 189 and 406 minutes (42% to 90%) for meropenem. For the high MIC targets, mean T > MIC ranged between 30 and 446 minutes (7% to 99%) for vancomycin and between 45 and 181 minutes (10% to 40%) for meropenem. Conclusion. The differences in the T > MIC between the low and high targets illustrate how the interpretation of these results is highly susceptible to the defined MIC target. To encompass any trauma, contamination, or individual tissue differences, a more aggressive dosing approach may be considered to achieve longer T > MIC in all the exposed tissues, and thereby lower the risk of acquiring an infection after open tibial fractures. Cite this article: Bone Joint Res 2022;11(2):112–120

Introduction: Microdialysis can detect ischemia in soft tissue. In a previous study we have shown the development of ischemia in the femoral head removed from patients undergoing total hip replacement. This study also raised some methodological questions that this study tries to answer. What is happening in the dead space around the catheter in the drill canal? And is there an equilibrium period after the insertion of the catheter. Methods and materials:. Ex vivo study: in 5 syringes with 5 ml human blood a microdialysis catheter was inserted and microdialysis performed over 3 hours. In vivo study: in the proximal part of the femur in 6 mature Göttingen mini pigs a drill hole was made and microdialysis was performed over 3 hours. The pigs were kept normoventilated during the experiment. Results:. Ex vivo: the microdialysis results showed that lactate kept a steady level and glucose and glycerol all fell, pyruvate fell but leveled out. The lactate/pyruvate ratio increased from 13(4) to 32(6) (p< 0.001). In vivo: relative recovery was 57(11)%. Lactate increased, pyruvate stayed constant, glucose and glycerol fell. The lactate/pyruvate ratio increased from initial 30(8) to 37(8) after 1 hour (p=0.007) but no significant change from 1 to 2 hours was observed. Conclusion: The ex vivo study showed a clear washout pattern, and is different from what we see in bone. The in vivo study indicates that an equilibrium period is necessary or that a reference measurement in healthy bone must be used when performing short measurements in bone

In Denmark the most common postoperative pathogen is S. aureus (1), sensitive to dicloxacillin. These bacteria can cause a postoperative infection despite using prophylactic antibiotics. Whether the tissue concentration reached is above the minimal inhibitory concentration (MIC) for the pathogens is unknown, and if lower than expected could result in a postoperative infection. Thus a trial was conducted, measuring the actual tissue concentration of dicloxacillin in human muscle and adipose tissue and compared these to the plasma concentration. MIC for dicloxacillin against S. aureus was determined using the broth macrodilution method. Six healthy male volunteers aging 25 to 27 years (body-mass-index; 20–28), were recruited. A CMA63 (Mdialysis, Stockholm, Sweden) catheter was placed in the subcutaneous tissue of the abdomen and in the rectus muscle of the thigh and the volunteers given 2 g dicloxacillin intravenously over 5 minutes. In 10 min intervals for the following 6 hours, samples from blood and Microdialysis fluid (flowrate 5 ml/min) were collected. Recovery was determined in vitro. Plasma was isolated from blood samples. The unbound dicloxacillin was isolated from plasma using filter plates (AcroPrep 30K Omega, Pall Corporation, US) centrifuged for 30 minutes at 1000 × g and 37°C. All samples were analyzed with High Performance Liquid Chromatography. MIC was determined to be 0.125 µg/ml. Average recovery was 73,7 % Maximum concentrations were reached in muscle tissue after a median of 0.5 hours and adipose tissue after 0.8 hours. The geometric mean ration (GMR) of AUC0-6h for adipose tissue compared to plasma was 0.32 [0.15–0.71]. GMR of AUC0-6h for muscle tissue compared to plasma and adipose tissue compared to muscle showed no statistically significant differences. The tissue concentrations were above MIC for 3.4 hours for adipose tissue and 4.1 hours for muscle tissue. The administration of prophylactic dicloxacillin should be given at least 30 minutes prior to incision to ensure maximum tissue concentrations at the onset of surgery. A second dose should be given after 3.4 hours in case of long surgery time. Since the dicloxacillin concentration reached in the adipose tissue is lower than in plasma, it should be investigated whether this difference is more prominent in adipose patients or patients with impaired peripheral circulation, since these patients are at a greater risk of postoperative infections

