Implementation and evaluation of a Project ECHO telementoring program for the Namibian HIV workforce.

BACKGROUND: The Namibian Ministry of Health and Social Services (MoHSS) piloted the first HIV Project ECHO (Extension for Community Health Outcomes) in Africa at 10 clinical sites between 2015 and 2016. Goals of Project ECHO implementation included strengthening clinical capacity, improving professional satisfaction, and reducing isolation while addressing HIV service challenges during decentralization of antiretroviral therapy. METHODS: MoHSS conducted a mixed-methods evaluation to assess the pilot. Methods included pre/post program assessments of healthcare worker knowledge, self-efficacy, and professional satisfaction; assessment of continuing professional development (CPD) credit acquisition; and focus group discussions and in-depth interviews. Analysis compared the differences between pre/post scores descriptively. Qualitative transcripts were analyzed to extract themes and representative quotes. RESULTS: Knowledge of clinical HIV improved 17.8% overall (95% confidence interval 12.2-23.5%) and 22.3% (95% confidence interval 13.2-31.5%) for nurses. Professional satisfaction increased 30 percentage points. Most participants experienced reduced professional isolation (66%) and improved CPD credit access (57%). Qualitative findings reinforced quantitative results. Following the pilot, the Namibia MoHSS Project ECHO expanded to over 40 clinical sites by May 2019 serving more than 140 000 people living with HIV. CONCLUSIONS: Similar to other Project ECHO evaluation results in the United States of America, Namibia's Project ECHO led to the development of ongoing virtual communities of practice. The evaluation demonstrated the ability of the Namibia HIV Project ECHO to improve healthcare worker knowledge and satisfaction and decrease professional isolation

Preventing Data Ambiguity in Infectious Diseases with Four-Dimensional and Personalized Evaluations

Background: Diagnostic errors can occur, in infectious diseases, when anti-microbial immune responses involve several temporal scales. When responses span from nanosecond to week and larger temporal scales, any pre-selected temporal scale is likely to miss some (faster or slower) responses. Hoping to prevent diagnostic errors, a pilot study was conducted to evaluate a four-dimensional (4D) method that captures the complexity and dynamics of infectious diseases. Methods: Leukocyte-microbial-temporal data were explored in canine and human (bacterial and/or viral) infections, with: (i) a non-structured approach, which measures leukocytes or microbes in isolation; and (ii) a structured method that assesses numerous combinations of interacting variables. Four alternatives of the structured method were tested: (i) a noise-reduction oriented version, which generates a single (one data point-wide) line of observations; (ii) a version that measures complex, three-dimensional (3D) data interactions; (iii) a non-numerical version that displays temporal data directionality (arrows that connect pairs of consecutive observations); and (iv) a full 4D (single line-, complexity-, directionality-based) version. Results: In all studies, the non-structured approach revealed non-interpretable (ambiguous) data: observations numerically similar expressed different biological conditions, such as recovery and lack of recovery from infections. Ambiguity was also found when the data were structured as single lines. In contrast, two or more data subsets were distinguished and ambiguity was avoided when the data were structured as complex, 3D, single lines and, in addition, temporal data directionality was determined. The 4D method detected, even within one day, changes in immune profiles that occurred after antibiotics were prescribed. Conclusions: Infectious disease data may be ambiguous. Four-dimensional methods may prevent ambiguity, providing earlier, in vivo, dynamic, complex, and personalized information that facilitates both diagnostics and selection or evaluation of anti-microbial therapies

Longitudinal relationships in septic humans.

<p>Spatial patterns differentiated three data subsets among 7 septic patients analyzed with dimensionless indicators: (i) a vertical subset, (ii) a right subset, and (iii) the remaining observation, or ‘left’ subset (<b>a</b>). Higher M% and M/N ratio values distinguished the ‘right’ subset from the remaining data points, while higher L% and lower N/L ratio values differentiated the ‘left’ data point from the remaining observations (horizontal lines, <b>b</b>). Discrimination further improved when temporal and multidirectional data flows were assessed: several numerically similar observations displayed different directionalities (<b>c</b>). While not all observations could be analyzed statistically because some patterns included only one or two data point(s), the spatial-temporal analysis detected non-overlapping M% and M/N ratio distributions that differentiated by the ‘right’ subset with a left-to-right directional flow from the ‘right’ subset with a right-to-left flow (boxes, <b>d</b>). Non-numerical information (arrows) also distinguished ‘bottom/right-to-left’ from ‘bottom/left-to-right’ observations (boxes, <b>d</b>).</p

Classic analysis of immuno-microbial data.

<p>The classic method did not discriminate: leukocyte data distributions overlapped among different biological conditions, such as fever-positive and fever-negative individuals or individuals that recovered or did not recover from infections (blue boxes, <b>a-d</b>). The analysis of temporal data did not improve discrimination (<b>e-h</b>). Four studies were evaluated, including: (i) one dog [<b>a, e</b>], (ii) one human infected by MSSA [<b>b, f</b>]; (iii) one human HIV case, with a secondary MRSA infection [<b>c, g</b>]), and (iv) seven humans presenting with sepsis [<b>d, h</b>]).</p

Multi-directional data ambiguity.

<p>Ambiguity was also expressed when temporal data directionality was evaluated: arrows that connected pairs of consecutive observations displayed different temporal directionality even when they exhibited similar numerical information (boxes, <b>a-d</b>). Such pattern indicated that some dynamic changes took place at temporal scales smaller than the one utilized. Therefore, the 3D, single line of data points defined by the L%, the phagocyte/lymphocyte (P/L) and the mononuclear cell/neutrophil (MC/N) ratios failed to discriminate dynamics: some observations with similar numerical values, which expressed different biological conditions, were not distinguished.</p

Human leukocyte spatial-temporal (HIV/MRSA-related) relationships.

