The goal of this observational study is to determine changes in immune functioning after total knee replacement surgery in elderly. The study population consists of 14 patients aged 65 years or over undergoing primary total knee replacement surgery. Immune functioning will be assessed at multiple timepoints before and after surgery (i.e., ± 6 weeks before, and 1 day, 1 week, ± 2 weeks, and ± 6 weeks after surgery). Each patient will serve as his/her own control. Immune functioning will primarily be assessed by determining the change from baseline in monocyte-derived TNFα production at 1 week after surgery. Changes in monocyte responsiveness are considered indicative for changes in immune functioning. As secondary objective, additional parameters of immune functioning will be assessed. In addition, the course of immune functioning following total knee replacement surgery will be investigated. Burden and potential risks for the patient are estimated to be minor. During the study, 5 blood samples of 20 mL will be collected over a period of ± 12 weeks, resulting in a total blood draw of 100 mL. During surgery a sample of synovial fluid (± 2 mL) will be taken from surgical waste. Before and after surgery patients will report their pain medication intake and the presence of cold and flu-like symptoms in a diary. Patients do not directly benefit from the study.
The world population is progressively aging. As humans age, their immune system becomes weaker through a process called immunosenescence. This age-related decline in immune functioning results in an increased susceptibility to infections. Elderly with chronic diseases or elderly who have experienced an incident, such as fall-related trauma or surgery, are particularly vulnerable to these infections, likely due to immunosuppression resulting from such an immune challenge. Currently, there are no standard interventions used to improve immune functioning in these immune-suppressed elderly. However, before the potential of such interventions can be explored, postoperative immune suppression in elderly first needs to be demonstrated. The goal of this prospective ex vivo study is therefore to determine changes in immune functioning after total knee replacement surgery in elderly. The study population consists of 14 patients (classified as ASA II or ASA III) aged 65 years or over, diagnosed with osteoarthritis, undergoing primary total knee replacement surgery under general anesthesia. Immune functioning will be assessed at multiple timepoints before and after surgery (i.e., ± 6 weeks before, and 1 day, 1 week, ± 2 weeks, and ± 6 weeks after surgery). Each patient will serve as his/her own control. Immune functioning will primarily be assessed by determining the change from baseline in monocyte-derived TNFα production at 1 week after surgery. TNFα production will be measured after ex vivo stimulation of whole blood with inflammatory stimuli and normalized for monocyte count. Changes in monocyte responsiveness are considered indicative for changes in immune functioning. As secondary objective, additional parameters of immune functioning will be assessed. In addition, the course of immune functioning following total knee replacement surgery will be investigated. Burden and potential risks for the patient are estimated to be minor. During the study, 5 blood samples of 20 mL will be collected over a period of ± 12 weeks, resulting in a total blood draw of 100 mL. Blood sampling will be combined with regular care visits, with the exception of one occasion where blood sampling will be performed at home. Patients could experience mild pain by the venipuncture, which occasionally leads to lightheadedness, fainting and hematoma. During surgery a sample of synovial fluid (± 2 mL) will be taken from surgical waste. Before and after surgery patients will report their pain medication intake and the presence of cold and flu-like symptoms in a diary. Patients do not directly benefit from the study.