Aim. Cefuroxime is a time-dependent antibiotic widely used as intravenous perioperative prophylaxis in spine surgery. A previous study has indicated that a single dose of cefuroxime provided insufficient spine tissue concentrations for spine procedures lasting more than 2–3 hours. Due to the fact that postoperative pyogenic spondylodiscitis is associated with prolonged antimicrobial therapy and high relapse rates, we aimed to evaluate if a twofold increase of standard dosage of 1.5g cefuroxime given as one double dose or two single doses with 4-hours intervals will lead to sufficient cefuroxime spine tissue concentrations throughout the dosing interval. Method. This is preliminary data for 8 out of 16 female pigs. Data from all 16 pigs will be included for the conference. Eight pigs were randomized into two groups: Group A received one double dose of cefuroxime (3g) as a bolus, and Group B received two single doses of cefuroxime (2×1.5g) with 4-hours intervals. Measurements were obtained from plasma, subcutaneous tissue (SCT), vertebral cancellous bone and the intervertebral disc (IVD) for 8-hours thereafter. Microdialysis was applied for sampling in solid tissues. The cefuroxime concentrations were determined using ultra-high performance liquid chromatography. Results. The time with concentrations above the minimal inhibitory concentration (T>MIC) for the clinical breakpoint MIC for Staphylococcus aureus of 4 μg/ml, was superior in all compartments when administering cefuroxime as two single doses with 4-hours intervals. For the target MIC of 4 μg/ml, the mean T>MIC in all compartments ranged between 53–73% and 85–95% for Group A and B, respectively. For both groups the area under the concentration-curve (AUC) was higher for plasma compared to the remaining compartments, and the lowest AUCs were found in the vertebral cancellous bone and the IVD. There were no differences in AUC between the two groups. Furthermore, the maximal concentrations were lower for both vertebral cancellous bone and IVD compared to both SCT and plasma. When comparing the two groups, higher maximal concentrations were found in all compartments for Group A. Tissue penetration was incomplete and delayed for all compartments and comparable between the two groups. Conclusions. Despite comparable pharmacokinetic results between the two groups, Group B exhibited superior T>MIC in all compartments for the clinical breakpoint MIC for Staphylococcus aureus of 4 μg/ml. As such administration of cefuroxime as two single doses with 4-hours intervals provided sufficient cefuroxime spine tissue concentrations for a minimum of 85% of an 8-hour dosing interval, which may be acceptable for most spine procedures

Objectives. Meropenem may be an important drug in the treatment of open tibial fractures and chronic osteomyelitis. Therefore, the objective of this study was to describe meropenem pharmacokinetics in plasma, subcutaneous adipose tissue (SCT), and cancellous bone using microdialysis in a porcine model. Methods. Six female pigs were assigned to receive 1000 mg of meropenem intravenously over five minutes. Measurements of meropenem were obtained from plasma, SCT, and cancellous bone for eight hours thereafter. Microdialysis was applied for sampling in solid tissues. The meropenem concentrations were determined using ultra-high-performance liquid chromatography. Results. The penetration of meropenem into cancellous bone, expressed as the ratio of plasma to cancellous bone area under the concentration-curve from zero to the last measured value, was incomplete and delayed. The time with concentration above the minimal inhibitory concentration (T. >MIC. ), for an MIC of 0.5 μg/ml, was shorter for cancellous bone in comparison with both plasma and SCT. For MICs above 0.5 μg/ml, T. >MIC. in cancellous bone was only shorter than SCT. Considering an MIC of 4 μg/ml, no animals achieved the target of 40% T. >MIC. in plasma and cancellous bone, while less than 20% achieved it in SCT. Conclusion. The main finding of this study was short T. >MIC. in cancellous bone after intravenous administration of 1000 mg meropenem. Consequently, in order to achieve sufficient tissue concentration in the cases of open tibial fractures and chronic osteomyelitis, supplemental application of meropenem may be necessary. Cite this article: P. Hanberg, A. Lund, K. Søballe, M. Bue. Single-dose pharmacokinetics of meropenem in porcine cancellous bone determined by microdialysis: An animal study. Bone Joint Res 2019;8:342–348. DOI: 10.1302/2046-3758.87.BJR-2018-0308.R1

Aim

Deadspace is the tissue and bony defect in a surgical wound after closure. This space is presumably poorly perfused favouring bacterial proliferation and biofilm formation. In arthroplasty surgery, an obligate deadspace surrounding the prosthesis is introduced and deadspace management, in combination with obtaining therapeutic prophylactic antibiotic concentrations, is important for limiting the risk of acquiring a periprosthetic joint infection (PJI). This study aimed to investigate cefuroxime distribution to an orthopaedic surgical deadspace in comparison with plasma and bone concentrations during two dosing intervals (8 h × 2).

Aim

This study evaluated target tissue concentrations of double dose cefuroxime administered intravenously as either one 15 min infusion of 3,000 mg (Group 1) or two single 15 min infusions of 1,500 mg administered 4 h apart (Group 2).