<p>Viral load values of the HIV+ patient were not informative: they exhibited more than 1000-fold changes among clinically stable observations (arrows indicating green symbols, <b>a</b>). In contrast, dimensionless indicators (DIs) differentiated two spatial (‘vertical’ and ‘horizontal’) subsets, which included two MRSA isolations within the vertical subset (set I, <b>b</b>), while all bacteria-negative data points were horizontally located (set II, <b>b</b>). A second set of DIs separated the ‘vertical’ data points into two sub-subsets: (i) the ‘top vertical’ and (ii) the ‘left horizontal’ groups, which did not overlap with the remaining (‘right horizontal’) data points (<b>c</b>). At least the L% and the M/N ratio distinguished the three spatial data subsets (<b>d</b>). More information was extracted when arrows that connected pairs of consecutive observations were measured (<b>e, f</b>). The assessment of <i>spatial</i>-<i>temporal data directionality</i> differentiated, twice, changes that took place within one day (days 118–119; and 135–136; arrows, <b>e, f</b>). While the spatial (3D) analysis detected only two or three data subsets (<b>b, c</b>), the spatial-temporal (4D) assessment distinguished five data subsets (<b>g</b>). For instance, the L%, M%, N/L, and M/N ratios differentiated ‘top vertical’ from the remaining observations (blue horizontal lines, <b>g</b>). The L% and N/L ratio also distinguished the ‘left/top-down’ observation from the ‘left/bottom-up’ observations (green horizontal lines, <b>g</b>). Furthermore, the N/L ratio discriminated the ‘right horizontal’ from the remaining subsets (red horizontal line, <b>g</b>). Some leukocyte profiles were associated with antibiotic therapy, for instance, higher M/L values were observed after antibiotics were prescribed, even after antibiotic therapy was discontinued (<b>h</b>).</p

Spatial-temporal and personalized data analysis.

<p>When the leukocyte data of five septic patients tested daily over three days were analyzed on personalized bases, several <i>temporal patterns</i> were observed (the data of the two remaining septic patients were not analyzed because they were tested only two days). At least <i>two directionalities</i> were differentiated: (i) data flows that came from the center or left and, over time, moved to the right (‘from left-to-right’, <b>a, b</b>); and (ii) responses that followed the opposite directionality (<b>c-e)</b>. These responses were induced by: <i>A</i>. <i>baumannii</i> (<b>a</b>), <i>E</i>. <i>faecalis</i> (<b>b</b>), <i>S</i>. <i>liquefaciens</i> (<b>c</b>), and <i>E</i>. <i>coli</i> (<b>d, e</b>).</p

Nature and Consequences of Biological Reductionism for the Immunological Study of Infectious Diseases

Evolution has conserved “economic” systems that perform many functions, faster or better, with less. For example, three to five leukocyte types protect from thousands of pathogens. To achieve so much with so little, biological systems combine their limited elements, creating complex structures. Yet, the prevalent research paradigm is reductionist. Focusing on infectious diseases, reductionist and non-reductionist views are here described. The literature indicates that reductionism is associated with information loss and errors, while non-reductionist operations can extract more information from the same data. When designed to capture one-to-many/many-to-one interactions—including the use of arrows that connect pairs of consecutive observations—non-reductionist (spatial–temporal) constructs eliminate data variability from all dimensions, except along one line, while arrows describe the directionality of temporal changes that occur along the line. To validate the patterns detected by non-reductionist operations, reductionist procedures are needed. Integrated (non-reductionist and reductionist) methods can (i) distinguish data subsets that differ immunologically and statistically; (ii) differentiate false-negative from -positive errors; (iii) discriminate disease stages; (iv) capture in vivo, multilevel interactions that consider the patient, the microbe, and antibiotic-mediated responses; and (v) assess dynamics. Integrated methods provide repeatable and biologically interpretable information

Canine leukocyte spatial-temporal relationships.

<p>When dimensionless indicators (DIs) were utilized and three-dimensional (3D) patterns were considered, canine data revealed two (‘left’ and ‘right’) subsets (<b>a, b</b>). Spatial data subsets exhibited non-overlapping lymphocyte percentages and N/L and M/L ratios (<b>c</b>). When temporal data directionality was considered, arrows expressing different directionality (<b>d</b>) increased discrimination: 4D (spatial-temporal) patterns distinguished five subsets (in addition to the first observation) and non-overlapping N% differentiated the ‘right side/left-to-right flow’ observations from the first one (horizontal lines indicate non-overlapping data subsets, <b>e</b>).</p

Human leukocyte spatial-temporal (MSSA/hip implant-related) relationships.

<p>Three data subsets were identified when the MSSA/hip implant human case was explored with dimensionless indicators (<b>a</b>). All data points associated with antibiotic therapy were clustered within one subset (green polygon, <b>b</b>), even though antibiotics were administered in two non-consecutive periods (green boxes, <b>b</b>). The ‘vertical’ subset exhibited statistically significantly higher M/L values than the ‘bottom, left’ subset (<b>c</b>). When arrows that connected pairs of consecutive observations were assessed, three ‘bottom-up’ and two ‘top-down’ observations were detected (red and blue arrows, respectively, <b>d</b>). Changes in directionality were detected within one day: at days 159/160, one ‘bottom-up’ data point was followed by one ‘top-down’ observation (<b>d</b>). Spatial-temporal patterns (temporal data flows) differentiated four data subsets (<b>e</b>). The use of arrows distinguished ‘vertical, bottom-up’ from ‘vertical, top-down’ observations (horizontal line, <b>e</b>).</p