Study Type
OBSERVATIONAL
Enrollment
14
At multiple timepoints (i.e., ± 6 weeks before, and 1 day, 1 week, ± 2 weeks, and ± 6 weeks after surgery) before and after total knee replacement surgery blood will be collected to assess immune functioning
Gelderse Vallei Hospital
Ede, Netherlands
Monocyte-derived TNFa production
TNFα production after ex vivo stimulation of whole blood with inflammatory stimuli corrected for monocyte count
Time frame: Change from baseline at 1 week after surgery
Monocyte-derived cytokine production
Cytokine production after ex vivo stimulation of whole blood with inflammatory stimuli and corrected for monocyte count
Time frame: Change from baseline at 1 day after surgery
Monocyte-derived cytokine production
Cytokine production after ex vivo stimulation of whole blood with inflammatory stimuli and corrected for monocyte count
Time frame: Change from baseline at 1 week after surgery
Monocyte-derived cytokine production
Cytokine production after ex vivo stimulation of whole blood with inflammatory stimuli and corrected for monocyte count
Time frame: Change from baseline at ± 2 weeks after surgery
Monocyte-derived cytokine production
Cytokine production after ex vivo stimulation of whole blood with inflammatory stimuli and corrected for monocyte count
Time frame: Change from baseline at ± 6 weeks after surgery
Monocyte-derived cytokine production
Cytokine production after ex vivo stimulation of isolated monocytes with inflammatory stimuli
Time frame: Change from baseline at 1 day after surgery
Monocyte-derived cytokine production
Cytokine production after ex vivo stimulation of isolated monocytes with inflammatory stimuli
Time frame: Change from baseline at 1 week after surgery
Monocyte-derived cytokine production
Cytokine production after ex vivo stimulation of isolated monocytes with inflammatory stimuli
Time frame: Change from baseline at ± 2 weeks after surgery
Monocyte-derived cytokine production
Cytokine production after ex vivo stimulation of isolated monocytes with inflammatory stimuli
Time frame: Change from baseline at ± 6 weeks after surgery
PBMC (peripheral blood mononuclear cell)-derived cytokine production
Cytokine production after ex vivo stimulation of PBMCs with inflammatory stimuli
Time frame: Change from baseline at 1 day after surgery
PBMC-derived cytokine production
Cytokine production after ex vivo stimulation of PBMCs with inflammatory stimuli
Time frame: Change from baseline at 1 week after surgery
PBMC-derived cytokine production
Cytokine production after ex vivo stimulation of PBMCs with inflammatory stimuli
Time frame: Change from baseline at ± 2 weeks after surgery
PBMC-derived cytokine production
Cytokine production after ex vivo stimulation of PBMCs with inflammatory stimuli
Time frame: Change from baseline at ± 6 weeks after surgery
Composition of immune cell populations
Composition of immune cell populations (white blood cell count and differential) in whole blood
Time frame: Change from baseline at 1 day after surgery
Composition of immune cell populations
Composition of immune cell populations (white blood cell count and differential) in whole blood
Time frame: Change from baseline at 1 week after surgery
Composition of immune cell populations
Composition of immune cell populations (white blood cell count and differential) in whole blood
Time frame: Change from baseline at ± 2 weeks after surgery
Composition of immune cell populations
Composition of immune cell populations (white blood cell count and differential) in whole blood
Time frame: Change from baseline at ± 6 weeks after surgery
Systemic inflammation
Systemic inflammation as measured by circulating cytokines, chemokines, acute phase proteins, oxylipins, and markers of intestinal function
Time frame: Change from baseline at 1 day after surgery
Systemic inflammation
Systemic inflammation as measured by circulating cytokines, chemokines, acute phase proteins, oxylipins, and markers of intestinal function
Time frame: Change from baseline at 1 week after surgery
Systemic inflammation
Systemic inflammation as measured by circulating cytokines, chemokines, acute phase proteins, oxylipins, and markers of intestinal function
Time frame: Change from baseline at ± 2 weeks after surgery
Systemic inflammation
Systemic inflammation as measured by circulating cytokines, chemokines, acute phase proteins, oxylipins, and markers of intestinal function
Time frame: Change from baseline at ± 6 weeks after surgery
Phagocytic function of monocytes
Phagocytic function of monocytes as measured by the uptake of fluorescent particles
Time frame: Change from baseline at 1 day after surgery
Phagocytic function of monocytes
Phagocytic function of monocytes as measured by the uptake of fluorescent particles
Time frame: Change from baseline at 1 week after surgery
Phagocytic function of monocytes
Phagocytic function of monocytes as measured by the uptake of fluorescent particles
Time frame: Change from baseline at ± 2 weeks after surgery
Phagocytic function of monocytes
Phagocytic function of monocytes as measured by the uptake of fluorescent particles
Time frame: Change from baseline at ± 6 weeks after surgery
Monocyte HLA-DR expression
Monocyte HLA-DR expression as measured with fluorescent antibodies
Time frame: Change from baseline at 1 day after surgery
Monocyte HLA-DR expression
Monocyte HLA-DR expression as measured with fluorescent antibodies
Time frame: Change from baseline at 1 week after surgery
Monocyte HLA-DR expression
Monocyte HLA-DR expression as measured with fluorescent antibodies
Time frame: Change from baseline at ± 2 weeks after surgery
Monocyte HLA-DR expression
Monocyte HLA-DR expression as measured with fluorescent antibodies
Time frame: Change from baseline at ± 6 weeks after surgery
Synovial inflammation
Synovial inflammation as scored by the surgeon (yes/no)
Time frame: During surgery
Synovial inflammation
Synovial inflammation as measured by cytokine and chemokine levels in synovial fluid
Time frame: During surgery
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