Aim

Pyogenic spondylodiscitis is associated with prolonged antimicrobial therapy and high relapse rates. Nevertheless, tissue pharmacokinetic studies of relevant antimicrobials in both prophylactic and therapeutic situations are still sparse. Previous approaches based on bone biopsy and discectomy exhibit important methodological limitations. The objective of this study was therefore to assess the concentration of cefuroxime in intervertebral disc (IVD), vertebral body cancellous bone, subcutaneous adipose tissue (SCT) and plasma pharmacokinetics after single dose administration by use of microdialysis (MD) in a large animal model.

Objectives: Antimicrobial agents exert their effect inside the interstitial space, which is the site of many infections. Recently, microdialysis was applied to cortical and cancellous bone for the evaluation of gentamicin. The principle of microdialysis is to introduce a semipermeable membrane into bone and perfuse it with liquid, thus enabling dynamic measurements to be made.

The aim of this investigation was to measure pharmacokinetics of a Gentacoll sponge in bone tissue by microdialysis.

Materials and Methods: Nine pigs were randomized to either wet or dry application of a Gentacoll sponge (10cm* 10cm) into the bone marrow of tibia. Two catheters were inserted into cancellous bone tissue, one 1 cm (MD_1cm) and one 2 cm (MD_2cm) apart from the aimed location of the sponge. Then, the Gentacoll sponge was implanted. Wet application was defined as; the sponge was wetted in 2 mL. blood. Dry application was defined as usual surgical procedure. Concentrations of gentamicin were measured in serum and microdialysates on an Abbott Drug Analyser. Data presented are median (range). A rank sum test was performed for statistical analysis. A p-value below 0,05 was considered significant..AUC describes the total amount of gentamicin that passed though the tissue.

Results: The AUC_{6h, serum wet} was 92 (72–129) and AUC_{6h, serum dry} was 196 (142–626) mg*minute/L (P=0.02). The C_{peak, wet-group} was 120 mg/L (33–585) and C_{peak, dry-group} 178 mg/L(59–1294), (P=0.31). The overall (n=9) AUC_MD1cm was 24431 mg*minute/L (5.155–152.855) and similar the AUC_MD2cm 13759 mg*minute/L (6.351–74.573) (P=0,25). The C_{peak, MD 1cm} was 106 (41–354) (P=0.21). was 209 (33–1294) and C_{peak, MD 2cm}

Conclusions: This first study applied microdialysis for pharmacokinetic measurements of a local implant. The distribution of local applied antibiotics into bone tissue is difficult to measure. The small sample size precludes a detailed analysis, but previous found variation on the distribution of gentamicin from a Gentacoll sponge is reproduced in this work. It seems that neither application nor distance had impact on the initial pharmacokinetic of Gentacoll in bone tissue.

Introduction: We state that preserving the hip might be optimum in treatment of patients with dislocated femoral fractures presuming that the fractures unite. In order to be able to choose the right treatment for the patient with a dislocated femoral neck fracture, we have hypothesized that lack of blood flow and development of ischemia might have influence on outcome of the osteosynthesis. In this study we have established microdialysis and laser Doppler measurements in patients with a dislocated femoral neck fractures.

Methods and materials: 14 patients with dislocated fractures of the femoral neck were osteosynthezised by using 2 cannulated screws. During the operation blood flow was measured with laser Doppler in order to detect pulsatile flow, and microdialysis was performed to detect ischemia. Both measurements were made in the femoral head and with the greater trochanter as control. The parameters measured were lactate, pyruvate, glycerol and glucose concentrations. Lactate/pyruvate ratio was calculated in order to estimate ischemia defined as a value over 25. Measurements were done after the fracture was reduced, and during osteosynthesis. Data are presented as mean with standard deviation (SD) in brackets.

Results: In all but one patient laser Doppler showed pulsatile flow in the greater trochanter, whereas 8 patients had flow in the femoral head. In the greater trochanter the mean lactate/pyruvate ratio was 11 (7.55), in the femoral heads the mean ratio was 27.99 (21.24) although 4 heads did not show ischemia (p=0.0004). The values for glucose in the trochanter and the femoral head are 2.47 mM(1.92) and 1.53 mM(1.37) respectively, and for glycerol 0.16 mM(0.09) and 0.25 mM(0.22). During the observation period two patients were reoperated, one with hemiarthroplasty 3 months after the osteosynthesis due to failure of the osteosynthesis; the patient had flow measured by laser Doppler and ischemia with microdialysis. One had a resection arthroplasty due to infection.

Conclusion: To our knowledge it is the first time that laser Doppler and microdialysis has been established in patients with dislocated femoral neck fractures. Further studies will have to evaluate whether laser Doppler and microdialysis in combination with fracture related parameters can predict failure of the osteosynthesis. This might enable us to establish a treatment algorithm to be used in the daily clinic.

