Development of a national medical leadership competency framework: The Dutch approach

Background: The concept of medical leadership (ML) can enhance physicians' inclusion in efforts for higher quality healthcare. Despite ML's spiking popularity, only a few countries have built a national taxonomy to facilitate ML competency education and training. In this paper we discuss the development of the Dutch ML competency framework with two objectives: to account for the framework's making and to complement to known approaches of developing such frameworks. Methods: We designed a research approach and analyzed data from multiple sources based on Grounded Theory. Facilitated by the Royal Dutch Medical Association, a group of 14 volunteer researchers met over a period of 2.5 years to perform: 1) literature review; 2) individual interviews; 3) focus groups; 4) online surveys; 5) international framework comparison; and 6) comprehensive data synthesis. Results: The developmental processes that led to the framework provided a taxonomic depiction of ML in Dutch perspective. It can be seen as a canonical 'knowledge artefact' created by a community of practice and comprises of a contemporary definition of ML and 12 domains, each entailing four distinct ML competencies. Conclusions: This paper demonstrates how a new language for ML can be created in a healthcare system. The success of our approach to capture insights, expectations and demands relating leadership by Dutch physicians depended on close involvement of the Dutch national medical associations and a nationally active community of practice; voluntary work of diverse researchers and medical practitioners and an appropriate research design that used multiple methods and strategies to circumvent reverberation of established opinions and conventionalisms. Implications: The experiences reported here may provide inspiration and guidance for those anticipating similar work in other countries to develop a tailored approach to create a ML framework

Current strategies for treatment of intervertebral disc degeneration: substitution and regeneration possibilities

Background: Intervertebral disc degeneration has an annual worldwide socioeconomic impact masked as low back pain of over 70 billion euros. This disease has a high prevalence over the working age class, which raises the socioeconomic impact over the years. Acute physical trauma or prolonged intervertebral disc mistreatment triggers a biochemical negative tendency of catabolic-anabolic balance that progress to a chronic degeneration disease. Current biomedical treatments are not only ineffective in the long-run, but can also cause degeneration to spread to adjacent intervertebral discs. Regenerative strategies are desperately needed in the clinics, such as: minimal invasive nucleus pulposus or annulus fibrosus treatments, total disc replacement, and cartilaginous endplates decalcification. Main Body: Herein, it is reviewed the state-of-the-art of intervertebral disc regeneration strategies from the perspective of cells, scaffolds, or constructs, including both popular and unique tissue engineering approaches. The premises for cell type and origin selection or even absence of cells is being explored. Choice of several raw materials and scaffold fabrication methods are evaluated. Extensive studies have been developed for fully regeneration of the annulus fibrosus and nucleus pulposus, together or separately, with a long set of different rationales already reported. Recent works show promising biomaterials and processing methods applied to intervertebral disc substitutive or regenerative strategies. Facing the abundance of studies presented in the literature aiming intervertebral disc regeneration it is interesting to observe how cartilaginous endplates have been extensively neglected, being this a major source of nutrients and water supply for the whole disc. Conclusion: Severalinnovative avenues for tackling intervertebral disc degeneration are being reported â from acellular to cellular approaches, but the cartilaginous endplates regeneration strategies remain unaddressed. Interestingly, patient-specific approaches show great promise in respecting patient anatomy and thus allow quicker translation to the clinics in the near future.The authors would like to acknowledge the support provided by the Portuguese Foundation for Science and Technology (FCT) through the project EPIDisc (UTAP-EXPL/BBBECT/0050/2014), funded in the Framework of the “International Collaboratory for Emerging Technologies, CoLab”, UT Austin|Portugal Program. The FCT distinctions attributed to J. Miguel Oliveira (IF/00423/2012 and IF/01285/ 2015) and J. Silva-Correia (IF/00115/2015) under the Investigator FCT program are also greatly acknowledged.info:eu-repo/semantics/publishedVersio

Rate of decrease of myocardial O2 consumption due to cardiac arrest in anesthetized goats

