Shoulder injury related to vaccine administration (SIRVA) is a prolonged episode of shoulder dysfunction that commences within 24 to 48 hours of a vaccination. Symptoms include a combination of shoulder pain, stiffness, and weakness. There has been a recent rapid increase in reported cases of SIRVA within the literature, particularly in adults, and is likely related to the mass vaccination programmes associated with COVID-19 and influenza. The pathophysiology is not certain, but placement of the vaccination in the subdeltoid bursa or other pericapsular tissue has been suggested to result in an inflammatory capsular process. It has been hypothesized that this is associated with a vaccine injection site that is “too high” and predisposes to the development of SIRVA. Nerve conduction studies are routinely normal, but further imaging can reveal deep-deltoid collections,
The purpose of this study was to identify factors associated with limitations in function, measured by patient-reported outcome measures (PROMs), six to nine months after a proximal humeral fracture, from a range of demographic, injury, psychological, and social variables measured within a week and two to four weeks after injury. We enrolled 177 adult patients who sustained an isolated proximal humeral fracture into the study and invited them to complete PROMs at their initial outpatient visit within one week of injury, between two and four weeks, and between six to nine months after injury. There were 128 women and 49 men; the mean age was 66 years (Aims
Patients and Methods
Aims. Rotator cuff tendinopathy has a multifactorial origin. Rejecting
the mechanistic theory has also led to abandoning operative treatment
at initial presentation in the first line. Physiotherapy exercise
programmes are the accepted first line treatment. The aim of this
study was to assess the long-term additional benefits of subacromial decompression
in the treatment of
Peri-tendinous injection of local anaesthetic,
both alone and in combination with corticosteroids, is commonly performed
in the treatment of tendinopathies. Previous studies have shown
that local anaesthetics and corticosteroids are chondrotoxic, but
their effect on tenocytes remains unknown. We compared the effects
of lidocaine and ropivacaine, alone or combined with dexamethasone,
on the viability of cultured bovine tenocytes. Tenocytes were exposed
to ten different conditions: 1) normal saline; 2) 1% lidocaine;
3) 2% lidocaine; 4) 0.2% ropivacaine; 5) 0.5% ropivacaine; 6) dexamethasone
(dex); 7) 1% lidocaine+dex; 8) 2% lidocaine+dex; 9) 0.2% ropivacaine+dex;
and 10) 0.5% ropivacaine+dex, for 30 minutes. After a 24-hour recovery
period, the viability of the tenocytes was quantified using the
CellTiter-Glo viability assay and fluorescence-activated cell sorting
(FACS) for live/dead cell counts. A 30-minute exposure to lidocaine
alone was significantly toxic to the tenocytes in a dose-dependent
manner, but a 30-minute exposure to ropivacaine or dexamethasone
alone was not significantly toxic. Dexamethasone potentiated ropivacaine tenocyte toxicity at higher
doses of ropivacaine, but did not potentiate lidocaine tenocyte
toxicity. As seen in other cell types, lidocaine has a dose-dependent
toxicity to tenocytes but ropivacaine is not significantly toxic.
Although dexamethasone alone is not toxic, its combination with
0.5% ropivacaine significantly increased its toxicity to tenocytes.
These findings might be relevant to clinical practice and warrant
further investigation.