Aims. Flucloxacillin is commonly administered intravenously for perioperative antimicrobial prophylaxis, while oral administration is typical for prophylaxis following smaller traumatic wounds. We assessed the time, for which the free flucloxacillin concentration was maintained above the minimum inhibitory concentration (fT > MIC) for methicillin-susceptible Staphylococcus aureus in soft and bone tissue, after intravenous and oral administration, using microdialysis in a porcine model. Methods. A total of 16 pigs were randomly allocated to either intravenous (Group IV) or oral (Group PO) flucloxacillin 1 g every six hours during a 24-hour period. Microdialysis was used for sampling in cancellous and cortical bone, subcutaneous tissue, and the knee joint. In addition, plasma was sampled. The flucloxacillin fT > MIC was evaluated using a low MIC target (0.5 μg/ml) and a high MIC target (2.0 μg/ml). Results. Intravenous administration resulted in longer fT > MIC (0.5 μg/ml) compared to oral administration, except for cortical bone. In Group IV, all pigs reached a concentration of 0.5 μg/ml in all compartments. The mean fT > MIC (0.5 μg/ml) was 149 minutes (95% confidence interval (CI) 119 to 179; range 68 to 323) in subcutaneous tissue and 61 minutes (95% CI 29 to 94; range 0 to 121) to 106 minutes (95% CI 76 to 136; range 71 to 154) in bone tissue. In Group PO, 0/8 pigs reached a concentration of 0.5 μg/ml in all compartments. For the high MIC target (2.0 μg/ml), fT > MIC was close to zero minutes in both groups across compartments. Conclusion. Although intravenous administration of flucloxacillin 1 g provided higher fT > MIC for the low MIC target compared to oral administration, concentrations were surprisingly low, particularly for bone tissue. Achievement of sufficient bone and soft tissue flucloxacillin concentrations may require a dose increase or continuous administration. Cite this article: Bone Joint Res 2021;10(1):60–67

Aim. The β-lactam penicillin is often used in the treatment of soft tissue infections and osteomyelitis caused by penicillin susceptible Staphylococcus aureus. Oral antibiotic treatment has been shown to be non-inferior to intravenous (IV) therapy when used during the first 6 weeks in complex orthopedic infections (OVIVA trial). However, the use of oral β-lactams in osteomyelitis treatment remains a topic of debate due to low and variable bioavailability. The aim was to assess the time for which the unbound penicillin concentration exceeded targeted minimum inhibitory concentrations (fT>MIC) in cancellous bone and subcutaneous tissue after IV (penicillin G) and oral (penicillin V) treatment in a porcine microdialysis model. Method. 12 female pigs (75kg) were assigned to standard clinical regimens of either three doses of IV penicillin G (1.2g) or oral penicillin V (0.8g) every 6h over 18h. Microdialysis catheters were placed for sampling in tibial cancellous bone and adjacent subcutaneous tissue. Data was collected in the first dosing interval (0–6h; prophylactic situation) and the third dosing interval (12–18h; assumed steady state). Plasma samples were collected for reference. MIC targets of 0.125μg/mL (Staph. aureus breakpoint), 0.25μg/mL (Strep. Group A, B, C and G breakpoint) and 0.5μg/mL (4xMIC) were applied. Results. For all investigated MIC targets, IV penicillin G resulted in a longer mean fT>MIC in cancellous bone during the first dosing interval, and in both cancellous bone and subcutaneous tissue during the third dosing interval compared to oral penicillin V. Across compartments, mean fT>MIC for IV penicillin G (MIC: 0.125, 0.25 and 0.5μg/mL) were ≥97%, ≥84% and ≥75% during the first dosing interval, and 100%, ≥95% and ≥88%, during the third dosing interval. The mean fT>MIC for oral penicillin V were ≥40%, ≥24% and ≥7% during the first dosing interval, and ≥42%, ≥36% and ≥18% during the third dosing interval. Conclusions. The findings suggest that standard clinical dosing of IV penicillin G provides superior fT>MIC in cancellous bone and subcutaneous tissue compared to oral penicillin V, particularly in the third dosing interval. This emphasizes the importance of appropriate route of administration when applying penicillin treatment. Acknowledgements. Funding was received from The Kirsten and Freddy Johansen Foundation, The Novo Nordisk Foundation, The Beckett Foundation, The Hede Nielsen Family Foundation, King Christian the 10. th. Foundation, The A.P. Møller Foundation, The Dagmar Marshalls Foundation, and The Carl and Ellen Hertz Foundation