The rate of change of myocardial O2 consumption, MVO2, has been measured during the transition from beating to cardiac arrest. Cardiac arrest was achieved by destruction of the bundle of His by injection of formalin and induced by 25 s interruption of pacing. The left main coronary artery was perfused under constant pressure and the great cardiac vein was drained under controlled pressure. The arterio-venous O2 content difference, [O2](a-v), and coronary arterial and venous flows, CAF resp CVF, were continuously measured. The MVO2 transient was calculated using the following equation based on a 3 compartment model: MVO2 = CAF . [O2](a-v) - (Vc + Vv) . d[O2]v/dt - (Vc . Vv/CVF) . d2[O2]v/dt2 where Vc and Vv are the capillary and the venous blood volume as function of time and [O2]v is the venous oxygen content. A 7th order polynoma was fit to the [O2]v-data and the fitted equation was differentiated analytically to obtain the first and second order derivatives. The MVO2 decreased from 94 +/- 5 microliters O2/s/100 g (mean +/- SE) before cardiac arrest to 15.4 +/- 5 microliters O2/s/100 g after 15 s of cardiac arrest. The change in MVO2 (50% in 3.8 +/- 0.3 s) preceded the change in venous oxygen content (50% in 12.7 +/- 0.5 s) and the change in coronary resistance (50% in 14.9 +/- 0.9). These results are in accordance with the hypothesis that interstitial O2 concentration is a major determinant of coronary resistanc

Stopped-flow epicardial lymph pressure is affected by left ventricular pressure in anesthetized goats

We measured epicardial lymph pressure (Plymph) in the anesthetized goat (n = 5 goats). To study the transmission of systolic left ventricular pressure (PLV) to Plymph, the effect of an increase in PLV caused by clamping of the descending aorta on Plymph was evaluated. Peak systolic PLV was 131 +/- 4 (+/- SE) mmHg during control (43 beats) and 188 +/- 4 mmHg when elevated due to aortic clamping (157 beats). Peak systolic Plymph was 24.8 +/- 1.0 and 34.8 +/- 1.1 mmHg during control and elevated PLV, respectively. In the first beat of elevated PLV, peak Plymph did not change, although the pressure waveform did. In the subsequent beats, Plymph increased proportionally with increased PLV. When PLV was decreased back to control, Plymph also decreased but did not reach control level until after three beats. The relationship between normalized Plymph and normalized PLV is given by Plymph = 0.70 x PLV + 0.09. The results show that PLV does affect Plymph in a normal beating hear

Intramyocardial blood volume change in first moments of cardiac arrest in anesthetized goats

The effect of cardiac relaxation on the intramyocardial blood volume was studied by measuring the integrated difference between arterial inflow and great cardiac venous outflow. In nine anesthetized goats, the left main coronary artery was perfused under constant pressure. The great cardiac vein was drained under pressure control. The venous flow signal was amplified so that the integrated intramyocardial blood volume was constant in the beating heart. With normal vasomotor tone, the mean change in vascular volume was 3.01 +/- 0.18 (SE) ml/100 g left ventricle (LV); 67% of the volume change was achieved in 1.60 +/- 0.09 s. For the fully dilated bed (adenosine infusion), the values were 4.13 +/- 0.33 ml/100 g and 0.96 +/- 0.06 s, respectively. The volume change could be correlated with the venous pressure during cardiac arrest (Pvd) and the change in mean left ventricular pressure after cardiac arrest (r = 0.95). The correlation improved when data were selected for Pvd less than 6 mmHg to r = 0.98. We assumed that the change in vascular transmural pressure can be approximated as half the mean left ventricular pressure change. The intramyocardial vascular compliance was then estimated as 0.104 +/- 0.012 and 0.146 +/- 0.028 ml X mmHg-1 X 100 g-1 for control and adenosine conditions, respectively. The long time constants excluded the large epicardial veins as the site of volume change; they were much longer than the duration of diastole in the beating heart. We conclude that the intramyocardial vascular compartment is capable of volume expansion on the order of 20% of its normal volume when myocardial compression by ventricular systole is suspende

Dynamic response of coronary regulation to heart rate and perfusion changes in dogs

The rate of change of coronary adjustment in the anesthetized dog to a step change in heart rate (HR) and in perfusion was analyzed. The left main coronary artery was perfused either at constant pressure (CP) or at constant flow (CF). Coronary arterial pressure and flow were continuously measured and averaged per beat, after which their ratio, being an index of coronary resistance in steady state, was calculated. The rate of change of pressure-to-flow ratio was quantified by t50, the time required to establish half of the completed response. The t50 values for the dilating responses at CP were 5.5 +/- 0.4 (SE) s for an increase in HR and 5.5 +/- 0.1 s for a decrease in perfusion. At CF these values were 9.3 +/- 0.9 and 9.7 +/- 1.6 s, respectively. The t50 values for the constricting responses with CP were 6.6 +/- 0.5 s for a decrease in HR and 6.2 +/- 0.2 s for an increase in perfusion. At CF these values were 12.2 +/- 1.5 and 10.8 +/- 2.2 s. The responses in the dog are faster than in the goat. Furthermore, the directional sensitivity in responses with perfusion changes, observed earlier in goats, is normally absent in dog

Changes in myocardial fluid filtration are reflected in epicardial lymph pressure

The effect of increased fluid filtration on stopped-flow epicardial lymph pressure (P(lymph)), used as an indicator of myocardial interstitial volume, was investigated in the anesthetized open-chest dog. Histamine infusion resulted in an increased systolic peak in the P(lymph) signal together with an increase in diastolic P(lymph) in four of five animals. During reactive hyperemia, systolic and diastolic P(lymph) increased to 127 +/- 8 and 121 +/- 6.7% (mean +/- SE, n = 6) of control, respectively. Peak P(lymph) was approximately 15 s later than peak coronary blood flow and venous pressure (P(ven)). When P(ven) was transiently elevated to 367 +/- 72 (systolic) and 247 +/- 45% (diastolic) of control, P(lymph) increased to 132 +/- 12 and 120 +/- 5.5% of control. The time of response was similar for P(ven) and P(lymph) (t50 approximately 2 S). The increased systolic and diastolic P(lymph) can be explained by an increase in interstitial and lymph filling. It is concluded that changes in myocardial fluid filtration are reflected in epicardial P(lymph). Furthermore, it seems that cardiac contraction constitutes an important defense mechanism against the formation of myocardial edem

Cardiac contraction and intramyocardial venous pressure generation in the anaesthetized dog.

1. Two hypotheses relating to the influence of contraction of the heart on coronary venous pressure (Pv) were tested. The first assumes a direct transmission of left ventricular pressure (PLV). According to the alternative hypothesis the Pv is caused by cyclical changes in the elastance of the surrounding tissue. 2. A small epicardial vein was cannulated retrogradely in eight open-chest dogs deeply anaesthetized with fentanyl. The duration of diastoles was varied after induction of a heart block with formaldehyde. Coronary arterial inflow and perfusion pressure were controlled by a perfusion system connected to the left main coronary artery by a Gregg cannula. Stopped-flow Pv was studied with intrinsic coronary tone (IT) and after maximal dilatation with adenosine. 3. The Pv pulse in the first contraction after a long diastole was not significantly correlated to the PLV pulse, with a slope of 0.5, in any dog, either with IT or during adenosine treatment. Comparing the first contraction after the long diastole with the last beat before, systolic Pv pulse decreased significantly in seven out of eight dogs, but systolic PLV pulse increased in five dogs and was unaltered in three dogs in both conditions. In contrast, end-diastolic Pv was significantly correlated to the systolic Pv in each individual animal under either condition. 4. The results indicate that pressure generation in the small coronary veins can be explained on the basis of the time-varying elastance hypothesis and that a direct transmission of PLV to Pv is absent

Dynamics of coronary adjustment to a change in heart rate in the anaesthetized goat.

1. We have previously shown that steady-state coronary flow during auto-regulation and metabolic rate changes is predicted by a mathematically expressed theory which assigns control of coronary vascular resistance to tissue PO2. Our present purpose was to test the applicability of this theory to the non-steady state as exemplified by a sudden step change in heart rate. 2. The theory predicted that the response time of change of resistance in these circumstances would be slower with constant-flow perfusion of the coronary bed than with constant-pressure perfusion, and that with constant-pressure perfusion only, the rate of adaption of resistance would be dependent on the level of pressure used. 3. These predictions were tested in open-chest goats with cannulation of the left main coronary artery and perfusion with alternately constant pressure or constant flow. Sudden step changes in heart rate were induced by pacing to induce rapid transients in myocardial metabolic rate. 4. The half-time of subsequent change in perfusion pressure-flow ratio, which in the dynamical state is not equal to resistance, was 15.7 +/- 0.4 s (mean +/- S.E.M.), which was statistically shorter than for constant flow (22.2 +/- 0.5 s, P less than 0.001). 5. The half-time of subsequent change in perfusion pressure-flow ratio with constant-pressure perfusion was 14.4 +/- 0.6 s at low pressure and 17.0 +/- 0.6 s at high pressure (P less than 0.001). 6. The results differed from those predicted by the theory, in that the changes described above were preceded by a rapid (5 s) step change in pressure-flow ratio, up with an increase in heart rate and down with a decrease in heart rate. We postulated that this was a mechanical effect due to greater compression of the coronary microvasculature with more frequent contractions. 7. To test this hypothesis, we measured changes in coronary blood volume by integrating the difference between arterial inflow and venous outflow. These experiments showed a decrease in coronary blood volume with heart rate increase and vice versa. 8. Abolition of autoregulation and metabolic regulation was achieved with maximum vasodilatation of the coronary bed with adenosine. A sudden switch in heart rate then produced the initial step change in pressure-flow ratio, but not the subsequent adaptation over 13-25 s. This confirmed that the former effect is attributable to a passive mechanical mechanism